This document summarizes a study using Herschel observations of the [C ii] 158μm line to analyze the distribution of different gas components in the Milky Way galaxy. The observations provide high-resolution maps of [C ii] emission across the Galactic plane. By comparing these maps to observations of HI, CO, and other tracers, the study finds that [C ii] emission is associated with spiral arms between 4-10 kpc from the Galactic center. It estimates that [C ii] traces dense photon-dominated regions (47%), CO-dark H2 gas (28%), cold atomic gas (21%), and ionized gas (4%). The study also analyzes the distribution of cold neutral medium versus
Galaxy dynamics and the mass density of the universeSérgio Sacani
Dynamical evidence accumulated over the
past 20 years has convinced astronomers that luminous matter
in a spiral galaxy constitutes no more than 10% of the mass of
a galaxy. An additional 90% is inferred by its gravitational
effect on luminous material. Here I review recent observations
concerning the distribution of luminous and nonluminous
matter in the Milky Way, in galaxies, and in galaxy clusters.
Observations of neutral hydrogen disks, some extending in
radius several times the optical disk, confirm that a massive
dark halo is a major component of virtually every spiral. A
recent surprise has been the discovery that stellar and gas
motions in ellipticals are enormously complex. To date, only for
a few spheroidal galaxies do the velocities extend far enough to
probe the outer mass distribution. But the diverse kinematics
of inner cores, peripheral to deducing the overall mass distribution,
offer additional evidence that ellipticals have acquired
gas-rich systems after initial formation. Dynamical results are
consistent with a low-density universe, in which the required
dark matter could be baryonic. On smallest scales of galaxies
[10 kiloparsec (kpc); H. = 50 kmsec'lmegaparsec'11 the
luminous matter constitutes only 1% of the closure density. On
scales greater than binary galaxies (i.e., .100 kpc) all systems
indicate a density -10% of the closure density, a density
consistent with the low baryon density in the universe. If
large-scale motions in the universe require a higher mass
density, these motions would constitute the first dynamical
evidence for nonbaryonic matter in a universe of higher
density.
PROBING FOR EVIDENCE OF PLUMES ON EUROPA WITH HST/STISSérgio Sacani
Roth et al. (2014a) reported evidence for plumes of water venting from a southern high latitude
region on Europa – spectroscopic detection of off-limb line emission from the dissociation
products of water. Here, we present Hubble Space Telescope (HST) direct images of Europa in
the far ultraviolet (FUV) as it transited the smooth face of Jupiter, in order to measure absorption
from gas or aerosols beyond the Europa limb. Out of ten observations we found three in which
plume activity could be implicated. Two show statistically significant features at latitudes similar
to Roth et al., and the third, at a more equatorial location. We consider potential systematic
effects that might influence the statistical analysis and create artifacts, and are unable to find any
that can definitively explain the features, although there are reasons to be cautious. If the
apparent absorption features are real, the magnitude of implied outgassing is similar to that of the
Roth et al. feature, however the apparent activity appears more frequently in our data.
A highly magnetized twin-jet base pinpoints a supermassive black holeSérgio Sacani
Supermassive black holes (SMBH) are essential for the production of jets in radio-loud active galactic nuclei (AGN). Theoretical
models based on (Blandford & Znajek 1977, MNRAS, 179, 433) extract the rotational energy from a Kerr black hole, which could
be the case for NGC1052, to launch these jets. This requires magnetic fields on the order of 103 G to 104 G. We imaged the vicinity
of the SMBH of the AGN NGC1052 with the Global Millimetre VLBI Array and found a bright and compact central feature that is
smaller than 1.9 light days (100 Schwarzschild radii) in radius. Interpreting this as a blend of the unresolved jet bases, we derive the
magnetic field at 1 Schwarzschild radius to lie between 200 G and 8:3 104 G consistent with Blandford & Znajek models.
The ASTRODEEP Frontier Fields catalogues II. Photometric redshifts and rest f...Sérgio Sacani
Aims. We present the first public release of photometric redshifts, galaxy rest frame properties and associated magnification values
in the cluster and parallel pointings of the first two Frontier Fields, Abell-2744 and MACS-J0416. The released catalogues aim to
provide a reference for future investigations of extragalactic populations in these legacy fields: from lensed high-redshift galaxies to
cluster members themselves.
Methods.We exploit a multiwavelength catalogue, ranging from Hubble Space Telescope (HST) to ground-based K and Spitzer IRAC,
which is specifically designed to enable detection and measurement of accurate fluxes in crowded cluster regions. The multiband
information is used to derive photometric redshifts and physical properties of sources detected either in the H-band image alone, or
from a stack of four WFC3 bands. To minimize systematics, median photometric redshifts are assembled from six dierent approaches
to photo-z estimates. Their reliability is assessed through a comparison with available spectroscopic samples. State-of-the-art lensing
models are used to derive magnification values on an object-by-object basis by taking into account sources positions and redshifts.
Results. We show that photometric redshifts reach a remarkable 3–5% accuracy. After accounting for magnification, the H-band
number counts are found to be in agreement at bright magnitudes with number counts from the CANDELS fields, while extending
the presently available samples to galaxies that, intrinsically, are as faint as H 32 33, thanks to strong gravitational lensing. The
Frontier Fields allow the galaxy stellar mass distribution to be probed, depending on magnification, at 0.5–1.5 dex lower masses with
respect to extragalactic wide fields, including sources at Mstar 107–108 M at z > 5. Similarly, they allow the detection of objects
with intrinsic star formation rates (SFRs) >1 dex lower than in the CANDELS fields reaching 0.1–1 M=yr at z 6–10.
A suppression of differential rotation in Jupiter’s deep interiorSérgio Sacani
Jupiter’s atmosphere is rotating differentially, with zones and
belts rotating at speeds that differ by up to 100 metres per
second. Whether this is also true of the gas giant’s interior has
been unknown1,2
, limiting our ability to probe the structure and
composition of the planet3,4
. The discovery by the Juno spacecraft
that Jupiter’s gravity field is north–south asymmetric5
and the
determination of its non-zero odd gravitational harmonics J3, J5, J7
and J9 demonstrates that the observed zonal cloud flow must persist
to a depth of about 3,000 kilometres from the cloud tops6
. Here we
report an analysis of Jupiter’s even gravitational harmonics J4, J6,
J8 and J10 as observed by Juno5
and compared to the predictions
of interior models. We find that the deep interior of the planet
rotates nearly as a rigid body, with differential rotation decreasing
by at least an order of magnitude compared to the atmosphere.
Moreover, we find that the atmospheric zonal flow extends to more
than 2,000 kilometres and to less than 3,500 kilometres, making
it fully consistent with the constraints obtained independently
from the odd gravitational harmonics. This depth corresponds
to the point at which the electric conductivity becomes large and
magnetic drag should suppress differential rotation7
. Given that
electric conductivity is dependent on planetary mass, we expect the
outer, differentially rotating region to be at least three times deeper
in Saturn and to be shallower in massive giant planets and brown
dwarfs.
Galaxy dynamics and the mass density of the universeSérgio Sacani
Dynamical evidence accumulated over the
past 20 years has convinced astronomers that luminous matter
in a spiral galaxy constitutes no more than 10% of the mass of
a galaxy. An additional 90% is inferred by its gravitational
effect on luminous material. Here I review recent observations
concerning the distribution of luminous and nonluminous
matter in the Milky Way, in galaxies, and in galaxy clusters.
Observations of neutral hydrogen disks, some extending in
radius several times the optical disk, confirm that a massive
dark halo is a major component of virtually every spiral. A
recent surprise has been the discovery that stellar and gas
motions in ellipticals are enormously complex. To date, only for
a few spheroidal galaxies do the velocities extend far enough to
probe the outer mass distribution. But the diverse kinematics
of inner cores, peripheral to deducing the overall mass distribution,
offer additional evidence that ellipticals have acquired
gas-rich systems after initial formation. Dynamical results are
consistent with a low-density universe, in which the required
dark matter could be baryonic. On smallest scales of galaxies
[10 kiloparsec (kpc); H. = 50 kmsec'lmegaparsec'11 the
luminous matter constitutes only 1% of the closure density. On
scales greater than binary galaxies (i.e., .100 kpc) all systems
indicate a density -10% of the closure density, a density
consistent with the low baryon density in the universe. If
large-scale motions in the universe require a higher mass
density, these motions would constitute the first dynamical
evidence for nonbaryonic matter in a universe of higher
density.
PROBING FOR EVIDENCE OF PLUMES ON EUROPA WITH HST/STISSérgio Sacani
Roth et al. (2014a) reported evidence for plumes of water venting from a southern high latitude
region on Europa – spectroscopic detection of off-limb line emission from the dissociation
products of water. Here, we present Hubble Space Telescope (HST) direct images of Europa in
the far ultraviolet (FUV) as it transited the smooth face of Jupiter, in order to measure absorption
from gas or aerosols beyond the Europa limb. Out of ten observations we found three in which
plume activity could be implicated. Two show statistically significant features at latitudes similar
to Roth et al., and the third, at a more equatorial location. We consider potential systematic
effects that might influence the statistical analysis and create artifacts, and are unable to find any
that can definitively explain the features, although there are reasons to be cautious. If the
apparent absorption features are real, the magnitude of implied outgassing is similar to that of the
Roth et al. feature, however the apparent activity appears more frequently in our data.
A highly magnetized twin-jet base pinpoints a supermassive black holeSérgio Sacani
Supermassive black holes (SMBH) are essential for the production of jets in radio-loud active galactic nuclei (AGN). Theoretical
models based on (Blandford & Znajek 1977, MNRAS, 179, 433) extract the rotational energy from a Kerr black hole, which could
be the case for NGC1052, to launch these jets. This requires magnetic fields on the order of 103 G to 104 G. We imaged the vicinity
of the SMBH of the AGN NGC1052 with the Global Millimetre VLBI Array and found a bright and compact central feature that is
smaller than 1.9 light days (100 Schwarzschild radii) in radius. Interpreting this as a blend of the unresolved jet bases, we derive the
magnetic field at 1 Schwarzschild radius to lie between 200 G and 8:3 104 G consistent with Blandford & Znajek models.
The ASTRODEEP Frontier Fields catalogues II. Photometric redshifts and rest f...Sérgio Sacani
Aims. We present the first public release of photometric redshifts, galaxy rest frame properties and associated magnification values
in the cluster and parallel pointings of the first two Frontier Fields, Abell-2744 and MACS-J0416. The released catalogues aim to
provide a reference for future investigations of extragalactic populations in these legacy fields: from lensed high-redshift galaxies to
cluster members themselves.
Methods.We exploit a multiwavelength catalogue, ranging from Hubble Space Telescope (HST) to ground-based K and Spitzer IRAC,
which is specifically designed to enable detection and measurement of accurate fluxes in crowded cluster regions. The multiband
information is used to derive photometric redshifts and physical properties of sources detected either in the H-band image alone, or
from a stack of four WFC3 bands. To minimize systematics, median photometric redshifts are assembled from six dierent approaches
to photo-z estimates. Their reliability is assessed through a comparison with available spectroscopic samples. State-of-the-art lensing
models are used to derive magnification values on an object-by-object basis by taking into account sources positions and redshifts.
Results. We show that photometric redshifts reach a remarkable 3–5% accuracy. After accounting for magnification, the H-band
number counts are found to be in agreement at bright magnitudes with number counts from the CANDELS fields, while extending
the presently available samples to galaxies that, intrinsically, are as faint as H 32 33, thanks to strong gravitational lensing. The
Frontier Fields allow the galaxy stellar mass distribution to be probed, depending on magnification, at 0.5–1.5 dex lower masses with
respect to extragalactic wide fields, including sources at Mstar 107–108 M at z > 5. Similarly, they allow the detection of objects
with intrinsic star formation rates (SFRs) >1 dex lower than in the CANDELS fields reaching 0.1–1 M=yr at z 6–10.
A suppression of differential rotation in Jupiter’s deep interiorSérgio Sacani
Jupiter’s atmosphere is rotating differentially, with zones and
belts rotating at speeds that differ by up to 100 metres per
second. Whether this is also true of the gas giant’s interior has
been unknown1,2
, limiting our ability to probe the structure and
composition of the planet3,4
. The discovery by the Juno spacecraft
that Jupiter’s gravity field is north–south asymmetric5
and the
determination of its non-zero odd gravitational harmonics J3, J5, J7
and J9 demonstrates that the observed zonal cloud flow must persist
to a depth of about 3,000 kilometres from the cloud tops6
. Here we
report an analysis of Jupiter’s even gravitational harmonics J4, J6,
J8 and J10 as observed by Juno5
and compared to the predictions
of interior models. We find that the deep interior of the planet
rotates nearly as a rigid body, with differential rotation decreasing
by at least an order of magnitude compared to the atmosphere.
Moreover, we find that the atmospheric zonal flow extends to more
than 2,000 kilometres and to less than 3,500 kilometres, making
it fully consistent with the constraints obtained independently
from the odd gravitational harmonics. This depth corresponds
to the point at which the electric conductivity becomes large and
magnetic drag should suppress differential rotation7
. Given that
electric conductivity is dependent on planetary mass, we expect the
outer, differentially rotating region to be at least three times deeper
in Saturn and to be shallower in massive giant planets and brown
dwarfs.
Measurement of Jupiter’s asymmetric gravity fieldSérgio Sacani
The gravity harmonics of a fluid, rotating planet can be decomposed
into static components arising from solid-body rotation and dynamic
components arising from flows. In the absence of internal dynamics,
the gravity field is axially and hemispherically symmetric and is
dominated by even zonal gravity harmonics J2n that are approximately
proportional to qn, where q is the ratio between centrifugal
acceleration and gravity at the planet’s equator1
. Any asymmetry in the
gravity field is attributed to differential rotation and deep atmospheric
flows. The odd harmonics, J3, J5, J7, J9 and higher, are a measure of the
depth of the winds in the different zones of the atmosphere2,3
. Here
we report measurements of Jupiter’s gravity harmonics (both even
and odd) through precise Doppler tracking of the Juno spacecraft
in its polar orbit around Jupiter. We find a north–south asymmetry,
which is a signature of atmospheric and interior flows. Analysis of
the harmonics, described in two accompanying papers4,5
, provides
the vertical profile of the winds and precise constraints for the depth
of Jupiter’s dynamical atmosphere.
Cassini finds molecular hydrogen in the Enceladus plume: Evidence for hydroth...Sérgio Sacani
Saturn’s moon Enceladus has an ice-covered ocean; a plume of material erupts from
cracks in the ice. The plume contains chemical signatures of water-rock interaction
between the ocean and a rocky core.We used the Ion Neutral Mass Spectrometer onboard
the Cassini spacecraft to detect molecular hydrogen in the plume. By using the instrument’s
open-source mode, background processes of hydrogen production in the instrument were
minimized and quantified, enabling the identification of a statistically significant signal of
hydrogen native to Enceladus.We find that the most plausible source of this hydrogen is
ongoing hydrothermal reactions of rock containing reduced minerals and organic materials.
The relatively high hydrogen abundance in the plume signals thermodynamic disequilibrium
that favors the formation of methane from CO2 in Enceladus’ ocean.
Supermassive black holes in galaxy centres can grow by the accretion
of gas, liberating enormous amounts of energy that might
regulate star formation on galaxy-wide scales1–3
. The nature of
gaseous fuel reservoirs that power black hole growth is nevertheless
largely unconstrained by observations, and is instead routinely
simplified as a smooth, spherical inflow of very hot gas
in accordance with the Bondi solution4
. Recent theory5–7 and
simulations8–10 instead predict that accretion can be dominated by
a stochastic, clumpy distribution of very cold molecular clouds,
though unambiguous observational support for this prediction remains
elusive. Here we show observational evidence for a cold,
clumpy accretion flow toward a supermassive black hole fuel reservoir
in the nucleus of the Abell 2597 Brightest Cluster Galaxy
(BCG), a nearby (z = 0.0821) giant elliptical galaxy surrounded
by a dense halo of hot plasma11–13. Under the right conditions,
thermal instabilities can precipitate from this hot gas, producing a
rain of cold clouds that fall toward the galaxy’s centre14, sustaining
star formation amid a kiloparsec-scale molecular nebula that inhabits
its core15. New interferometric sub-millimetre observations
show that these cold clouds also fuel black hole accretion, revealing
“shadows” cast by molecular clouds as they move inward at ∼ 300
km s−1
toward the active supermassive black hole in the galaxy
centre, which serves as a bright backlight. Corroborating evidence
from prior observations16 of warmer atomic gas at extremely high
spatial resolution17, along with simple arguments based on geometry
and probability, indicates that these clouds are within the innermost
hundred parsecs of the black hole, and falling closer toward
it
Todo mundo sabe que os raios produzidos pela Estrela da Morte em Guerra nas Estrelas não pode existir na vida real, porém no universo existem fenômenos que as vezes conseguem superar até a mais surpreendente ficção.
A galáxia Pictor A, é um desses objetos que possuem fenômenos tão espetaculares quanto aqueles exibidos no cinema. Essa galáxia localiza-se a cerca de 500 milhões de anos-luz da Terra e possui um buraco negro supermassivo no seu centro. Uma grande quantidade de energia gravitacional é lançada, à medida que o material cai em direção ao horizonte de eventos, o ponto sem volta ao redor do buraco negro. Essa energia produz um enorme jato de partículas que viajam a uma velocidade próxima da velocidade da luz no espaço intergaláctico, chamado de jato relativístico.
Para obter imagens desse jato, os cientistas usaram o Observatório de Raios-X Chandra, da NASA várias vezes durante 15 anos. Os dados do Chandra, apresentados em azul nas imagens, foram combinados com os dados obtidos em ondas de rádio a partir do Australia Telescope Compact Array, e são aparesentados em vermelho nas imagens.
Storm in teacup_a_radio_quiet_quasar_with_radio_emitting_bubblesSérgio Sacani
Artigo descreve descoberta feita com o VLA de uma tempestade nas ondas de rádio em uma galáxia até então calma, o que traz conclusões sobre a evolução das galáxias.
A 2 4_determination_of_the_local_value_of_the_hubble_constantSérgio Sacani
We use the Wide Field Camera 3 (WFC3) on the Hubble Space Telescope (HST) to
reduce the uncertainty in the local value of the Hubble constant from 3.3% to 2.4%.
The bulk of this improvement comes from new, near-infrared observations of Cepheid
variables in 11 host galaxies of recent type Ia supernovae (SNe Ia), more than doubling
the sample of reliable SNe Ia having a Cepheid-calibrated distance to a total of 19; these
in turn leverage the magnitude-redshift relation based on 300 SNe Ia at z <0.15. All
19 hosts as well as the megamaser system NGC4258 have been observed with WFC3
in the optical and near-infrared, thus nullifying cross-instrument zeropoint errors in the
relative distance estimates from Cepheids. Other noteworthy improvements include a
33% reduction in the systematic uncertainty in the maser distance to NGC4258, a larger
sample of Cepheids in the Large Magellanic Cloud (LMC), a more robust distance to
the LMC based on late-type detached eclipsing binaries (DEBs), HST observations of
Cepheids in M31, and new HST-based trigonometric parallaxes for Milky Way (MW)
Cepheids.
An Earth-sized exoplanet with a Mercury-like compositionSérgio Sacani
Earth, Venus, Mars and some extrasolar terrestrial planets1
have a mass and radius that is consistent with a mass fraction
of about 30% metallic core and 70% silicate mantle2
. At the
inner frontier of the Solar System, Mercury has a completely
different composition, with a mass fraction of about 70%
metallic core and 30% silicate mantle3
. Several formation or
evolution scenarios are proposed to explain this metal-rich
composition, such as a giant impact4, mantle evaporation5
or the depletion of silicate at the inner edge of the protoplanetary
disk6. These scenarios are still strongly debated.
Here, we report the discovery of a multiple transiting planetary
system (K2-229) in which the inner planet has a radius
of 1.165 ± 0.066 Earth radii and a mass of 2.59 ± 0.43 Earth
masses. This Earth-sized planet thus has a core-mass fraction
that is compatible with that of Mercury, although it was
expected to be similar to that of Earth based on host-star
chemistry7
. This larger Mercury analogue either formed with
a very peculiar composition or has evolved, for example, by
losing part of its mantle. Further characterization of Mercurylike
exoplanets such as K2-229 b will help to put the detailed
in situ observations of Mercury (with MESSENGER and
BepiColombo8) into the global context of the formation and
evolution of solar and extrasolar terrestrial planets.
Quase 900 galáxias próximas, porém escondidas, têm sido estudadas por uma equipe internacional de astrônomos, levando uma nova luz sobre o entendimento do Grande Atrator - uma concentração difusa de massa a 250 milhões de anos-luz de distância, que está puxando a nossa Via Láctea, e milhares de outras galáxias em sua direção.
Usando o Multibeam Receiver, instalado no rádio telescópio Parkes de 64 m, pertencente à instituição CSIRO na Austrália, a equipe foi capaz de ver através das estrelas e da poeira da nossa galáxia, vasculhando assim uma região inexplorada do espaço, conhecida pelos astrônomos como Zone of Avoidance (Zona de Anulação).
“Nós descobrimos 883 galáxias, um terço das quais nunca tinham sido vistas anteriormente”, disse o Professor Lister Staveley-Smith, membro da equipe, do ARC Centre of Excellence for All-sky Astrophysics, e da University of Western Australia, um dos nós do International Centre for Radio Astronomy Research.
Measurement of Jupiter’s asymmetric gravity fieldSérgio Sacani
The gravity harmonics of a fluid, rotating planet can be decomposed
into static components arising from solid-body rotation and dynamic
components arising from flows. In the absence of internal dynamics,
the gravity field is axially and hemispherically symmetric and is
dominated by even zonal gravity harmonics J2n that are approximately
proportional to qn, where q is the ratio between centrifugal
acceleration and gravity at the planet’s equator1
. Any asymmetry in the
gravity field is attributed to differential rotation and deep atmospheric
flows. The odd harmonics, J3, J5, J7, J9 and higher, are a measure of the
depth of the winds in the different zones of the atmosphere2,3
. Here
we report measurements of Jupiter’s gravity harmonics (both even
and odd) through precise Doppler tracking of the Juno spacecraft
in its polar orbit around Jupiter. We find a north–south asymmetry,
which is a signature of atmospheric and interior flows. Analysis of
the harmonics, described in two accompanying papers4,5
, provides
the vertical profile of the winds and precise constraints for the depth
of Jupiter’s dynamical atmosphere.
Cassini finds molecular hydrogen in the Enceladus plume: Evidence for hydroth...Sérgio Sacani
Saturn’s moon Enceladus has an ice-covered ocean; a plume of material erupts from
cracks in the ice. The plume contains chemical signatures of water-rock interaction
between the ocean and a rocky core.We used the Ion Neutral Mass Spectrometer onboard
the Cassini spacecraft to detect molecular hydrogen in the plume. By using the instrument’s
open-source mode, background processes of hydrogen production in the instrument were
minimized and quantified, enabling the identification of a statistically significant signal of
hydrogen native to Enceladus.We find that the most plausible source of this hydrogen is
ongoing hydrothermal reactions of rock containing reduced minerals and organic materials.
The relatively high hydrogen abundance in the plume signals thermodynamic disequilibrium
that favors the formation of methane from CO2 in Enceladus’ ocean.
Supermassive black holes in galaxy centres can grow by the accretion
of gas, liberating enormous amounts of energy that might
regulate star formation on galaxy-wide scales1–3
. The nature of
gaseous fuel reservoirs that power black hole growth is nevertheless
largely unconstrained by observations, and is instead routinely
simplified as a smooth, spherical inflow of very hot gas
in accordance with the Bondi solution4
. Recent theory5–7 and
simulations8–10 instead predict that accretion can be dominated by
a stochastic, clumpy distribution of very cold molecular clouds,
though unambiguous observational support for this prediction remains
elusive. Here we show observational evidence for a cold,
clumpy accretion flow toward a supermassive black hole fuel reservoir
in the nucleus of the Abell 2597 Brightest Cluster Galaxy
(BCG), a nearby (z = 0.0821) giant elliptical galaxy surrounded
by a dense halo of hot plasma11–13. Under the right conditions,
thermal instabilities can precipitate from this hot gas, producing a
rain of cold clouds that fall toward the galaxy’s centre14, sustaining
star formation amid a kiloparsec-scale molecular nebula that inhabits
its core15. New interferometric sub-millimetre observations
show that these cold clouds also fuel black hole accretion, revealing
“shadows” cast by molecular clouds as they move inward at ∼ 300
km s−1
toward the active supermassive black hole in the galaxy
centre, which serves as a bright backlight. Corroborating evidence
from prior observations16 of warmer atomic gas at extremely high
spatial resolution17, along with simple arguments based on geometry
and probability, indicates that these clouds are within the innermost
hundred parsecs of the black hole, and falling closer toward
it
Todo mundo sabe que os raios produzidos pela Estrela da Morte em Guerra nas Estrelas não pode existir na vida real, porém no universo existem fenômenos que as vezes conseguem superar até a mais surpreendente ficção.
A galáxia Pictor A, é um desses objetos que possuem fenômenos tão espetaculares quanto aqueles exibidos no cinema. Essa galáxia localiza-se a cerca de 500 milhões de anos-luz da Terra e possui um buraco negro supermassivo no seu centro. Uma grande quantidade de energia gravitacional é lançada, à medida que o material cai em direção ao horizonte de eventos, o ponto sem volta ao redor do buraco negro. Essa energia produz um enorme jato de partículas que viajam a uma velocidade próxima da velocidade da luz no espaço intergaláctico, chamado de jato relativístico.
Para obter imagens desse jato, os cientistas usaram o Observatório de Raios-X Chandra, da NASA várias vezes durante 15 anos. Os dados do Chandra, apresentados em azul nas imagens, foram combinados com os dados obtidos em ondas de rádio a partir do Australia Telescope Compact Array, e são aparesentados em vermelho nas imagens.
Storm in teacup_a_radio_quiet_quasar_with_radio_emitting_bubblesSérgio Sacani
Artigo descreve descoberta feita com o VLA de uma tempestade nas ondas de rádio em uma galáxia até então calma, o que traz conclusões sobre a evolução das galáxias.
A 2 4_determination_of_the_local_value_of_the_hubble_constantSérgio Sacani
We use the Wide Field Camera 3 (WFC3) on the Hubble Space Telescope (HST) to
reduce the uncertainty in the local value of the Hubble constant from 3.3% to 2.4%.
The bulk of this improvement comes from new, near-infrared observations of Cepheid
variables in 11 host galaxies of recent type Ia supernovae (SNe Ia), more than doubling
the sample of reliable SNe Ia having a Cepheid-calibrated distance to a total of 19; these
in turn leverage the magnitude-redshift relation based on 300 SNe Ia at z <0.15. All
19 hosts as well as the megamaser system NGC4258 have been observed with WFC3
in the optical and near-infrared, thus nullifying cross-instrument zeropoint errors in the
relative distance estimates from Cepheids. Other noteworthy improvements include a
33% reduction in the systematic uncertainty in the maser distance to NGC4258, a larger
sample of Cepheids in the Large Magellanic Cloud (LMC), a more robust distance to
the LMC based on late-type detached eclipsing binaries (DEBs), HST observations of
Cepheids in M31, and new HST-based trigonometric parallaxes for Milky Way (MW)
Cepheids.
An Earth-sized exoplanet with a Mercury-like compositionSérgio Sacani
Earth, Venus, Mars and some extrasolar terrestrial planets1
have a mass and radius that is consistent with a mass fraction
of about 30% metallic core and 70% silicate mantle2
. At the
inner frontier of the Solar System, Mercury has a completely
different composition, with a mass fraction of about 70%
metallic core and 30% silicate mantle3
. Several formation or
evolution scenarios are proposed to explain this metal-rich
composition, such as a giant impact4, mantle evaporation5
or the depletion of silicate at the inner edge of the protoplanetary
disk6. These scenarios are still strongly debated.
Here, we report the discovery of a multiple transiting planetary
system (K2-229) in which the inner planet has a radius
of 1.165 ± 0.066 Earth radii and a mass of 2.59 ± 0.43 Earth
masses. This Earth-sized planet thus has a core-mass fraction
that is compatible with that of Mercury, although it was
expected to be similar to that of Earth based on host-star
chemistry7
. This larger Mercury analogue either formed with
a very peculiar composition or has evolved, for example, by
losing part of its mantle. Further characterization of Mercurylike
exoplanets such as K2-229 b will help to put the detailed
in situ observations of Mercury (with MESSENGER and
BepiColombo8) into the global context of the formation and
evolution of solar and extrasolar terrestrial planets.
Quase 900 galáxias próximas, porém escondidas, têm sido estudadas por uma equipe internacional de astrônomos, levando uma nova luz sobre o entendimento do Grande Atrator - uma concentração difusa de massa a 250 milhões de anos-luz de distância, que está puxando a nossa Via Láctea, e milhares de outras galáxias em sua direção.
Usando o Multibeam Receiver, instalado no rádio telescópio Parkes de 64 m, pertencente à instituição CSIRO na Austrália, a equipe foi capaz de ver através das estrelas e da poeira da nossa galáxia, vasculhando assim uma região inexplorada do espaço, conhecida pelos astrônomos como Zone of Avoidance (Zona de Anulação).
“Nós descobrimos 883 galáxias, um terço das quais nunca tinham sido vistas anteriormente”, disse o Professor Lister Staveley-Smith, membro da equipe, do ARC Centre of Excellence for All-sky Astrophysics, e da University of Western Australia, um dos nós do International Centre for Radio Astronomy Research.
First results from_the_hubble_opal_program_jupiter_in_2015Sérgio Sacani
Os cientistas usando o Telescópio Espacial Hubble da NASA/ESA produziram novos mapas de Júpiter, que mostram as contínuas mudanças que ocorrem com a famosa Grande Mancha Vermelha. As imagens também revelam uma rara estrutura em forma de onda na atmosfera do planeta que não tinha sido vista por décadas. A nova imagem é a primeira de uma série de retratos anuais dos planetas externos do Sistema Solar, que nos darão um novo olhar desses mundos remotos, e ajudarão os cientistas a estudarem como eles mudam com o passar do tempo.
Nessa nova imagem de Júpiter, uma grande quantidade de feições foi capturada incluindo ventos, nuvens e tempestades. Os cientistas por trás dessas novas imagens, as obtiveram usando a Wide Field Camera 3 do Hubble, num período de observação de mais de 10 horas e produziram assim dois mapas completos do planeta, a partir das suas observações. Esses mapas fizeram com que fosse possível determinar a velocidade dos ventos em Júpiter, com a finalidade de identificar diferentes fenômenos na sua atmosfera além de traquear as suas feições mais famosas.
As novas imagens confirmam que a grande tempestade que tem existido na superfície de nuvens de Júpiter por no mínimo 300 anos, continua a encolher, mas mesmo que desapareça, ela irá morrer lutando. A tempestade, conhecida como Grande Mancha Vermelha, é vista aqui fazendo seus movimentos em espiral no centro da imagem do planeta. Ela tem diminuído de tamanho de maneira muito rápida de ano em ano. Mas agora, a taxa de encolhimento parece ter reduzido novamente, mesmo apesar da mancha ser cerca de 240 quilômetros menor do que era em 2014.
The shadow _of_the_flying_saucer_a_very_low_temperature_for_large_dust_grainsSérgio Sacani
Os astrónomos usaram o ALMA e os telescópios do IRAM para fazer a primeira medição direta da temperatura dos grãos de poeira grandes situados nas regiões periféricas de um disco de formação planetária que se encontra em torno de uma estrela jovem. Ao observar de forma inovadora um objeto cujo nome informal é Disco Voador, os astrónomos descobriram que os grãos de poeira são muito mais frios do que o esperado: -266º Celsius. Este resultado surpreendente sugere que os modelos teóricos destes discos precisam de ser revistos.
Uma equipa internacional liderada por Stephane Guilloteau do Laboratoire d´Astrophysique de Bordeaux, França, mediu a temperatura de enormes grãos de poeira que se encontram em torno da jovem estrela 2MASS J16281370-2431391 na região de formação estelar Rho Ophiuchi, a cerca de 400 anos-luz de distância da Terra.
Esta estrela encontra-se rodeada por um disco de gás e poeira — chamado disco protoplanetário, uma vez que se encontra na fase inicial da formação de um sistema planetário. Este disco é visto de perfil quando observado a partir da Terra e a sua aparência em imagens no visível levou a que se lhe desse o nome informal de Disco Voador.
Os astrónomos utilizaram o ALMA para observar o brilho emitido pelas moléculas de monóxido de carbono no disco da 2MASS J16281370-2431391. As imagens revelaram-se extremamente nítidas e descobriu-se algo estranho — em alguns casos o sinal recebido era negativo. Normalmente um sinal negativo é fisicamente impossível, mas neste caso existe uma explicação, que leva a uma conclusão surpreendente.
Detection of an atmosphere around the super earth 55 cancri eSérgio Sacani
We report the analysis of two new spectroscopic observations of the super-Earth 55 Cancri e, in the near
infrared, obtained with the WFC3 camera onboard the HST. 55 Cancri e orbits so close to its parent
star, that temperatures much higher than 2000 K are expected on its surface. Given the brightness
of 55 Cancri, the observations were obtained in scanning mode, adopting a very long scanning length
and a very high scanning speed. We use our specialized pipeline to take into account systematics
introduced by these observational parameters when coupled with the geometrical distortions of the
instrument. We measure the transit depth per wavelength channel with an average relative uncertainty
of 22 ppm per visit and nd modulations that depart from a straight line model with a 6 condence
level. These results suggest that 55 Cancri e is surrounded by an atmosphere, which is probably
hydrogen-rich. Our fully Bayesian spectral retrieval code, T -REx, has identied HCN to be the
most likely molecular candidate able to explain the features at 1.42 and 1.54 m. While additional
spectroscopic observations in a broader wavelength range in the infrared will be needed to conrm
the HCN detection, we discuss here the implications of such result. Our chemical model, developed
with combustion specialists, indicates that relatively high mixing ratios of HCN may be caused by a
high C/O ratio. This result suggests this super-Earth is a carbon-rich environment even more exotic
than previously thought.
First detection of CO2 emission in a Centaur: JWST NIRSpec observations of 39...Sérgio Sacani
Centaurs are minor solar system bodies with orbits transitioning between those of Trans-Neptunian
Scattered Disk objects and Jupiter Family comets. 39P/Oterma is a frequently active Centaur that
has recently held both Centaur and JFC classifications and was observed with the JWST NIRSpec
instrument on 2022 July 27 UTC while it was 5.82 au from the Sun. For the first time, CO2 gas
emission was detected in a Centaur, with a production rate of QCO2 = (5.96 ± 0.80) × 1023 molecules
s
−1
. This is the lowest detection of CO2 of any Centaur or comet. CO and H2O were not detected
down to constraining upper limits. Derived mixing ratios of QCO/QCO2 ≤2.03 and QCO2
/QH2O ≥0.60
are consistent with CO2 and/or CO outgassing playing large roles in driving the activity, but not water,
and show a significant difference between the coma abundances of 29P/Schwassmann-Wachmann 1,
another Centaur at a similar heliocentric distance, which may be explained by thermal processing of
39P’s surface during its previous Jupiter-family comet orbit. To help contextualize the JWST data we
also acquired visible CCD imaging data on two dates in July (Gemini North) and September (Lowell
Discovery Telescope) 2022. Image analysis and photometry based on these data are consistent with a
point source detection and an estimated effective nucleus radius of 39P in the range of Rnuc =2.21 to
2.49 km.
Exocometary gas in_th_hd_181327_debris_ringSérgio Sacani
An increasing number of observations have shown that gaseous debris discs are not an
exception. However, until now we only knew of cases around A stars. Here we present the first
detection of 12CO (2-1) disc emission around an F star, HD 181327, obtained with ALMA
observations at 1.3 mm. The continuum and CO emission are resolved into an axisymmetric
disc with ring-like morphology. Using a Markov chain Monte Carlo method coupled with
radiative transfer calculations we study the dust and CO mass distribution. We find the dust is
distributed in a ring with a radius of 86:0 0:4 AU and a radial width of 23:2 1:0 AU. At
this frequency the ring radius is smaller than in the optical, revealing grain size segregation
expected due to radiation pressure. We also report on the detection of low level continuum
emission beyond the main ring out to 200 AU. We model the CO emission in the non-LTE
regime and we find that the CO is co-located with the dust, with a total CO gas mass ranging
between 1:2 10 6 M and 2:9 10 6 M, depending on the gas kinetic temperature and
collisional partners densities. The CO densities and location suggest a secondary origin, i.e.
released from icy planetesimals in the ring. We derive a CO cometary composition that is
consistent with Solar system comets. Due to the low gas densities it is unlikely that the gas is
shaping the dust distribution.
The pristine nature of SMSS 1605−1443 revealed by ESPRESSOSérgio Sacani
SMSS J160540.18−144323.1 is the carbon-enhanced metal-poor (CEMP) star with the lowest iron abundance ever measured, [Fe/H] =
−6.2, which was first reported with the SkyMapper telescope. The carbon abundance is A(C) ≈ 6.1 in the low-C band, as the majority of the stars
in this metallicity range. Yet, constraining the isotopic ratio of key species, such as carbon, sheds light on the properties and origin of these elusive
stars.
Aims. We performed high-resolution observations of SMSS 1605−1443 with the ESPRESSO spectrograph to look for variations in the radial
velocity (vrad) with time. These data have been combined with older MIKE and UVES archival observations to enlarge the temporal baseline. The
12C/
13C isotopic ratio is also studied to explore the possibility of mass transfer from a binary companion.
Methods. A cross-correlation function against a natural template was applied to detect vrad variability and a spectral synthesis technique was used
to derive 12C/
13C in the stellar atmosphere.
Results. We confirm previous indications of binarity in SMSS 1605−1443 and measured a lower limit 12C/
13C > 60 at more than a 3σ confidence
level, proving that this system is chemically unmixed and that no mass transfer from the unseen companion has happened so far. Thus, we confirm
the CEMP-no nature of SMSS 1605−1443 and show that the pristine chemical composition of the cloud from which it formed is currently imprinted
in its stellar atmosphere free of contamination.
Hot Earth or Young Venus? A nearby transiting rocky planet mysterySérgio Sacani
Venus and Earth provide astonishingly different views of the evolution of a rocky planet, raising the question of why these two rock y worlds evolv ed so differently. The recently disco v ered transiting Super-Earth LP 890-9c (TOI-4306c, SPECULOOS-2c) is a key to the question. It circles a nearby M6V star in 8.46 d. LP890-9c receives similar flux as modern Earth, which puts it very close to the inner edge of the Habitable Zone (HZ), where models differ strongly in their prediction of how long rocky planets can hold onto their water. We model the atmosphere of a hot LP890-9c at the inner edge of the HZ, where the planet could sustain several very different environments. The resulting transmission spectra differ considerably between a hot, wet exo-Earth, a steamy planet caught in a runaway greenhouse, and an exo-Venus. Distinguishing these scenarios from the planet’s spectra will provide critical new insights into the evolution of hot terrestrial planets into exo-Venus. Our model and spectra are available online as a tool to plan observations. They show that observing LP890-9c can provide key insights into the evolution of a rocky planet at the inner edge of the HZ as well as the long-term future of Earth.
The xmm newton-view_of_the_central_degrees_of_the_milk_waySérgio Sacani
Novas imagens do Observatório de Raios-X XMM-Newton da ESA revelaram alguns dos processos mais intensos que acontecem no coração da nossa Via Láctea.
As fontes brilhantes e pontuais que se destacam por toda imagem indicam os sistemas estelares binários onde uma das estrelas atingiu o final de sua vida, desenvolvendo para um objeto compacto e denso – uma estrela de nêutrons ou um buraco negro.
A região central da Via Láctea também contém jovens estrelas e aglomerados estelares e algumas dessas fontes são visíveis como pontos brancos e vermelhos brilhando na imagem, que se espalha por 1000 anos-luz.
A maior parte da ação ocorre no centro, onde nuvens difusas de gás estão sendo cavadas por ventos poderosos soprados por estrelas jovens, bem como por supernovas.
Different Martian Crustal Seismic Velocities across the Dichotomy Boundary fr...Sérgio Sacani
Article This article is protected by copyright. All rights reserved.
Abstract
We have observed both minor-arc (R1) and major-arc (R2) Rayleigh waves for the largest marsquake (magnitude
of 4.7 ± 0.2) ever recorded. Along the R1 path (in the lowlands), inversion results show that a simple, two-layer
model with an interface located at 21 - 29 km and an upper crustal shear-wave velocity of 3.05 - 3.17 km/s can fit the
group velocity measurements. Along the R2 path, observations can be explained by upper crustal thickness models
constrained from gravity data and upper crustal shear-wave velocities of 2.61 - 3.27 km/s and 3.28 - 3.52 km/s in the
lowlands and highlands, respectively. The shear-wave velocity being faster in the highlands than in the lowlands
indicates the possible existence of sedimentary rocks, and relatively higher porosity in the lowlands.
Observation of Io’s Resurfacing via Plume Deposition Using Ground-based Adapt...Sérgio Sacani
Since volcanic activity was first discovered on Io from Voyager images in 1979, changes
on Io’s surface have been monitored from both spacecraft and ground-based telescopes.
Here, we present the highest spatial resolution images of Io ever obtained from a groundbased telescope. These images, acquired by the SHARK-VIS instrument on the Large
Binocular Telescope, show evidence of a major resurfacing event on Io’s trailing hemisphere. When compared to the most recent spacecraft images, the SHARK-VIS images
show that a plume deposit from a powerful eruption at Pillan Patera has covered part
of the long-lived Pele plume deposit. Although this type of resurfacing event may be common on Io, few have been detected due to the rarity of spacecraft visits and the previously low spatial resolution available from Earth-based telescopes. The SHARK-VIS instrument ushers in a new era of high resolution imaging of Io’s surface using adaptive
optics at visible wavelengths.
Earliest Galaxies in the JADES Origins Field: Luminosity Function and Cosmic ...Sérgio Sacani
We characterize the earliest galaxy population in the JADES Origins Field (JOF), the deepest
imaging field observed with JWST. We make use of the ancillary Hubble optical images (5 filters
spanning 0.4−0.9µm) and novel JWST images with 14 filters spanning 0.8−5µm, including 7 mediumband filters, and reaching total exposure times of up to 46 hours per filter. We combine all our data
at > 2.3µm to construct an ultradeep image, reaching as deep as ≈ 31.4 AB mag in the stack and
30.3-31.0 AB mag (5σ, r = 0.1” circular aperture) in individual filters. We measure photometric
redshifts and use robust selection criteria to identify a sample of eight galaxy candidates at redshifts
z = 11.5 − 15. These objects show compact half-light radii of R1/2 ∼ 50 − 200pc, stellar masses of
M⋆ ∼ 107−108M⊙, and star-formation rates of SFR ∼ 0.1−1 M⊙ yr−1
. Our search finds no candidates
at 15 < z < 20, placing upper limits at these redshifts. We develop a forward modeling approach to
infer the properties of the evolving luminosity function without binning in redshift or luminosity that
marginalizes over the photometric redshift uncertainty of our candidate galaxies and incorporates the
impact of non-detections. We find a z = 12 luminosity function in good agreement with prior results,
and that the luminosity function normalization and UV luminosity density decline by a factor of ∼ 2.5
from z = 12 to z = 14. We discuss the possible implications of our results in the context of theoretical
models for evolution of the dark matter halo mass function.
THE IMPORTANCE OF MARTIAN ATMOSPHERE SAMPLE RETURN.Sérgio Sacani
The return of a sample of near-surface atmosphere from Mars would facilitate answers to several first-order science questions surrounding the formation and evolution of the planet. One of the important aspects of terrestrial planet formation in general is the role that primary atmospheres played in influencing the chemistry and structure of the planets and their antecedents. Studies of the martian atmosphere can be used to investigate the role of a primary atmosphere in its history. Atmosphere samples would also inform our understanding of the near-surface chemistry of the planet, and ultimately the prospects for life. High-precision isotopic analyses of constituent gases are needed to address these questions, requiring that the analyses are made on returned samples rather than in situ.
Multi-source connectivity as the driver of solar wind variability in the heli...Sérgio Sacani
The ambient solar wind that flls the heliosphere originates from multiple
sources in the solar corona and is highly structured. It is often described
as high-speed, relatively homogeneous, plasma streams from coronal
holes and slow-speed, highly variable, streams whose source regions are
under debate. A key goal of ESA/NASA’s Solar Orbiter mission is to identify
solar wind sources and understand what drives the complexity seen in the
heliosphere. By combining magnetic feld modelling and spectroscopic
techniques with high-resolution observations and measurements, we show
that the solar wind variability detected in situ by Solar Orbiter in March
2022 is driven by spatio-temporal changes in the magnetic connectivity to
multiple sources in the solar atmosphere. The magnetic feld footpoints
connected to the spacecraft moved from the boundaries of a coronal hole
to one active region (12961) and then across to another region (12957). This
is refected in the in situ measurements, which show the transition from fast
to highly Alfvénic then to slow solar wind that is disrupted by the arrival of
a coronal mass ejection. Our results describe solar wind variability at 0.5 au
but are applicable to near-Earth observatories.
Gliese 12 b: A Temperate Earth-sized Planet at 12 pc Ideal for Atmospheric Tr...Sérgio Sacani
Recent discoveries of Earth-sized planets transiting nearby M dwarfs have made it possible to characterize the
atmospheres of terrestrial planets via follow-up spectroscopic observations. However, the number of such planets
receiving low insolation is still small, limiting our ability to understand the diversity of the atmospheric
composition and climates of temperate terrestrial planets. We report the discovery of an Earth-sized planet
transiting the nearby (12 pc) inactive M3.0 dwarf Gliese 12 (TOI-6251) with an orbital period (Porb) of 12.76 days.
The planet, Gliese 12 b, was initially identified as a candidate with an ambiguous Porb from TESS data. We
confirmed the transit signal and Porb using ground-based photometry with MuSCAT2 and MuSCAT3, and
validated the planetary nature of the signal using high-resolution images from Gemini/NIRI and Keck/NIRC2 as
well as radial velocity (RV) measurements from the InfraRed Doppler instrument on the Subaru 8.2 m telescope
and from CARMENES on the CAHA 3.5 m telescope. X-ray observations with XMM-Newton showed the host
star is inactive, with an X-ray-to-bolometric luminosity ratio of log 5.7 L L X bol » - . Joint analysis of the light
curves and RV measurements revealed that Gliese 12 b has a radius of 0.96 ± 0.05 R⊕,a3σ mass upper limit of
3.9 M⊕, and an equilibrium temperature of 315 ± 6 K assuming zero albedo. The transmission spectroscopy metric
(TSM) value of Gliese 12 b is close to the TSM values of the TRAPPIST-1 planets, adding Gliese 12 b to the small
list of potentially terrestrial, temperate planets amenable to atmospheric characterization with JWST.
Gliese 12 b, a temperate Earth-sized planet at 12 parsecs discovered with TES...Sérgio Sacani
We report on the discovery of Gliese 12 b, the nearest transiting temperate, Earth-sized planet found to date. Gliese 12 is a
bright (V = 12.6 mag, K = 7.8 mag) metal-poor M4V star only 12.162 ± 0.005 pc away from the Solar system with one of the
lowest stellar activity levels known for M-dwarfs. A planet candidate was detected by TESS based on only 3 transits in sectors
42, 43, and 57, with an ambiguity in the orbital period due to observational gaps. We performed follow-up transit observations
with CHEOPS and ground-based photometry with MINERVA-Australis, SPECULOOS, and Purple Mountain Observatory,
as well as further TESS observations in sector 70. We statistically validate Gliese 12 b as a planet with an orbital period of
12.76144 ± 0.00006 d and a radius of 1.0 ± 0.1 R⊕, resulting in an equilibrium temperature of ∼315 K. Gliese 12 b has excellent
future prospects for precise mass measurement, which may inform how planetary internal structure is affected by the stellar
compositional environment. Gliese 12 b also represents one of the best targets to study whether Earth-like planets orbiting cool
stars can retain their atmospheres, a crucial step to advance our understanding of habitability on Earth and across the galaxy.
The importance of continents, oceans and plate tectonics for the evolution of...Sérgio Sacani
Within the uncertainties of involved astronomical and biological parameters, the Drake Equation
typically predicts that there should be many exoplanets in our galaxy hosting active, communicative
civilizations (ACCs). These optimistic calculations are however not supported by evidence, which is
often referred to as the Fermi Paradox. Here, we elaborate on this long-standing enigma by showing
the importance of planetary tectonic style for biological evolution. We summarize growing evidence
that a prolonged transition from Mesoproterozoic active single lid tectonics (1.6 to 1.0 Ga) to modern
plate tectonics occurred in the Neoproterozoic Era (1.0 to 0.541 Ga), which dramatically accelerated
emergence and evolution of complex species. We further suggest that both continents and oceans
are required for ACCs because early evolution of simple life must happen in water but late evolution
of advanced life capable of creating technology must happen on land. We resolve the Fermi Paradox
(1) by adding two additional terms to the Drake Equation: foc
(the fraction of habitable exoplanets
with significant continents and oceans) and fpt
(the fraction of habitable exoplanets with significant
continents and oceans that have had plate tectonics operating for at least 0.5 Ga); and (2) by
demonstrating that the product of foc
and fpt
is very small (< 0.00003–0.002). We propose that the lack
of evidence for ACCs reflects the scarcity of long-lived plate tectonics and/or continents and oceans on
exoplanets with primitive life.
A Giant Impact Origin for the First Subduction on EarthSérgio Sacani
Hadean zircons provide a potential record of Earth's earliest subduction 4.3 billion years ago. Itremains enigmatic how subduction could be initiated so soon after the presumably Moon‐forming giant impact(MGI). Earlier studies found an increase in Earth's core‐mantle boundary (CMB) temperature due to theaccumulation of the impactor's core, and our recent work shows Earth's lower mantle remains largely solid, withsome of the impactor's mantle potentially surviving as the large low‐shear velocity provinces (LLSVPs). Here,we show that a hot post‐impact CMB drives the initiation of strong mantle plumes that can induce subductioninitiation ∼200 Myr after the MGI. 2D and 3D thermomechanical computations show that a high CMBtemperature is the primary factor triggering early subduction, with enrichment of heat‐producing elements inLLSVPs as another potential factor. The models link the earliest subduction to the MGI with implications forunderstanding the diverse tectonic regimes of rocky planets.
Climate extremes likely to drive land mammal extinction during next supercont...Sérgio Sacani
Mammals have dominated Earth for approximately 55 Myr thanks to their
adaptations and resilience to warming and cooling during the Cenozoic. All
life will eventually perish in a runaway greenhouse once absorbed solar
radiation exceeds the emission of thermal radiation in several billions of
years. However, conditions rendering the Earth naturally inhospitable to
mammals may develop sooner because of long-term processes linked to
plate tectonics (short-term perturbations are not considered here). In
~250 Myr, all continents will converge to form Earth’s next supercontinent,
Pangea Ultima. A natural consequence of the creation and decay of Pangea
Ultima will be extremes in pCO2 due to changes in volcanic rifting and
outgassing. Here we show that increased pCO2, solar energy (F⨀;
approximately +2.5% W m−2 greater than today) and continentality (larger
range in temperatures away from the ocean) lead to increasing warming
hostile to mammalian life. We assess their impact on mammalian
physiological limits (dry bulb, wet bulb and Humidex heat stress indicators)
as well as a planetary habitability index. Given mammals’ continued survival,
predicted background pCO2 levels of 410–816 ppm combined with increased
F⨀ will probably lead to a climate tipping point and their mass extinction.
The results also highlight how global landmass configuration, pCO2 and F⨀
play a critical role in planetary habitability.
Constraints on Neutrino Natal Kicks from Black-Hole Binary VFTS 243Sérgio Sacani
The recently reported observation of VFTS 243 is the first example of a massive black-hole binary
system with negligible binary interaction following black-hole formation. The black-hole mass (≈10M⊙)
and near-circular orbit (e ≈ 0.02) of VFTS 243 suggest that the progenitor star experienced complete
collapse, with energy-momentum being lost predominantly through neutrinos. VFTS 243 enables us to
constrain the natal kick and neutrino-emission asymmetry during black-hole formation. At 68% confidence
level, the natal kick velocity (mass decrement) is ≲10 km=s (≲1.0M⊙), with a full probability distribution
that peaks when ≈0.3M⊙ were ejected, presumably in neutrinos, and the black hole experienced a natal
kick of 4 km=s. The neutrino-emission asymmetry is ≲4%, with best fit values of ∼0–0.2%. Such a small
neutrino natal kick accompanying black-hole formation is in agreement with theoretical predictions.
Detectability of Solar Panels as a TechnosignatureSérgio Sacani
In this work, we assess the potential detectability of solar panels made of silicon on an Earth-like
exoplanet as a potential technosignature. Silicon-based photovoltaic cells have high reflectance in the
UV-VIS and in the near-IR, within the wavelength range of a space-based flagship mission concept
like the Habitable Worlds Observatory (HWO). Assuming that only solar energy is used to provide
the 2022 human energy needs with a land cover of ∼ 2.4%, and projecting the future energy demand
assuming various growth-rate scenarios, we assess the detectability with an 8 m HWO-like telescope.
Assuming the most favorable viewing orientation, and focusing on the strong absorption edge in the
ultraviolet-to-visible (0.34 − 0.52 µm), we find that several 100s of hours of observation time is needed
to reach a SNR of 5 for an Earth-like planet around a Sun-like star at 10pc, even with a solar panel
coverage of ∼ 23% land coverage of a future Earth. We discuss the necessity of concepts like Kardeshev
Type I/II civilizations and Dyson spheres, which would aim to harness vast amounts of energy. Even
with much larger populations than today, the total energy use of human civilization would be orders of
magnitude below the threshold for causing direct thermal heating or reaching the scale of a Kardashev
Type I civilization. Any extraterrrestrial civilization that likewise achieves sustainable population
levels may also find a limit on its need to expand, which suggests that a galaxy-spanning civilization
as imagined in the Fermi paradox may not exist.
Jet reorientation in central galaxies of clusters and groups: insights from V...Sérgio Sacani
Recent observations of galaxy clusters and groups with misalignments between their central AGN jets
and X-ray cavities, or with multiple misaligned cavities, have raised concerns about the jet – bubble
connection in cooling cores, and the processes responsible for jet realignment. To investigate the
frequency and causes of such misalignments, we construct a sample of 16 cool core galaxy clusters and
groups. Using VLBA radio data we measure the parsec-scale position angle of the jets, and compare
it with the position angle of the X-ray cavities detected in Chandra data. Using the overall sample
and selected subsets, we consistently find that there is a 30% – 38% chance to find a misalignment
larger than ∆Ψ = 45◦ when observing a cluster/group with a detected jet and at least one cavity. We
determine that projection may account for an apparently large ∆Ψ only in a fraction of objects (∼35%),
and given that gas dynamical disturbances (as sloshing) are found in both aligned and misaligned
systems, we exclude environmental perturbation as the main driver of cavity – jet misalignment.
Moreover, we find that large misalignments (up to ∼ 90◦
) are favored over smaller ones (45◦ ≤ ∆Ψ ≤
70◦
), and that the change in jet direction can occur on timescales between one and a few tens of Myr.
We conclude that misalignments are more likely related to actual reorientation of the jet axis, and we
discuss several engine-based mechanisms that may cause these dramatic changes.
The solar dynamo begins near the surfaceSérgio Sacani
The magnetic dynamo cycle of the Sun features a distinct pattern: a propagating
region of sunspot emergence appears around 30° latitude and vanishes near the
equator every 11 years (ref. 1). Moreover, longitudinal flows called torsional oscillations
closely shadow sunspot migration, undoubtedly sharing a common cause2. Contrary
to theories suggesting deep origins of these phenomena, helioseismology pinpoints
low-latitude torsional oscillations to the outer 5–10% of the Sun, the near-surface
shear layer3,4. Within this zone, inwardly increasing differential rotation coupled with
a poloidal magnetic field strongly implicates the magneto-rotational instability5,6,
prominent in accretion-disk theory and observed in laboratory experiments7.
Together, these two facts prompt the general question: whether the solar dynamo is
possibly a near-surface instability. Here we report strong affirmative evidence in stark
contrast to traditional models8 focusing on the deeper tachocline. Simple analytic
estimates show that the near-surface magneto-rotational instability better explains
the spatiotemporal scales of the torsional oscillations and inferred subsurface
magnetic field amplitudes9. State-of-the-art numerical simulations corroborate these
estimates and reproduce hemispherical magnetic current helicity laws10. The dynamo
resulting from a well-understood near-surface phenomenon improves prospects
for accurate predictions of full magnetic cycles and space weather, affecting the
electromagnetic infrastructure of Earth.
Extensive Pollution of Uranus and Neptune’s Atmospheres by Upsweep of Icy Mat...Sérgio Sacani
In the Nice model of solar system formation, Uranus and Neptune undergo an orbital upheaval,
sweeping through a planetesimal disk. The region of the disk from which material is accreted by
the ice giants during this phase of their evolution has not previously been identified. We perform
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atmospheric enrichment could potentially produce sufficient latent heat to alter the planetary cooling
timescale according to existing models. Our findings suggest that substantial accretion during this
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thermal evolution of the ice giants, motivating future work on the fate of deposited solid material.
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Herschel galactic plane_survey_the_global_distribution_of_ism_gas_componnent
1. arXiv:1304.7770v3[astro-ph.GA]29May2013
Astronomy & Astrophysics manuscript no. distro˙paper c ESO 2013
May 30, 2013
A Herschel [C ii] Galactic plane survey I: the global distribution of
ISM gas components⋆
J. L. Pineda, W. D. Langer, T. Velusamy, and P. F. Goldsmith
Jet Propulsion Laboratory, California Institute of Technology, 4800 Oak Grove Drive, Pasadena, CA 91109-8099, USA
e-mail: Jorge.Pineda@jpl.nasa.gov
Received January 30, 2013; accepted April 11, 2013
ABSTRACT
Context. The [C ii] 158µm line is an important tool for understanding the life cycle of interstellar matter. Ionized carbon is present in
a variety of phases of the interstellar medium (ISM), including the diffuse ionized medium, warm and cold atomic clouds, clouds in
transition from atomic to molecular, and dense and warm photon dominated regions (PDRs).
Aims. Velocity–resolved observations of [C ii] are the most powerful technique available to disentangle the emission produced by
these components. These observations can also be used to trace CO–dark H2 gas and determine the total mass of the ISM.
Methods. The Galactic Observations of Terahertz C+ (GOT C+) project surveys the [C ii] 158µm line over the entire Galactic disk
with velocity–resolved observations using the Herschel/HIFI instrument. We present the first longitude–velocity maps of the [C ii]
emission for Galactic latitudes b = 0◦
, ±0.5◦
, and ±1.0◦
. We combine these maps with those of H i, 12
CO, and 13
CO to separate the
different phases of the ISM and study their properties and distribution in the Galactic plane.
Results. [C ii] emission is mostly associated with spiral arms, mainly emerging from Galactocentric distances between 4 and 10 kpc.
It traces the envelopes of evolved clouds as well as clouds that are in the transition between atomic and molecular. We estimate that
most of the observed [C ii] emission is produced by dense photon dominated regions (∼47%), with smaller contributions from CO–
dark H2 gas (∼28%), cold atomic gas (∼21%), and ionized gas (∼4%). Atomic gas inside the Solar radius is mostly in the form of
cold neutral medium (CNM), while the warm neutral medium (WNM) gas dominates the outer galaxy. The average fraction of CNM
relative to total atomic gas is ∼43%. We find that the warm and diffuse CO–dark H2 is distributed over a larger range of Galactocentric
distances (4–11 kpc) than the cold and dense H2 gas traced by 12
CO and 13
CO (4–8 kpc). The fraction of CO-dark H2 to total H2
increases with Galactocentric distance, ranging from ∼20% at 4 kpc to ∼80% at 10 kpc. On average, CO-dark H2 accounts for ∼30%
of the molecular mass of the Milky Way. When the CO–dark H2 component is included, the radial distribution of the CO–to–H2
conversion factor is steeper than that when only molecular gas traced by CO is considered. Most of the observed [C ii] emission
emerging from dense photon dominated regions is associated with modest far–ultraviolet fields in the range χ0 ≃ 1 − 30.
Key words. ISM: atoms —ISM: molecules — ISM: structure — Galaxy: structure
1. Introduction
The transition from atomic to molecular clouds, the formation
of stars within high density regions, the radiative feedback from
newly formed stars, and the disruption of molecular clouds and
termination of star formation are of great astrophysical inter-
est as they are processes governing the evolution of galaxies
in our Universe. In the Milky Way the evolution of the inter-
stellar medium (ISM) has traditionally been studied with radio
continuum and Hα observations for the ionized component (e.g.
Haffner et al. 2009), with observations of the H i 21 cm line for
the atomic gas component (e.g. Kalberla & Kerp 2009), and with
rotational transitions of the CO molecule for the dense molecu-
lar gas component (e.g. Dame et al. 2001). But observations of
the transition between these different stages of evolution with
velocity–resolved observations required to separate different gas
components along the line–of–sight (LOS) have been missing.
The [C ii] 158µm fine–structure transition is an excellent
tracer of the different stages of evolution of the ISM. As ionized
carbon (C+
) can be found throughout the ISM and can be excited
by collisions with electrons, H i, and H2, the [C ii] line traces
⋆
Herschel is an ESA space observatory with science instruments
provided by European-led Principal Investigator consortia and with im-
portant participation from NASA.
the warm ionized medium, the warm and cold diffuse atomic
medium, and warm and dense molecular gas. The [C ii] 158µm
line is the main coolant of the diffuse ISM and therefore plays a
key role in the thermal instability that converts from warm and
diffuse atomic clouds to cold and dense clouds. As the [C ii] in-
tensity is sensitive to column density, volume density, and kinetic
temperature, it can be used to determine the physical conditions
of the line–emitting gas.
The first sensitive all sky survey of line emission in the wave-
length range between 100µm and 1 cm was carried out with
the Far-Infrared Spectrometer (FIRAS) on COBE (Bennett et al.
1994). The angular resolution of COBE was 7◦
and the spec-
tral resolution of FIRAS was about 1000 km s−1
for the [C ii]
158µm and [N ii] 205µm lines. The COBE map showed that
[C ii] is widespread over the Galactic plane and that it is the
brightest far-infrared line. COBE also found a correlation be-
tween the [C ii], [N ii], and far–infrared (FIR) continuum emis-
sion, suggesting that [C ii] might be a good tracer of star-
formation activity in galaxies. The balloon-borne BICE mis-
sion (Nakagawa et al. 1998) observed [C ii] in the inner Galactic
plane with 15′
angular resolution and 175 km s−1
velocity resolu-
tion. This mission gave better constraints on the latitudinal distri-
bution of the Galactic [C ii] emission. The COBE and BICE mis-
sions did not have the required angular and velocity resolution to
1
2. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
resolve spatially and in velocity individual clouds in the Galactic
plane. The Kuiper Airborne Observatory allowed the study of
a handful of H ii regions with velocity-resolved [C ii] obser-
vations (e.g Boreiko et al. 1988; Boreiko & Betz 1991). These
observations, and also those recently obtained with Herschel
(e.g. Ossenkopf et al. 2012) and SOFIA (e.g. Graf et al. 2012),
were mostly limited to hot and dense photon–dominated regions
(PDRs) associated with massive star-forming regions.
Far–infrared (FIR) dust continuum emission has been
widely used as a mass tracer of the ISM, and several high–
resolution, large–scale, sensitive maps of the Galactic plane exist
(Carey et al. 2009; Molinari et al. 2010). Dust continuum emis-
sion is the result of the integrated contribution of different ISM
components distributed along the line–of–sight. Therefore, it is
impossible to use this emission to isolate and study the different
contributing ISM components, particularly for observations of
the Galactic plane.
The Herschel (Pilbratt et al. 2010) Open Time Key Project
Galactic Observations of Terahertz C+ (GOT C+; Langer et al.
2011) provides the first high–angular resolution (12′′
), velocity–
resolved (0.1 km s−1
) observations of the [C ii] line in the
Galactic disk, allowing us to resolve individual clouds and to
separate the different ISM components along the line–of–sight.
The GOT C+ survey consists of ∼500 LOSs distributed in a
volume-weighted sampling of the Galactic disk. We have com-
plemented our GOT C+ [C ii] data with observations of the H i
21 cm line, tracing diffuse atomic gas, and of CO and its iso-
topologues, tracing the dense molecular gas.
In this paper we present the full GOT C+ Galactic plane sur-
vey. We use the kinematic information provided by high ve-
locity resolution observations of [C ii], obtained with the HIFI
(de Graauw et al. 2010) instrument on Herschel, together with
complementary CO and H i surveys to study the structure of the
galaxy and to characterize the distribution of the different com-
ponents of the interstellar medium in the Milky Way.
Neutral atomic hydrogen represents the dominant gas com-
ponent of the interstellar medium in galaxies. This H i gas is pre-
dicted to exist in two phases in rough thermal pressure equilib-
rium (Pikel’Ner 1968; Field et al. 1969; Wolfire et al. 1995); the
cold neutral medium (nH ≃ 50 cm−3
; Tkin ≃80 K; CNM) and the
warm neutral medium (nH ≃ 0.5 cm−3
; Tkin ≃8000 K; WNM).
Note, however, that gas in thermally unstable conditions has
been observed (e.g Dickey et al. 1977; Heiles & Troland 2003)
and predicted in numerical simulations (see V´azquez-Semadeni
2012, and references therein). The atomic gas component has
been extensively mapped using the H i 21 cm line in the Milky
Way and external galaxies. But this line in emission traces only
the total column of gas along the line–of–sight (assuming that it
is optically thin), and therefore it is impossible to disentangle the
relative contribution from gas in the CNM or WNM. H i absorp-
tion studies of nearby clouds in the foreground of extragalac-
tic continuum sources have provided constraints on the relative
fraction of the CNM and WNM, suggesting that 60% of the gas
is in the WNM and 40% is in the CNM (Heiles & Troland 2003).
But these observations are limited to a small number of sources
distributed mostly at high Galactic latitudes, thus corresponding
only to the local ISM. We therefore lack the knowledge about
the distribution and conditions of the CNM and WNM over the
entire Galactic disk. The [C ii] 158µm line is also a tracer of the
diffuse neutral gas but has the advantage that it is also sensitive
to the density and temperature of the gas. In particular, because
of the density contrast between the CNM and WNM, for a given
H i column density the [C ii] emission associated with the WNM
is expected to be a factor of ∼20 weaker than that associated
with the CNM (Wolfire et al. 2010). We can therefore use the
GOT C+ [C ii] emission in combination with H i to study the dis-
tribution and properties of the WNM and CNM over the entire
Galactic disk.
The mass of molecular clouds has traditionally been traced
using observations of the CO molecule. However, the column
density from the cloud exterior to the location where hydrogen
becomes molecular is smaller than that required for carbon to
become molecular in the form of CO. It is therefore expected
that in the outer parts of molecular clouds a significant fraction
of the H2 is associated with C+
and C0
instead of with CO. This
gas is called “hidden–H2” or “dark–H2” gas (see Grenier et al.
2005; Langer et al. 2010; Wolfire et al. 2010). In this paper we
will refer to this component as “CO–dark H2 gas”. Indirect ob-
servations of gamma–rays (Grenier et al. 2005) and dust con-
tinuum emission (Planck Collaboration et al. 2011) suggest that
30–50% of the molecular mass in the Galaxy is not traced by
CO. The preliminary results from GOT C+, based on a sample
of 16 LOSs, reached a similar conclusion (Langer et al. 2010;
Velusamy et al. 2010). Velusamy et al. (2013) used a Gaussian
decomposition approach to study the GOT C+ LOS in the in-
ner Galaxy, −90◦
< l < 57◦
, discussing the distribution of the
[C ii] velocity components as a function of Galactocentric dis-
tance and the distribution of CO–dark H2 gas as function cloud
type (diffuse clouds, transition clouds, and dense clouds traced
by 13
CO). A more detailed analysis of the Gaussian decompo-
sition of the GOT C+ [C ii] emission in the inner galaxy will be
presented in Langer et al. (2013) in preparation. Note that some
of the H2 gas might not be traced by CO due to the lack of sen-
sitivity of the CO observations. In the Taurus molecular cloud,
Pineda et al. (2010a) found that 23% of the total mass is in the
outskirts of the cloud where neither 12
CO nor 13
CO could be de-
tected in single pixels, but both isotopologues could be readily
measured by averaging pixels over a large area.
A significant fraction of the FIR line and contin-
uum emission in galaxies originates from dense photon–
dominated regions (or photodissociation regions; or PDRs; see
Hollenbach & Tielens 1999 and references therein). In PDRs the
chemistry and thermal balance is dominated by the influence of
far–ultraviolet photons from massive stars. Therefore, PDRs are
the best sites for studying the radiative feedback from newly
formed massive stars on their progenitor molecular gas, a pro-
cess that plays a key role in the regulation of star–formation in
galaxies. The [C ii] line is a very bright tracer of PDRs and, to-
gether with fine–structure transitions of [O i] and [C i] and rota-
tional transitions of CO, can be used to determine the physical
conditions of the line–emitting regions. The FUV field inten-
sity is a key parameter for PDRs and is closely related to the
massive star–formation activity around PDRs. The FUV field
is often measured in units of the Draine (1978) field1
defined
as the average FUV intensity in the local ISM. Kaufman et al.
(1999) showed that the ratio of [C ii] to CO is a good tracer of
the strength of the FUV field in the galaxy. Using this line ratio
in a sample of 16 LOSs, Pineda et al. (2010b) found that most
of the dense PDRs have FUV fields lower than 100 times the in-
terstellar FUV field. With the complete GOT C+ survey, we can
1
The average FUV intensity of the local ISM is
2.2×10−4
erg cm−2
s−1
sr−1
(Draine 1978). The Draine field is isotropic
(i.e. a given point is illuminated from 4π steradians), while the surface
of the clouds considered here are only illuminated from 2π steradians,
therefore the rate of photoreactions at the cloud surface are half of what
they would be with the Draine field.
2
3. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
use the [C ii]/CO ratio to trace the strength of the FUV radiation
field over the entire Galactic disk.
This paper is organized as follows. In Section 2 we describe
the GOT C+ observations and data reduction. We also describe
the observations of ancillary CO and H i data. In Section 3.1 we
present position–velocity maps of the [C ii] emission and relate
them to the spiral structure of the Milky Way. In Section 3.2,
we present the distribution of the [C ii], H i, and CO emissivi-
ties as a function of Galactocentric distance. In Section 4, we
combine the [C ii], H i, and CO emission to identify the differ-
ent ISM components and determine their contribution to the ob-
served [C ii] emission. We describe the distribution of the warm
and cold neutral medium atomic gas components in Section 5.1.
In Section 5.2, we study the radial distribution of the CO–dark
H2 gas component and compare it to that of molecular gas traced
by CO and 13
CO. In Section 6 we present a determination of the
FUV field distribution in the Galactic plane. We summarize our
results in Section 7.
2. Observations
2.1. [C ii] observations
We surveyed the Galactic plane in the [C ii] 2
P3/2 →2
P1/2 fine
structure line at 1900.5469GHz (rest frequency) with the HIFI
(de Graauw et al. 2010) instrument on–board the Herschel space
observatory (Pilbratt et al. 2010). These observations are part of
the Herschel Open Time Key Project Galactic Observations of
Terahertz C+ (GOT C+), which is devoted to studying the [C ii]
158 µm line over a wide range of environments in the Galactic
plane, the Galactic center, and in the Outer Galaxy Warp. The
GOT C+ Galactic plane survey consists of 452 LOSs distributed
in an approximately volume–weighted sample of the Galactic
plane. We present a selection of GOT C+ lines–of–sight in [C ii],
H i, and 12
CO emission in Figure 1. The entire data set is pre-
sented as a set of position–velocity maps in Figure 2 and in
Appendix B. We sampled in Galactic longitude every 0.87◦
for
|l| < 60◦
, every 1.3◦
for 30◦
< |l| < 60◦
, and every 4.5◦
for
60◦
< |l| < 90◦
. In the Outer Galaxy (|l| > 90◦
), we sampled
in alternating steps varying from 4.5◦
to 13.5◦
. We sampled in
Galactic latitude 0.5◦
and 1.0◦
above and below the plane at
alternate positions in l. In 11 LOSs in the Outer Galaxy with
|l| > 90◦
, we sampled b = ±2.0◦
instead of ±0.5◦
.
The [C ii] 1.9 THz observations were carried out with
the HIFI Band 7b receiver, which is employs Hot Electron
Bolometer (HEB) mixers. The HEB bands in HIFI show promi-
nent electrical standing waves that are produced between the
HEB mixing element and the first low noise amplifier. The stand-
ing wave shape is not a standard sinusoid and is difficult to re-
move from the resulting spectrum using standard fitting meth-
ods (Higgins & Kooi 2009). To remove these standing waves
we used a procedure developed at the HIFI Instrument Control
Center (ICC; Ian Avruch priv. comm.) which generates a li-
brary of standing wave shapes from different observations and
finds the best fitting one to correct the observed spectrum (see
Higgins 2011 for a detailed description of this method). We pro-
cessed our data with this standing wave removal script in HIPE
(Ott et al. 2006) version 8. In HIPE we also removed residual
standing waves by fitting a single sinusoidal function using the
FitHIFIFringe() procedure. After all standing waves are re-
moved, we exported our data to the CLASS902
data analysis soft-
ware, which we used to combine different polarizations, fit poly-
2
http://www.iram.fr/IRAMFR/GILDAS
Fig. 1. A selection of GOT C+ lines–of–sight observed in [C ii],
H i, and 12
CO emission. Note that the [C ii] emission systemat-
ically extends closer to the tangent velocity compared with the
12
CO line, where it follows the distribution of the H i emission
(see Section 3.1).
nomial baselines (typically of order 3), and smooth the data in
velocity.
The angular resolution of the [C ii] observations is 12′′
. We
applied a main–beam efficiency of 0.72 to transform the data
from an antenna temperature to a main-beam temperature scale
(Roelfsema et al. 2012).
We used the data produced by the wide band spectrometer
(WBS), which have a channel width of 12 MHz (0.16 km s−1
at
1.9 THz). We later smoothed the data to a channel width of 0.8
3
4. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
HI
[CII]
CO
Fig. 2. Position velocity maps of H i, [C ii], and 12
CO J = 1 → 0 for the observed GOT C+ LOSs between l = −100◦
and 100◦
at b = 0◦
. We have overlaid the Scutum-Crux, Sagittarius Carina, Perseus, and Norma-Cygnus spiral arms projected onto the
position–velocity maps (see Section 3.1).
4
5. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 3. Projections in the Galactic longitude–velocity map of the Scutum-Crux, Sagittarius Carina, Perseus, and Norma-Cygnus
spiral arms (see Section 3.1). The distance to the Galactic center is color coded according to the scale shown at the right.
km s−1
. For this channel width the average rms noise of our data
is3
0.1 K.
As we expected the [C ii] emission to be extended in the
Galactic plane, we used the LoadChop with reference observing
mode. In this observing mode an internal cold calibration source
is used as a comparison load to correct short term changes in
the instrument behavior. Since the optical path differs between
source and internal reference, a residual standing wave struc-
ture remains and is corrected with an observation of a sky refer-
ence position. For a given Galactic longitude, LOSs with b = 0◦
,
±0.5◦
and ±1.0◦
share the same reference position at b = ±2.0◦
.
In the 11 Outer Galaxy positions where we observed b = 0◦
,
±1.0◦
, and ±2.0◦
, we used the b = ±2.0◦
as a reference for
b = 0◦
, ±1.0◦
and b = ±4.0◦
as a reference for b = ±2.0◦
. We re-
covered the reference spectrum (OFF) using HIPE by subtracting
from the ON–OFF spectrum a spectrum for which the reference
subtraction step in the HIFI pipeline was suppressed. The result-
ing spectra include a standing wave with period ∼90 MHz. We
combined all observations of the reference spectrum in CLASS90
and removed the standing wave using a Fast Fourier Transform
(FFT) procedure. In the cases where emission in the reference
position is present, we decomposed this emission into Gaussian
components and corrected the ON–source spectra appropriately.
A total of 51% of the GOT C+ spectra were corrected for emis-
sion in the reference position.
3
For the typical [C ii] FWHM line width of about 3 km s−1
(Langer
et al. 2013 in preparation), this sensitivity limit corresponds to 1.1×10−6
erg s−1
cm−2
sr−1
. The integrated intensity in units of K km s−1
can be
converted that in units of erg s−1
cm−2
sr−1
using I[K km s−1
]=1.43 ×
105
I[erg s−1
cm−2
sr−1
] (Goldsmith et al. 2012).
2.2. CO observations
To complement the GOT C+ data, we observed the J = 1 → 0
transitions of 12
CO, 13
CO, and C18
O with the ATNF Mopra4
Telescope. We observed all GOT C+ positions towards the inner
Galaxy between l = −175.5◦
and l = 56.8◦
with an angular res-
olution of 33′′
. Typical system temperatures were 600, 300, and
250 K for 12
CO, 13
CO, and C18
O, respectively. To convert from
antenna to main–beam temperature scale, we used a main-beam
efficiency of 0.42 (Ladd et al. 2005). All lines were observed si-
multaneously with the MOPS spectrometer in zoom mode. The
spectra were smoothed in velocity to 0.8 km s−1
for 12
CO and
13
CO and to 1.6 km s−1
for C18
O. The typical rms noise is 0.6 K
for 12
CO and 0.1 K for both 13
CO and C18
O. We checked point-
ing accuracy every 60 minutes using the closest and brightest
SiO maser. For 102◦
< l < 141◦
, we used the 12
CO J = 1 → 0
data from the FCRAO Outer Galaxy survey (Heyer et al. 1998).
The data have an angular resolution of 45′′
, and a rms noise of
about 0.6 K in a 0.8 km s−1
channel.
2.3. H i data
We used supplementary H i 21 cm data taken from the Southern
Galactic Plane Survey (SGPS; McClure-Griffiths et al. 2005),
the Canadian Galactic Plane Survey (CGPS; Taylor et al. 2003),
and the VLA Galactic Plane Survey (VGPS; Stil et al. 2006).
These surveys combined cover the 253◦
< l < 67◦
portion of
the Galactic plane. The SGPS (253◦
< l <358◦
) data have an an-
gular resolution of 2′
, and a rms noise of 1.6 K per 0.8 km s−1
channel. The CGPS covers 74◦
< l <147◦
, with an angular res-
olution of 1′
, and a rms noise of 2 K in a 0.82 km s−1
channel.
Finally, the coverage of the VGPS is 18◦
< l <67◦
, with an an-
gular resolution of 1′
, and a rms noise of 2 K in a 0.82 km s−1
channel. For the Galactic center we used the data presented by
4
The Mopra radio telescope is part of the Australia Telescope which
is funded by the Commonwealth of Australia for operation as a National
Facility managed by CSIRO.
5
6. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
McClure-Griffiths et al. (2012) which have parameters similar to
those of the SGPS. We also used the GALFA–H i Arecibo survey
(Peek et al. 2011) to cover the Galactic longitude range between
180◦
< l <212◦
. The GALFA–H i data have an angular resolution
of 4′
and a typical rms noise of 80 mK in a 1 km s−1
channel.
3. The Distribution of [C ii] in the Milky Way
3.1. Position–Velocity Maps
In Figure 2 we present the GOT C+ survey in a set of position-
velocity maps for b = 0◦
. The corresponding position–velocity
maps for ±0.5◦
, and ±1.0◦
are presented in Appendix B. The ob-
served [C ii] emission peaks at b = 0◦
and decreases for LOSs
above and below the Galactic plane. Most of the [C ii] is con-
centrated in the inner galaxy (−60◦
≤ l ≤60◦
). The position–
velocity map is overlaid with projections of the Scutum-Crux,
Sagittarius-Carina, Perseus, and Norma-Cygnus5
Milky Way
spiral arms. We used the fits to the parameters determining
the logarithmic spiral arms presented by Steiman-Cameron et al.
(2010) and assumed a flat rotation curve the distance of the Sun
to the Galactic center, R⊙ = 8.5 kpc, and an orbital velocity of the
sun with respect to the Galactic center, V⊙ = 220 km s−1
, which
are the values recommended by the International Astronomical
Union (IAU). We show the projected spiral arms in the range
of Galactocentric distance between 3 kpc and 25 kpc. We can
see that most of the [C ii] emission is closely associated with
the spiral arms and it is brightest at the spiral arms’ tangent
points. In Figure 3, we plot the spiral arms with a color scale
that represents the Galactocentric distance. Comparing Figure 3
with the panels in Figure 2, we see that the [C ii] emission is
mostly concentrated within the inner 10 kpc of the Galaxy (see
also Section 3.2). The [C ii] emission is slightly shifted with re-
spect to that of 12
CO, with the [C ii] emission present at veloci-
ties that are closer to the tangent velocity. This shift can also be
seen near the tangent velocities in the sample spectra shown in
Figure 1. This suggests that the [C ii] emission traces an inter-
mediate phase between the extended H i emission and the cold
and dense molecular gas traced by 12
CO.
3.2. Radial Distribution Plots
In the following we study the distribution of the [C ii] emission
as a function of Galactocentric radius. We divided the galaxy
in a set of rings with a distance to the Galactic center Rgal and
width ∆R = 0.5 kpc. For each of these rings, we calculated
the azimuthally–averaged integrated intensity per unit length or
emissivity of the [C ii] line. We describe the procedure used to
determine these emissivities in Appendix A.
In Figure 4 we present the azimuthally averaged emissivity
of [C ii] as a function of Galactocentric radius. The [C ii] emis-
sion shows a main peak at 4.2 kpc and a secondary peak at ∼ 6
kpc. As mentioned above, the [C ii] emission is concentrated in
the inner 10 kpc of the Galaxy. When we separate the contri-
bution from LOSs with l = 0 − 180◦
and l = 180 − 360◦
, we
can see that the peak at 4.2 kpc originates from LOSs in the
l = 0 − 180◦
range while the peak at 6 kpc originates from LOSs
in the l = 180−360◦
range. This difference in the emissivity dis-
tribution between both sides of the Galaxy illustrates the mag-
nitude of the intrinsic scatter within the rings, which is a result
of the fact that the Galaxy is not axisymmetric. Because the aim
5
The Norma-Cygnus arm is also known as the Norma-3 kpc arm
(e.g. Vall´ee 2008).
Fig. 4. Radial distribution of the azimuthally averaged [C ii]
emissivity at b = 0◦
. The shaded area represents the emissiv-
ity calculated considering all sampled Galactic longitudes. The
connected boxes represent the radial emissivity distribution for
0◦
< l < 180◦
, while the connected circles represent that for
180◦
< l < 360◦
. The typical 1σ uncertainty in the [C ii] emissiv-
ity is 0.02 K km s−1
kpc−1
.
of our analysis is to describe the average properties of the ISM
within a Galactocentric ring, we only consider the uncertainties
that describe how accurately this azimuthal average emissivity
is determined. These uncertainties are generally very small, as
they are the result of averaging over a large number of data val-
ues. In many figures the error–bars are too small to be visible,
especially when the emissivity vary over a large range, and we
will quote them in the figure captions. Note that in most cases
the uncertainties in the assumptions of our modelling are much
larger than those indicated by the observational error–bars.
In Figure 5 we show the contributions to the [C ii] emissivity
from the different spiral arm tangents. We consider LOSs in 12◦
–
wide bins in Galactic longitude centered at the spiral arm tan-
gent locations defined by Vall´ee (2008). Note that different spi-
ral arms can be seen in this set of LOSs, but the peak of the [C ii]
emission corresponds to the tangent of the spiral arm. The peak
at 4.2 kpc is associated with the Scutum–Crux tangent while the
6 kpc peak is related to the combined emission from the Start
of Perseus (peak at 4.7 kpc), Norma-Cygnus (peak at 5.7 kpc),
and Crux–Scutum (peak at 6.7 kpc) tangencies. The Sagittarius–
Carina (peak at 6.2 kpc) and Carina–Sagittarius (peak at 8.7 kpc)
make a smaller contribution. Figure 5 shows that the brightest
[C ii] emission in the GOT C+ survey arises from the Scutum–
Crux tangent at 4.2 kpc.
In Figure 6 we show the radial distribution of the [C ii] emis-
sivity from LOSs with b = 0◦
, b = ±0.5◦
, and b = ±1.0◦
, and
for all observed LOSs together. The [C ii] peak at 4.2 kpc from
the Scutum-Crux arm is only seen for b = 0◦
, while the intensi-
ties from b = ±0.5◦
, b = ±1.0◦
mostly contribute to the inten-
sity at 5.2 kpc from the Galactic center. The shift in the peak of
the radial distribution for |b| >0◦
is related to the vertical struc-
6
7. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 5. Radial distribution of the azimuthally averaged [C ii]
emissivity for GOT C+ LOSs toward the tangents of spiral arms
as defined by Vall´ee (2008).
Fig. 6. Radial distribution of the azimuthally averaged [C ii]
emissivity for LOSs at b = 0◦
, b = ±0.5◦
, b = ±1.0◦
, and for all
observed LOSs together.
ture of the Galactic disk. A cloud with Rgal = 5 kpc observed
in a LOS with |b|=1◦
would have a vertical distance from the
Galactic plane of ∼65 pc, assuming that it is in the near side of
the Galaxy, while a cloud with Rgal = 4 kpc, in the same situa-
tion, would have a vertical distance of ∼100 pc. A Gaussian fit
to the latitudinal [C ii] distribution observed by BICE (see Fig.
9 in Nakagawa et al. 1998) results in an angular FWHM of the
Galactic disk of 1.9◦
. Assuming that most of their observed [C ii]
Fig. 7. Radial distribution of the azimuthally averaged [C ii], H i,
and 12
CO emissivities at b = 0◦
. The discontinuity in the H i
emissivity distribution at ∼9 kpc is discussed in Section 5.1.
Typical 1σ uncertainties in the [C ii], H i, and 12
CO emissivities
(before scaling) are 0.02, 0.6, and 0.1 K km s−1
kpc−1
, respec-
tively.
emission is in the near side of the Galaxy at a heliocentric dis-
tance of about 4 kpc, this angular FWHM corresponds to 130 pc.
Our inability to detect a peak of emission at 4 kpc for |b| > 0◦
seems to be consistent with this value of the [C ii] disk thick-
ness. Results on the vertical structure of the Galactic disk using
the GOT C+ data will be presented in a future paper.
In Figure 7, we compare the radial distributions of the [C ii],
12
CO, and H i emissivities. Typical 1σ uncertainties in the [C ii],
H i, and 12
CO emissivities are 0.02, 0.6, and 0.1 K km s−1
kpc−1
,
respectively. We see that both [C ii] and 12
CO are mostly con-
centrated in the 4–10 kpc range, peaking at 4.25 kpc. The dis-
tribution of the H i emissivities extends over a larger range of
Galactocentric distances, with a peak at 5 kpc.
Table 1. Definition of Mask Regions
Mask H i [C ii] 12
CO 13
CO
0 × × ×
1 × ×
2 × ×
3 ×
4
: Emission is detected in individual spaxels.
×: Emission is not detected.
×: Emission is either detected or not detected.
7
8. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 8. Position velocity maps of the different types of regions defined in Section 4.1 at b = 0◦
. Mask 0 (grey) represents velocity
components with only H i detected, Mask 1 (white) are components with only H i and CO detected, Mask 2 (blue) components with
only H i and [C ii], Mask 3 (black) components with H i, [C ii], and CO, and Mask 4 (red) components with H i, [C ii], 12
CO, and
13
CO.
4. The origin of the [C ii] emission in the Galaxy
4.1. Velocity Components
In the following, we associate the [C ii] emission with other
tracers in order to separate the contribution from different ISM
phases to the observed emission. We define 5 mask regions
that represent different stages of the ISM evolution depending
whether H i, [C ii], 12
CO, and 13
CO are detected in an individual
pixel in the position–velocity map (spaxel). We define Mask 0
as those spaxels in which H i emission is detected but [C ii],
CO, and 13
CO not. These regions likely represent low–volume
density atomic gas (see Section 5.1). Mask 1 includes spaxels in
which H i and 12
CO (or 13
CO) are detected but [C ii] is not. These
spaxels trace dense molecular gas that is too cold for [C ii] to be
detectable at the sensitivity limit of the observations. Mask 2 are
spaxels where H i and [C ii] are detected but 12
CO is not. These
regions are likely larger volume density atomic clouds that have
insufficient FUV–photon shielding to allow the build–up of CO
and therefore in which most of the gas–phase carbon is in the
form of C+
. Mask 3 includes spaxels in which H i, [C ii], and
12
CO are detected but 13
CO is not. These regions represent more
shielded regions where CO is forming but with inadequate col-
umn density to have detectable 13
CO emission at the sensitivity
of our observations. Finally, Mask 4 includes spaxels in which
H i, [C ii], 12
CO, and 13
CO are all detected. These regions likely
represent PDRs that have large volume and column densities
and are warm enough to produce significant [C ii] emission. In
Table 1 we present a summary of the Mask region definitions.
In Figure 8 we present the distribution of the different Masks
in the position–velocity map of the Galaxy for −60◦
< l <60◦
and b = 0◦
. We present similar position–velocity maps for
b = ±0.5◦
and ±1.0◦
in Appendix B (Figure B.5). The dense
PDRs (Mask 4) are closely associated with the spiral arms. These
regions are surrounded with spaxels in Mask 3 which, in turn,
are surrounded with spaxels in Mask 2. We suggest that this spa-
tial arrangement indicates that Mask 3 and Mask 2 represent the
envelopes of the active star–forming regions traced by Mask 4.
There is a significant fraction of spaxels in Mask 1, particu-
larly in the molecular ring and local arms. Mask 0 represents the
largest fraction of spaxels.
Figure 9 presents the intensity distribution of H i, [C ii],
12
CO, and 13
CO for the different Mask regions defined above
for b = 0◦
. Although by definition Masks 0 and 1 have no [C ii]
emission in a given spaxel, its emission can still be seen when the
8
9. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 9. Galactocentric distribution of the different types of re-
gions defined in Section 4.1. The plots include data from all
LOSs at b = 0◦
, b = ±0.5◦
, and b = ±1.0◦
.
data is averaged over the different rings. The same result happens
with 13
CO in Mask 3. The detection of emission after averaging
the data in azimuth shows that our classification into Masks de-
pends on the sensitivity of our observations. We will study the
[C ii] emission in Mask 0 and 1 and the 13
CO emission in Mask 3
separately as they represent a different population of clouds that
are weak in [C ii] and 13
CO, respectively.
4.2. Atomic gas
We first assumed that all the observed [C ii] emission arises from
a purely atomic gas at a kinetic temperature Tkin = 100 K. For
optically thin emission, the [C ii] intensity (in units of K km s−1
)
is related to the C+
column density, NC+ ( cm−2
), and volume
density of the collisional partner, n (e−
, H, or H2; cm−3
), as (see
e.g. Goldsmith et al. 2012),
I[CII] = NC+ 3.05 × 1015
1 + 0.5 1 +
Aul
Ruln
e91.21/Tkin
−1
, (1)
where Aul = 2.3 × 10−6
s−1
is the Einstein spontaneous decay
rate and Rul is the collisional de–excitation rate coefficient at a
kinetic temperature Tkin. We used a value of Rul for collisions
with H at Tkin = 100 K of 8.1×10−10
s−1
cm−3
(Launay & Roueff
1977). In the optically thin limit we can estimate the atomic gas
column density, N(H), from the H i 21 cm observations using,
N(H) = 1.82 × 1018
I(HI) cm−2
, with I(HI) in units of K km s−1
.
Observations of H i absorption toward continuum sources, how-
ever, suggest that the opacity of H i increases toward the inner
Galaxy, where the assumption of optically thin emission might
not apply. Kolpak et al. (2002) derived an average value, assum-
ing Tkin = 50 K, of τ ≃ 1 for Rgal < 8.5 kpc. For our assumed
Tkin = 100 K, this opacity corresponds to τ ≃ 0.5. We used
this opacity to correct the H i column densities derived from the
21 cm line that is associated with [C ii] emission, resulting in a
30% increase in the derived column density.
The column density of ionized carbon can be estimated
from N(H i) assuming an appropriate [C]/[H] fractional abun-
dance, provided that all gas–phase carbon is in the form of
C+
. There is evidence that the gas–phase abundance of met-
als in the Milky Way decreases with Galactocentric distance.
Rolleston et al. (2000) found that the fractional abundance dis-
tribution of several light elements (C, O, Mg & Si) can be rep-
resented by a linear function with slope −0.07 ± 0.01 dex kpc−1
over 6 kpc < Rgal < 18 kpc . We use this relationship to convert
N(H) to N(C+
) for any given galactocentic distance, assuming
that the slope of the relative abundance gradient does not change
significantly for Rgal < 6 kpc. We assume a [C]/[H] fractional
abundance of 1.4 × 10−4
for Rgal = 8.5 kpc (Cardelli et al. 1996).
The [C]/[H] abundance as a function of Galactocentric distance
is thus given by
[C]/[H] = 5.5 × 10−4
10−0.07Rgal
. (2)
The [C]/[H] abundance drops by a factor of 2.6 from Rgal = 4
kpc to 10 kpc.
With the estimated value of N(C+
) we used Equation (1) to
solve for the volume density of H i that is required to match
the observed [C ii] emission, under the assumption that all ob-
served [C ii] emission comes from atomic gas. In Figure 10a, we
present the distribution of hydrogen volume densities as a func-
tion of Galactocentric distance for the different Mask regions for
4 kpc < Rgal < 11 kpc, which is the range of Rgal in which most of
the [C ii] emission is detected. The H volume density increases
toward the Galactic center with a range between 100 cm−3
to
103
cm−3
for Masks 2, 3 and 4. For Masks 0 and 1 the vol-
ume densities are more moderate, ranging from 20 to 80 cm−3
.
In Figure 10b, we present the corresponding thermal pressures
(p/k = nTkin) as a function of Galactocentric distance for the
9
10. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 10. (Upper panel) Neutral hydrogen volume density as a
function of Galactocentric distance for the Mask regions defined
in Section 4.1, assuming that all [C ii] is associated with atomic
gas at Tkin = 100 K. (Lower panel) Corresponding thermal pres-
sure as a function of Galactocentric distance.
different Mask regions. We also show the thermal pressure dis-
tribution suggested by Wolfire et al. (2003),
p/k = 1.4 × 104
exp
−Rgal
5.5 kpc
K cm−3
, (3)
corresponding to the predicted thermal pressure of the CNM gas.
Masks 0 and 1 have thermal pressures that are consistent with
those suggested by Wolfire et al. (2003). Thus, the densities and
thermal pressures estimated in Masks 0 and 1 are consistent with
their [C ii] emission originating from the CNM. Masks 2, 3, and
4 have volume densities and thermal pressures that are about
one order of magnitude larger than those observed and predicted
for the CNM. We therefore conclude that the assumption that
the [C ii] emission in Masks 2, 3, and 4 originates entirely from
atomic gas is incompatible with our observations. As we will
discuss below, part of the observed [C ii] emission in Masks 2, 3,
and 4 also emerges from molecular, and to a lesser extent, from
ionized gas.
Motivated by the agreement between the pressures derived in
Masks 0 and 1 and those predicted in Equation (3), we used this
expression to estimate, assuming a constant Tkin = 100 K, the
radial H volume density distribution the atomic gas associated
with Masks 2, 3, and 4. We then used Equation (1) to estimate
the contribution from CNM gas to the observed [C ii] emission
in these Mask regions. Note that for a given thermal pressure, the
intensity of [C ii] associated with H i has a only weak dependence
on the assumed kinetic temperature, varying by about ±20% in
the range between 60 and 200 K.
In Figure 11 we show the resulting contribution from atomic
gas to the [C ii] intensity as a function of the Galactocentric dis-
tance. We estimate that the contribution from [C ii] emerging
from the atomic gas component represents 21% of the observed
intensity.
4.3. Ionized gas
It has been suggested that a significant fraction of the [C ii]
emission in the Galaxy observed by COBE emerges from the
Extended Low Density Warm Ionized Medium (ELDWIM;
Petuchowski & Bennett 1993; Heiles 1994). We estimated the
contribution to the observed [C ii] emission from an ionized gas
using the Galactic distribution of the electron density used by
the NE2001 code (Cordes & Lazio 2002). The NE2001 code as-
sumes a Galactic distribution of the electron density, including a
thin and thick disk, spiral arms (four), and Galactic center com-
ponents. This electron density distribution is further constrained
using observations of the dispersion measure of pulsars.
We used the NE2001 model to extract the electron density
as a function of heliocentric distance for all GOT C+ lines–of–
sight in the Galactic plane. For each step in heliocentric distance
we also calculate the column density of electrons and, assuming
the [C]/[H] gradient (Equation 2), the column density of C+
as-
sociated with the ionized gas. We estimate the [C ii] intensity as
a function of heliocentric distance for each line–of–sight using
Equation (1), assuming a kinetic temperature of 104
K, and ex-
citation by collisions with electrons (Rul = 4.8 × 10−8
s−1
cm−3
;
Wilson & Bell 2002). The term involving the kinetic tempera-
ture in Equation (1) becomes unity for such a large temperature,
therefore the intensity of [C ii] associated with ionized gas is in-
sensitive to the kinetic temperature. Note that the NE2001 model
is smooth and can only reproduce the electron density distribu-
tion over large scales. Finally, we calculated the distribution of
the [C ii] emissivity as a function of Galactocentric distance tak-
ing the same considerations as described in Appendix A. The
resulting radial distribution is shown in Figure 11. We estimated
that the contribution from [C ii] arising from ionized gas repre-
sents only 4% of the total observed intensity.
Velusamy et al. (2013) observed an excess of [C ii] emission
at the tangent velocities towards the Scrutum–Crux spiral arms
tangent which was interpreted as coming from compressed ion-
ized gas. They suggested that this compression of ionized gas
is the result of the passing of a spiral arm density wave. Note,
however, that this excess can only be detected toward spiral arm
tangencies due to a projection effect by which the path length
toward a spiral arm is maximized. We therefore do not expect a
10
11. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
significant contribution from this excess to the overall observed
[C ii] intensity.
Note that our estimation of the contribution from ionized gas
to the observed [C ii] emission corresponds only to that for lines–
of–sight in the Galactic plane with b=0◦
. The ELDWIM gas is
known to have a scale height of about 1 kpc (Kulkarni & Heiles
1987; Reynolds 1989), which is much larger than that of the
atomic and molecular gas (∼ 100 − 300 pc). Thus, the con-
tribution from ionized gas to the total [C ii] luminosity of the
Galaxy should be larger than what is suggested by the emissiv-
ities at b = 0◦
. At a distance from the Sun of 4 kpc, a 1 kpc
scale height corresponds to 14◦
. Thus, within the a 7◦
beam of
COBE, the [C ii] emission from the ionized component fills the
beam, while the emission from the Galactic plane (vertical an-
gular scale ∼2 deg; Nakagawa et al. 1998) will be significantly
beam diluted. The [C ii] emission from the Galactic plane and
that from the extended ionized medium should appear compa-
rable within a COBE beam, as suggested by several analyses
(Petuchowski & Bennett 1993; Heiles 1994). A detailed analy-
sis of the relationship between the Herschel/HIFI [C ii] observa-
tions and those from COBE/FIRAS will be presented in a future
paper.
4.4. Dense photon-dominated regions
It is possible that a significant fraction of the observed [C ii] in-
tensity in the Galactic plane comes from dense PDRs, as obser-
vations of Galactic and extragalactic PDRs have shown that they
are the sources of bright [C ii] emission (e.g. Stacey et al. 1991;
Boreiko et al. 1988). Note that the main–beam temperatures in
the GOT C+ survey are mostly in the 0.5–8K range, with only a
few spaxels with Tmb >8 K (see Fig. 7 in Goldsmith et al. 2012).
This range of main beam temperatures is well below that ob-
served in nearby star–forming regions such as Orion (∼100 K)
which are powered by the intense FUV radiation field produced
by nearby massive stars. Bright PDRs are, however, not numer-
ous enough to dominate the global [C ii] emission in the Milky
Way. In Section 6 (see also Pineda et al. 2010a) we found that
most of the [C ii] emission in the Galactic plane arises from
regions which are exposed to moderate–strength FUV fields,
in agreement with models of the Galaxy based on COBE data
(Cubick et al. 2008). We considered [C ii] velocity components
associated with 13
CO (Mask 4) as likely to be associated with
dense and warm PDRs. Such regions have large enough column
densities, and presumably sufficient volume densities, to pro-
duce detectable 13
CO emission while they are also warm enough
to produce detectable [C ii] emission. We determined the con-
tribution from dense PDRs to the observed [C ii] intensity in
Mask 4 by subtracting the [C ii] emission associated with atomic
gas, as determined in Section 4.2. The resulting radial distribu-
tion of the [C ii] emissivity associated with dense PDRs is shown
as a red-dashed line in Figure 11. The [C ii] emission emerging
from dense PDRs represents 47% of the total emission observed
in the GOT C+ survey.
4.5. [C ii] Excess
The combined contribution to the [C ii] emission from atomic
gas, ionized gas, and dense PDRs, as estimated above, can ac-
count for only 72% of the observed emission. It has been sug-
gested the remaining [C ii] emission is produced in the envelopes
of dense molecular clouds where the H i/H2 transition is largely
complete, but the column densities are low enough that the
Fig. 11. Azimuthally–averaged radial distribution of the ob-
served [C ii] emissivity in Masks 2, 3, and 4 together with the
different contributions from the ISM components discussed in
Section 4. Typical uncertainties are 0.02 K km s−1
kpc−1
for the
total [C ii] emission and that contributed from dense PDRs, and
0.001 K km s−1
kpc−1
for the contribution from H i gas. For the
contribution from ionized gas, we assume 30% uncertainties or
0.07 K km s−1
kpc−1
.
C+
/C0
/CO transition is not (e.g Madden et al. 1997; Langer et al.
2010). Since this H2 gas component is not traced by CO, but by
[C ii] and to a lesser extent by [C i], we refer to it as “CO–dark
H2 gas”. In the following section we derive the distribution of
the CO–dark H2 gas in the plane of the Milky Way, and compare
it to that traced by 12
CO and 13
CO.
5. The distribution of the ISM components in the
plane of the Milky Way
5.1. The Warm and Cold Neutral Medium
As mentioned earlier, atomic gas is predicted to be in two
phases in roughly thermal pressure equilibrium, the Cold Neutral
Medium (CNM; nH ≃ 50 cm−3
; Tkin ≃80 K) and the Warm
Neutral Medium (WNM; nH ≃ 0.5 cm−3
; Tkin ≃8000 K).
Because atomic hydrogen is one of the main collisional part-
ners of C+
, the [C ii] line is a tracer of atomic gas that has the
advantage over the 21 cm line (observed in emission) that it is
sensitive to both the volume density and the kinetic temperature
of the gas (Equation 1). Thus, the [C ii] line should in principle
trace both the WNM and CNM atomic gas components. In prac-
tice, however, because of the volume density contrast between
the CNM and WNM, the [C ii] line is expected to be significantly
weaker for WNM gas compared to the emission from CNM gas
(Wolfire et al. 2010). For the H i peak intensity of 160K (in a
0.8 km s−1
channel width) at the 5 kpc ring, and considering the
abundance and thermal pressure gradients (Equation 2 and 3, re-
spectively), we can use Equation (1), assuming 100 K for the
CNM and 8000 K for the WNM, to estimate a [C ii] intensity as-
sociated with H i of 0.3K in the case that all gas is CNM, and of
11
12. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 12. Radial distribution of the azimuthally averaged total H i
column density in the Galactic plane. We also include the es-
timated radial distribution of the cold neutral medium (CNM)
and warm neutral medium (WNM) gas. Typical uncertainties of
the H i column densities are 1018
cm−2
kpc−1
. The vertical line
shows the Solar radius. At 9 kpc there is a discontinuity in the
total and WNM N(H i) distribution which is attributed to the
abrupt change between the number of rings sampled in the inner
and outer Galaxy. We therefore also show lines that smoothly
connect the distributions in the inner and outer Galaxy.
0.04K in case all gas is WNM. Considering our 3σ sensitivity
limit per channel of 0.3 K we find that weak CNM gas can be
detected, while WNM gas would be too weak to be detected in
individual spaxels.
When azimuthally averaging (Section 4.2), however, [C ii]
emission associated with CNM can produce a significant con-
tribution to the observed [C ii] emissivity. For the Rgal =
5 kpc peak of 1.4 × 1021
cm−2
kpc−1
, we find a contribu-
tion of 1.1 K km s−1
kpc−1
for all H i gas in CNM, and
0.04 K km s−1
kpc−1
for all H i gas in WNM. As the 3σ sen-
sitivity limit for the azimuthal average is 0.06 K km s−1
kpc−1
(Appendix A), we see that WNM is always below the sensitivity
limit even for the azimuthal average. This suggests that only the
CNM can contribute to the observed [C ii] emission. We there-
fore assume that spaxels that have both H i and [C ii] emission
(Masks 2, 3, and 4) are associated with CNM gas. In our survey,
there are also spaxels where H i and 12
CO emission are detected
but [C ii] emission is not (Mask 1). These regions are likely too
cold and/or have too low volume densities for [C ii] to be de-
tected, but can still be associated with cold H i gas. We therefore
also consider H i associated with Mask 1 as being in the CNM
phase. Finally, we consider spaxels with H i but neither [C ii] nor
12
CO emission (Mask 0) to be associated with WNM gas. In the
following we use this criteria to separate the CNM and WNM
components from the observed H i emission and study their dis-
tribution in the plane of the Milky Way.
It is possible that some spaxels have [C ii] emission that is
below the sensitivity limit for individual spaxels but can still be
detected in the azimuthal average. In Figure 9, we see that [C ii]
emission (∼0.1 K km s−1
kpc−1
) in the inner galaxy can be de-
tected in the region where only H i is detected in the pointed ob-
Fig. 13. Radial distribution of the mass fraction of the atomic gas
in the cold neutral medium (CNM). The horizontal line shows
the local mass fraction of the CNM derived by Heiles & Troland
(2003). The vertical line denotes the solar radius. The typical
uncertainty in the ratio is ∼0.002.
servations (Mask 0). The average H i column for Rgal = 3−8 kpc
(∼ 1 × 1020
cm−2
kpc−1
), would imply a [C ii] emissivity of
about 0.17 K km s−1
kpc−1
in the case that all gas is CNM and
0.006 K km s−1
kpc−1
in the case that all gas is WNM. Thus, the
emission detected in Mask 0 can only be associated with CNM
gas. Note that for the inner galaxy, when we associate H i with
[C ii] and/or 12
CO emission in individual spaxels, we are assum-
ing that the H i and [C ii] and/or 12
CO emission arises from both
the near and far side of the Galaxy. We could in principle over-
estimate the H i column density associated with the CNM in the
case that the [C ii] and/or 12
CO emission arises from either the
near or far side of the galaxy, but H i from both sides. We con-
sider this situation unlikely, however, as we expect that the phys-
ical conditions within a galactocentric ring to be relatively uni-
form. The maximum effect, in the case that all LOSs in the inner
galaxy are affected, is a reduction of the azimuthally averaged
CNM column density by a factor of ∼2 (and a corresponding
increase of the WNM column density by the same factor).
In Figure 12, we show the radial distribution of the total
H i column density together with that of the contributions from
CNM and WNM gas. The column densities are estimated from
the H i emissivity distributions which are in turn calculated con-
sidering all spaxels with H i emission as well as those associ-
ated with CNM gas (Masks 1, 2, 3, and 4) and those associ-
ated with WNM gas (Mask 0). The column density of CNM gas
was corrected for opacity effects as described in Section 4.2.
The value of N(H i) at Rgal = 8.5 kpc (6.7 × 1020
cm−2
kpc−1
;
without the opacity correction) is in good agreement with the lo-
cal value of the H i surface density of 6.2 × 1020
cm−2
found by
Dickey & Lockman (1990). As we can see, the CNM dominates
the H i column density in the inner Galaxy, while WNM domi-
nates in the outer Galaxy. The column density of the WNM gas
in the inner Galaxy is similar to what we estimated for the H i
column density required to reproduce the [C ii] emission result-
ing from the azimuthal average in Mask 0. This result indicates
that even a larger fraction of the atomic gas in the inner Galaxy
12
13. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
might be in the form of CNM. CNM clouds may still exist in the
outer Galaxy, as molecular clouds and star formation are present,
and the reduction of its contribution in the outer Galaxy might
be a result of a reduced filling factor of the CNM gas.
There is a discontinuity in the total H i column density distri-
bution at around 9 kpc, which may be an artifact of the assumed
flat rotation curve with purely circular motions. An alternative
explanation is shown in Figure A.2 in Appendix A, which shows
the number of ring samples as a function of Galactocentric dis-
tance. Because a LOS samples a ring in the inner Galaxy twice
but a ring in the outer Galaxy only once, there is a discontinuity
in the number of samples between the inner and outer Galaxy.
This discontinuity will therefore affect the azimuthally averaged
emissivity distributions. The effect on the [C ii] and 12
CO emis-
sivity distributions is small because it coincides with a steep de-
crease in the value of the sum of the emissivities for each sam-
ple (see numerator in Equation A.8). In the case of H i, however,
the sum of the emissivities for each sample is smooth at around
9 kpc, and therefore dividing by the number of samples results
in a noticeable discontinuity. In Figure 12, we also show the H i
column density distribution where data points with Rgal < 9 kpc
and Rgal > 11 kpc are smoothly connected.
In Figure 13 we present the mass fraction of the CNM
gas. In the inner Galaxy, up to 90% of the atomic gas is in
the form of CNM, with even a larger percentage being pos-
sible based on the discussion above. For larger Galactocentric
distances, this fraction decreases to only 0.1–0.2, showing lit-
tle variation with Galactocentric distance. These results are in
good agreement with those found by Dickey et al. (2009) us-
ing H i emission/absorption observations in the outer Galaxy.
At Rgal = 8.5 kpc, we find that the fraction is in good agree-
ment with the local fraction of 0.4 derived by Heiles & Troland
(2003). We derive an average CNM mass fraction for the entire
Galactic disk of 0.43.
Our results suggest that the CNM is the dominant atomic gas
phase in the inner Galaxy while the WNM dominates the outer
Galaxy. The increase of the fraction of CNM gas towards the
inner Galaxy coincides with that of the 12
CO and [C ii] emissiv-
ities. This suggests that the CNM plays a important role as the
precursor of molecular clouds that will eventually form stars.
5.2. Molecular Hydrogen
5.2.1. CO–dark H2 gas
To derive the column density radial distribution of the CO–dark
H2 gas component, we first estimated the C+
column density as-
sociated with the [C ii] excess emission derived in Section 4.
The C+
column density, which can be derived by inverting
Equation (1), depends on the observed [C ii] intensity, the H2
volume density, nH2
, and the kinetic temperature of the H2 gas,
TH2
kin. Without an independent estimate of the physical conditions
in the CO–dark H2 layer, we need to make an assumption about
the value of nH2
and TH2
kin. In Section 4.2, we derived the con-
tribution from atomic gas (CNM) to the observed [C ii] inten-
sity by estimating the H i volume density, nHI, from the radial
thermal pressure distribution (Equation 3), assuming a kinetic
temperature of the H i gas, THI
kin, of 100 K. After the H/H2 tran-
sition takes place, and as the column density increases, self–
gravity starts to become important, resulting in a gradual in-
crease of the volume density of the gas. The increased shield-
ing of FUV photons results in a decreased gas heating, while
line cooling is largely unaffected due to the larger volume densi-
ties, resulting in a reduction of the kinetic temperature. Overall,
Fig. 14. Radial distribution of the azimuthally averaged excess
[C ii] emissivity as discussed in Section 4.5 (upper panel). Radial
distribution of the C+
column density derived from the excess
[C ii] emissivity (middle panel). Radial distribution of the H2
column densities derived from N(C+
) associated with the excess
[C ii] emissivity (lower pannel).
however, the thermal pressure of the gas increases with column
density: studies of local clouds, in CO absorption in the mil-
limeter (Liszt & Lucas 1998) and in the UV (Goldsmith 2013
submitted), tracing column densities up to that of the C+
/C0
/CO
transition layer, typically suggest thermal pressures in the range
between 102
to 104
K cm−3
, while for well shielded regions,
traced by 13
CO, excitation studies suggest thermal pressures in
the range between 104
to 105
K cm−3
(Sanders et al. 1993). It is
therefore likely that a thermal pressure gradient is present in the
region between the H/H2 and C+
/C0
/CO transition layers, where
the emission from CO–dark H2 gas originates. To estimate the
13
14. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 15. CO–dark H2 gas column density as a function of
Galactocentric distance for different H i and H2 temperature
pairs (THI
kin;TH2
kin). The corresponding volume densities were de-
rived from Equation (3; see Section 5.2.1).
column density of CO-dark H2 gas, we assume that the thermal
pressure of the CO–dark H2 gas is the geometric mean between
that of the H i gas (Equation 3) and the maximum observed at
the C+
/C0
/CO transition layer. At the solar neighborhood, the
minimum pressure given by Equation 3 is 3000 K cm−3
while
the maximum pressure at the C+
/C0
/CO transition layer given
by Goldsmith (2013) is 7400 K cm−3
. The resulting geometric
mean is 4700 K cm−3
, which is a factor of 1.6 larger than the
thermal pressure given by Equation (3). We therefore multiply
Equation (3) by this factor to determine the mean thermal pres-
sure of the CO–dark H2 gas as a function of Galactocentric dis-
tance. We assume a constant kinetic temperature of TH2
kin=70 K,
following the results from Rachford et al. (2002), and a corre-
sponding Rul = 4.3 × 10−10
s−1
cm−3
(Flower & Launay 1977)
for collisions with H2. Using this kinetic temperature we derive
the H2 volume density of the CO–dark H2 gas from Equation (3)
as discussed above. We will discuss below the effects of choos-
ing different values of TH2
kin and n(H2) in the derivation of the
column density of the CO–dark H2 gas. We finally converted the
radial distribution of the C+
column density to that of the H2 col-
umn density, assuming that all gas–phase carbon is in the form
of C+
, by applying a [C]/[H2] abundance gradient. The [C]/[H2]
abundance ratio is twice the [C]/[H] ratio given in Equation (2).
In Figure 14, we show the azimuthally–averaged radial dis-
tribution of the [C ii] excess emissivity (top panel), of the corre-
sponding C+
column density (middle panel), and of the CO–dark
H2 column density (lower panel). The steep distribution of the
[C ii] excess emissivity, with a peak at 4.2 kpc, becomes flatter
when converted to N(C+
) as a result of applying the n(H2) gradi-
ent derived from Equation (3) and a constant TH2
kin equal to 70 K.
When applying the [C]/[H2] abundance gradient, the radial dis-
tribution of CO–dark H2 becomes nearly constant between 4 and
11 kpc. We will discuss this flat distribution of the CO–dark H2
column density and relate it to the denser H2 gas traced by CO
and 13
CO in Section 5.3. Note that when calculating column den-
sities we are assuming that the [C ii] emission is extended with
respect to the beam of our observations. In the case that there is
substructure within the beam, our estimate of the column den-
sity will be a lower limit, as it corresponds to that averaged over
Herschel’s 12′′
beam.
In Figure 15 we show the resulting CO–dark H2 column den-
sity distribution for different combinations of the kinetic temper-
ature in the H i and H2 layers. The volume densities are obtained
from Equation (3), considering the factor 1.6 correction for H2
gas discussed above. We assume that the temperature of the H2
layer is equal to or lower than the temperature of the H i layer.
For each kinetic temperature, the corresponding value of Rul was
interpolated from data calculated by Flower & Launay (1977)
for collisions with H2 and by Launay & Roueff (1977) for col-
lisions with H. As we can see, for a wide range of temperature
combinations, the derived column density deviates by about 30%
from our adopted model with THI
kin = 100 K and TH2
kin = 70 K. We
therefore consider that our CO–dark H2 column density deter-
mination has a 30% uncertainty.
5.2.2. H2 gas traced by 12
CO and 13
CO
A commonly employed method to estimate the H2 mass of
molecular clouds is the use of the 13
CO integrated intensity,
I(13
CO), to derive the 13
CO column density, N(13
CO), assuming
that this line is optically thin and that local thermodynamic equi-
librium (LTE) applies. N(13
CO) can be then converted to N(CO),
assuming an appropriate isotopic ratio, and N(CO) to N(H2), as-
suming a CO abundance relative to H2. It has been observed in
large–scale 12
CO and 13
CO surveys, however, that the spatial ex-
tent of the 13
CO emission is often noticeably smaller than, and
is contained within, the observed extent of the 12
CO emission
(Goldsmith et al. 2008; Roman-Duval et al. 2010). This spatial
discrepancy is mostly due to the limited sensitivity of the obser-
vations that is often inadequate to detect the weak 13
CO emission
emerging from the envelopes of molecular clouds. The region
where only 12
CO is detected but 13
CO is not can account for
∼30% of the total mass of a molecular cloud (Goldsmith et al.
2008; Pineda et al. 2010a). The discrepancy between the spatial
extent of these two lines is also seen in the position velocity
maps of the observed 12
CO and 13
CO lines obtained as part of
the GOT C+ survey.
To estimate the azimuthally averaged H2 column density
traced by CO and 13
CO for each ring, we considered two cases:
spaxels where both 12
CO and 13
CO are detected (Mask CO2) and
spaxels where 12
CO is detected but 13
CO is not (Mask CO1). In
Figure 16, we show the radial distribution of the azimuthally av-
eraged 12
CO and 13
CO emissivity for spaxels in Masks CO1 and
CO2. Although by definition spaxels in Mask CO1 have 13
CO in-
tensities below the sensitivity limit, we could nevertheless detect
13
CO emission for spaxels in this mask region after averaging
them in azimuth as seen in the figure. As 13
CO can be considered
optically thin, the integrated intensity of this line is proportional
to the 13
CO column density which in turn should be proportional
to the H2 column density. Thus, spaxels in Masks CO2 and CO1
correspond to regions with larger and smaller column densities,
respectively, with the threshold between these two column den-
sity regimes given by the sensitivity of the 13
CO observations.
In the following we describe our procedure used to estimate
H2 column densities from Mask CO1 and Mask CO2. The pro-
cedure is very similar to that used in the Taurus molecular cloud
by Pineda et al. (2010a) and Goldsmith et al. (2008). We refer
to these papers for further details on the column density de-
14
15. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
termination. We derived the H2 column density using the 12
CO
and 13
CO emissivities calculated from spaxels where the 12
CO
and/or 13
CO are detected. We later expressed the derived H2 col-
umn density as an average that considers all sampled spaxels
within a given Galactocentric ring, not only where 12
CO and
13
CO emission is detected, to facilitate the comparison with the
column density of CO–dark H2 gas (Section 5.2.1).
For Mask CO2, we estimated N(13
CO) from I(13
CO) under
the assumption that this line is (almost) optically thin and that
LTE applies. Apart from the dependence on I(13
CO), N(13
CO)
depends on the excitation temperature, Tex, and opacity correc-
tions that might apply. The excitation temperature and the optical
depth can be derived from the peak line intensity of the 12
CO and
13
CO lines, respectively. To derive the line peak intensities we
assumed that the average 12
CO or 13
CO emissivities are equiv-
alent to the average of the integrated intensity of a number of
Gaussian lines with equal FWHM line width of 3 km s−1
, which
is a typical value for the observed 12
CO and 13
CO lines in our
survey (Langer et al. 2013 in preparation). Note that the calcu-
lation of Tex also assumes that the 12
CO line is optically thick
(τ >> 1). Accounting for opacity in the derivation of N(13
CO)
typically results in only a 10% correction.
We converted N(13
CO) to N(CO) using the slope of the
12
C/13
C isotope ratio gradient derived by Savage et al. (2002),
while fixing the 12
C/13
C isotope ratio to be 65 at Rgal = 8.5 kpc.
The 12
C/13
C isotope ratio as a function of Galactocentric dis-
tance is thus given by
12
C
13C
= 4.7
Rgal
kpc
+ 25.05, (4)
where Rgal is the Galactocentric distance. For this gradient, the
isotopic ratio varies from ∼43 to ∼80 for Galactocentric dis-
tance between 4 kpc and 12 kpc. We converted N(CO) to N(H2)
using a [CO]/[H2] abundance gradient constructed using the
slope of the [C]/[H] abundance gradient in Equation (2) fixing
[CO]/[H2]=1 × 10−4
at Rgal =8.5 kpc.
As noted by e.g. Tielens (2005), the [CO]/[H2] relative abun-
dance used here, and widely used in the literature, is a fac-
tor of 3 lower than the gas-phase carbon abundance observed
in the diffuse ISM, used in Section 5.2.1. This reduced CO
fractional abundance is inconsistent with chemical models that
predict that, in well shielded regions, all the gas–phase car-
bon should be in the form of CO (Solomon & Klemperer 1972;
Herbst & Klemperer 1973). This discrepancy is not a result of
CO molecules frozen onto dust grains, as it persist even af-
ter a correction to account for CO and CO2 ices is applied
(Whittet et al. 2010; Pineda et al. 2010a). The CO/H2 abundance
is often derived by comparing observations of CO and 13
CO with
visual extinction maps towards well studied nearby dark clouds
(e.g. Dickman 1978; Frerking et al. 1982; Pineda et al. 2010a).
When the contribution from H i gas is subtracted, the visual ex-
tinction traces the total column of H2 along the line of sight.
However, a certain column of H2 is required to shield the FUV
photons before CO can form. Therefore, for a given path length,
only a fraction of it, its central part, will have all gas–phase car-
bon in the form of CO, while the remainder will be what we
call the CO–dark H2 gas. Dividing the column density of CO
with that of H2 will result in a fractional abundance that is lower
than what would result if CO is the dominant form of carbon
over the entire path length. This effect is more prominent in re-
gions with moderate column densities, which represent the bulk
of the mass in giant molecular clouds, where the CO–dark H2
and CO–traced layers are comparable. Following this argument,
Fig. 16. Radial distribution of the azimuthally averaged 12
CO
and 13
CO emissivities observed in the Galactic plane for the
case where 12
CO is detected in individual spaxels but 13
CO is
not (Mask CO1; upper panel), and for the case where both 12
CO
and 13
CO are detected in individual spaxels (Mask CO2; lower
panel). Typical uncertainties of the 12
CO and 13
CO emissivities
are 0.1 and 0.02 K km s−1
kpc−1
, respectively.
the local values, [C]/[H2]=2.8 × 10−4
and [CO]/[H2]=1 × 10−4
,
would imply a CO–dark H2 gas fraction of 0.6, which is con-
sistent with what is shown in Figure 19 and that independently
found by Paradis et al. (2012) studying the CO–dark H2 fraction
in the Solar neighborhood using extinction mapping. Note that
by using [CO]/[H2]=1 × 10−4
in our calculations we are implic-
itly accounting for the contribution from CO–dark H2 gas in the
derivation of the H2 column density from CO and 13
CO. The
CO–dark H2 gas present in regions traced by CO and 13
CO will
be studied in detail by Langer et al. (2013 in preparation).
As noted above, spaxels in Mask CO1 correspond to low H2
column density gas. For molecular clouds it is likely that this
gas is also characterized by low H2 volume densities. Assuming
that the detected 12
CO emission in Mask CO1 is nonetheless op-
tically thick we estimated the excitation temperature as we did
for Mask CO2. Typical values were found to be in the 4 K to
15
16. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
6 K range for 4 kpc ≤ Rgal ≤ 12 kpc. As seen in Taurus, pixels
in Mask CO1 are located in the periphery of the large column
density molecular cloud traced by 12
CO and 13
CO (Mask CO2).
However, the excitation temperatures estimated for Mask CO1
are lower than those derived for Mask CO2 (∼10–20K), and
therefore they are inconsistent with what we would expect for
this gas being in LTE, because the kinetic temperature is likely
to be higher in the outer regions of the cloud which are subject
to increased heating. It is therefore reasonable to assume that the
gas in Mask CO1 is subthermally excited. Pineda et al. (2010a)
used the RADEX (van der Tak et al. 2007) excitation/radiative
transfer code to predict line intensities from a gas with condi-
tions similar to those of Mask CO1 in the envelope of the Taurus
molecular cloud. RADEX accounts for effects of trapping, which
are important for the excitation of CO at low densities. The
model parameters are the kinetic temperature, Tkin, the H2 vol-
ume density, n(H2), the CO column density per unit line width,
N(CO)/δv, and the 12
CO/13
CO abundance ratio, R. The observed
parameters are the excitation temperature and the 12
CO/13
CO in-
tegrated intensity ratio. As mentioned above, the excitation tem-
perature varies from 6 K to 4 K for 4 kpc ≤ Rgal ≤ 12 kpc. The
12
CO/13
CO integrated intensity ratio shows little variation from
its average value of ∼24 for the same range in Galactocentric
distance. We assume that the kinetic temperature is 15 K. If the
value of R were known, one could find a unique solution for
n(H2) and N(CO). However, the isotopic ratio is expected to
vary from that expected for well–shielded regions due to iso-
topic enhancements produced by chemical and/or photo effects.
Thus, there is a family of solutions that can reproduce the ob-
served quantities. Pineda et al. (2010a) used nearly 106
individ-
ual spectra in the Taurus molecular cloud to find a set of solu-
tions that produced a monotonically decreasing R with decreas-
ing excitation temperature and a smoothly decreasing column
density with decreasing excitation temperature. The observed
12
CO/13
CO integrated intensity ratio for a given value of Tex
for all Galactocentric rings is in excellent agreement with the
same quantities observed in the envelope of the Taurus molecular
cloud. We therefore used the solution presented in Pineda et al.
(2010a) to derive the N(CO) column density in Mask CO1 for
each Galactocentric ring. For our observed values of Tex and the
12
CO/13
CO integrated intensity ratio, their solution suggests a
gas with n(H2) ≃ 250 cm−3
and R ≃ 30. We use their fit to the
relationship between CO column density and the observed exci-
tation temperature given by
N(CO)
cm−2
δv
km s−1
−1
= 6.5 × 1013 Tex
K
2.7
(5)
to derive the average N(CO) column density in Mask CO1.
The [CO]/[H2] abundance ratio is expected to show strong
differences between UV–exposed and shielded regions as a re-
sult of the competition between the formation and destruction
of CO (e.g. van Dishoeck & Black 1988; Visser et al. 2009).
Pineda et al. (2010a) compared CO column densities derived at
the envelope of the Taurus molecular cloud with a visual extinc-
tion, AV, map of the same region (with the contribution from
dust associated with atomic gas to the visual extinction sub-
tracted). They provided a polynomial fit giving AV at any given
value of N(CO) (see their Figures 13 and 14). We use this fit to
derive visual extinctions from N(CO) in Mask CO1. Since AV
traces the total column density of H2, not only that traced by
CO, the relationship between N(CO) and AV should already ac-
count for the CO–dark H2 gas present in the envelope of the
Taurus molecular cloud. The visual extinction outside the CO
Fig. 17. Radial distribution of the azimuthally averaged H2 col-
umn density as traced by 12
CO and 13
CO. We include the radial
distribution of N(H2) from gas associated with spaxels where
both 12
CO and 13
CO are detected (Mask CO2) and where 12
CO
is detected but 13
CO is not (Mask CO1). The total distribution
(Mask CO1+ Mask CO2) has been increased by 20% to account
for 12
CO emission that is not detected in individual spaxels but
was detected after averaging them in azimuth (see Section 5.2.2).
boundary in Taurus can be estimated by searching for the value
of AV at which N(CO) = 0 cm−2
. A polynomial fit to the lower
part of the N(CO)–AV relationship gives N(CO) = 0 cm−2
for
AV=0.37 mag. Note that this correction only applies if the col-
umn density in Mask CO1 is derived using spaxels that have
both [C ii] and 12
CO emission. There are, however, spaxels in
Mask CO1 where 12
CO emission is detected but [C ii] is not, and
the correction in the conversion from N(CO) to AV does not ap-
ply to them, because their CO–dark H2 layer is not already traced
by [C ii]. We repeated the column density estimation described
above but for only spaxels in Mask CO1 that have both [C ii] and
12
CO emission as well as for those that have 12
CO emission but
no [C ii]. After applying the 0.37 mag correction to the column
density distribution derived from spaxels detected in [C ii] and
12
CO and adding it to that derived from spaxels with 12
CO emis-
sion only, we find that the total column density distribution is
about 15% lower than that without applying the correction. We
therefore reduce the derived values of AV by 15% to account for
the CO–dark H2 gas already traced by [C ii] in Mask CO1.
The formation of CO in cloud envelopes is mostly influ-
enced by dust grains shielding the FUV radiation field, with
smaller contributions from H2 shielding and CO self–shielding.
Thus, changes in metallicity will not significantly influence
the dust column density, but will modify the H2 column den-
sity, at which the C+
/C0
/CO transition takes place, because
a reduction/increase on metallicity is associated with a in-
crease/reduction of the gas–to–dust ratio, Rgd = N(H2)/AV. To
convert the derived visual extinctions to H2 column densities, we
assumed that Rgd has the same slope, but with the opposite sign,
of the galactic metallicity gradient (Equation 2), and we fixed its
value at Rgal = 8.5 kpc to be 9.4 × 1020
cm−2
mag−1
(Bohlin et al.
16
17. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
1978). The resulting gas to dust ratio as a function of galacto-
centric distance is therefore given by,
Rgd = 2.38 × 1020
100.07Rgal
cm−2
/mag, (6)
with the galactocentric distance, Rgal, in units of kpc. We applied
this relationship to convert from AV to N(H2) in Mask CO1.
Pineda et al. (2010a) and Goldsmith et al. (2008) detected
12
CO and 13
CO emission in the periphery of Taurus where these
lines were not detected in individual pixels. Pineda et al. (2010a)
estimated that this gas accounts for about 20% of the total mass
of Taurus. Although we can still detect weak 12
CO emission af-
ter averaging in azimuth regions where 12
CO is not detected in
individual spaxels, we could not detect 13
CO, and therefore can-
not repeat the analysis done in Taurus. We corrected the total
column density traced by 12
CO and 13
CO by 20% to account for
this missing CO gas component.
Figure 17 shows the total azimuthally averaged H2 column
density as traced by 12
CO and 13
CO. For the range between 4 kpc
and 7 kpc, gas associated with Mask CO2 contributes about 70%
of the total H2 traced by CO and 13
CO. For 7 kpc< Rgal <10 kpc,
the gas associated with Mask CO2 contributes about 25% of the
total CO–traced H2 gas. This contribution is consistent with the
relative contribution from Mask CO1 and Mask CO2 to the mass
of the nearby Taurus molecular cloud derived by Pineda et al.
(2010a).
5.3. The complete distribution of H2 in the plane of the Milky
Way
In Figure 18, we show the radial distribution of the total az-
imuthally averaged H2 column density. The total N(H2) is the
combination of the contribution from H2 gas traced by CO and
that traced by [C ii] (CO–dark H2 gas). Both contributions are
also included in the figure. Close to the Galactic center, most
of the H2 is traced by CO with the CO–dark H2 gas making a
negligible contribution. The CO–traced H2 gas is mostly con-
centrated in the 4 kpc to 7 kpc range, while the CO–dark H2 gas
is extended over a wider range of Galactocentric distances, be-
tween 4 and 11 kpc. As mentioned in Section 5.2.1, the distri-
bution of the CO–dark H2 column density is nearly constant be-
tween 4 and 11 kpc. However, the fraction of the total molecular
gas in this component increases with Galactocentric distance.
This increase is shown in Figure 19 where we show the CO–
dark H2 gas fraction as a function of Galactocentric distance.
The fraction of CO–dark H2 gas increases monotonically with
Galactocentric distance, rising from 0.2 of the total H2 gas at
4 kpc to be about 0.8 at 10 kpc. The Galactic metallicity gradi-
ent is likely accompanied by a decrease of the dust–to–gas ratio
with Galactocentric distance. The reduced dust extinction results
in an increased FUV penetration, which in turn results in the
C+
/C0
/CO transition layer taking place at larger H2 column den-
sities. Thus, as suggested by our results, the low–column density
H2 gas at large Galactocentric distances, with low–metallicities,
is better traced by [C ii] (and perhaps [C i]) than by CO.
For Rgal > 11 kpc, we see a reduction of the column density
of CO–dark H2 gas. In the outer Galaxy we detect fewer [C ii]
clouds per unit area and, as we can see in Figure 11, most of
the detected emission is associated with dense PDRs. Because
of the reduced carbon abundance in the outer Galaxy, and per-
haps reduced thermal pressures, the [C ii] intensity associated
with CO–dark H2, as well as that associated with H i and electron
gas, might be reduced to be below our detection threshold, while
only regions associated with star–formation, dense PDRs, can
Fig. 18. Radial distribution of the H2 column density in the plane
of the Milky Way. We also show the relative contributions to the
total H2 column density from gas traced by 12
CO and 13
CO and
from CO–dark H2 gas.
Fig. 19. Radial distribution of the fraction of the total H2 column
density comprised by the CO–dark H2 gas.
produce detectable emission. Due to the reduced star formation
activity per unit area in the outer Galaxy, the average strength of
the FUV field is likely also reduced. This reduction of the FUV
field results in a lower kinetic temperature that reduce the exci-
tation of [C ii] line. Additionally, the plane of the Milky Way is
known to warp towards the outer Galaxy, while the CO–dark H2
distribution is based on [C ii] data at b=0◦
. Thus, our sampling of
the outer Galactic plane might not be as good as it is for the inner
Galaxy. Therefore we cannot rule out that the distribution of H2
extends even further in the outer Galaxy than indicated here.
17
18. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 20. Radial distribution of the CO–to–H2 conversion factor.
We show the distribution for values estimated considering the
CO–traced H2 gas as well as that including the CO–dark H2 gas
component.
5.4. The CO–to–H2 conversion factor in the Milky Way
When 13
CO observations are not available, the mass of molec-
ular clouds or the molecular content of entire galaxies is of-
ten estimated from observations of the 12
CO J = 1 → 0 line
applying an empirically–derived CO–to–H2 conversion factor
(XCO ≡ N(H2)/ICO ∝ MH2
/LCO). Modelling applied to γ–ray
observations, which trace the total molecular content along the
line–of–sight, results in a local value of 1.74 × 1020
cm−2
(K km
s−1
)−1
or MH2
/LCO = 3.7 M⊙(K Km s−1
pc2
)−1
(Grenier et al.
2005). Several theoretical studies have focused on the depen-
dence of XCO on environmental conditions, showing that XCO
is particularly sensitive to metallicity and the strength of the
FUV radiation field (e.g. Maloney & Black 1988; Sakamoto
1996). Observationally, however, it has been found that XCO is
mostly sensitive to metallicity (e.g. Rubio et al. 1991; Wilson
1995; Israel 1997, 2000) while not showing a significant de-
pendence on the strength of the FUV field (Pineda et al. 2009;
Hughes et al. 2010).
We estimated the radial distribution of XCO in the
Galactic plane by dividing the H2 column density in a given
Galactocentric ring by its corresponding 12
CO emissivity. In
Figure 20 we show the radial distribution of XCO derived from
the H2 column density traced by CO and 13
CO only, as well
as that including the CO–dark H2 component. We also show
the radial distribution of XCO derived from the relationship be-
tween XCO and metallicity observed by Wilson (1995) and Israel
(2000) in nearby galaxies. We converted the dependence of XCO
on metallicity presented by these authors to a radial dependence
using the slope of the metallicity gradient in Equation (2), fixing
XCO to be 1.74 × 1020
cm−2
(K km s−1
)−1
at Rgal = 8.5 kpc.
Both XCO distributions increase with the Galactocentric dis-
tance. But when the contribution from CO–dark H2 is included,
the slope is steeper. This steeper slope is a result of the mono-
tonic increase of the CO–dark H2 contribution to the total H2
column density with Galactocentric distance (Figure 19). The ra-
dial distribution of XCO considering N(H2) from 12
CO and 13
CO
only is consistent with that fitted by Wilson (1995). When CO–
dark H2 is included in the calculation of XCO the radial distri-
bution starts to resemble that fitted by Israel (2000). The off-
sets of course will change if the normalization at Rgal=8.5 kpc is
adjusted. Note that there is a difference in the method used by
Wilson (1995) and Israel (2000) to derive XCO. Wilson (1995)
observed 12
CO in several giant molecular clouds within several
nearby galaxies and compared their virial masses to the mass
derived from their 12
CO luminosities using a Galactic conver-
sion factor. Israel (2000) estimated the H2 mass of a sample of
nearby galaxies by modelling their FIR continuum emission to
derive their masses and related them to their 12
CO luminosities
to derive XCO. The FIR continuum emission should trace the to-
tal H2 content (including the CO–dark H2 component) while the
method based on the virial mass derived from 12
CO mapping
accounts for only the H2 mass traced by 12
CO.
The increase of XCO with Galactocentric distance for the case
when only CO and 13
CO are used to derive N(H2) is a result of
the abundance gradient we applied in the calculation of N(H2).
If we set the [CO]/[H2] abundance to be constant when con-
verting N(CO) to N(H2) for Mask CO2, and from AV to N(H2)
for Mask CO1, we obtain a nearly constant radial distribution
of XCO. When the CO–dark H2 is included, however, the slope
(seen in Figure 20) results from both the abundance and the ther-
mal pressure gradients. If we also set the [C+
]/[H2] abundance to
be constant we still obtain a distribution that increases with Rgal.
Thus, the difference in the slopes in the distribution of XCO is a
result of the use of the thermal pressure gradient in the calcula-
tion of the CO–dark H2 column density distribution.
5.5. The surface density distribution and mass of the atomic
and molecular gas in the Galactic plane
In the top panel of Figure 21, we show the vertical surface
density distribution of the total hydrogen gas in the Galactic
plane. We also show the relative contributions from atomic
and molecular gas. We calculated the surface densities assum-
ing a Gaussian vertical distribution of the gas. For the molecu-
lar gas we assume a constant FWHM disk thickness of 130 pc
(Section 3.2). In the case of the atomic gas, the disk thickness is
observed to increase with Galactocentric distance, and we used
the exponential relation presented by Kalberla & Kerp (2009),
zFWHM = 0.3e(Rgal−8.5)/9.8
kpc. In all cases, the surface density
includes a correction to account for the contribution from He.
In the lower panel of Figure 21, we show the surface density
distribution of the different contributing ISM components of the
atomic and molecular gas studied here, the cold and warm neu-
tral medium, the CO–dark H2 gas, and the H2 gas traced by
12
CO and 13
CO. The surface density distribution of atomic and
molecular gas derived in our analysis is similar to that derived
by Scoville & Sanders (1987), but with the addition of the CO–
dark H2 component, the distribution of molecular gas extends
over a larger range of Galactocentric distances compared with
that traced by 12
CO and 13
CO only. In Table 2, we list the mass
of each ISM component studied here. The CO–dark H2 gas ac-
counts for about 30% of the total molecular gas mass. The WNM
dominates the mass of atomic gas in the Galactic plane, account-
ing for 70% of the total atomic mass.
6. The FUV radiation field distribution in the Milky
Way
An important parameter governing the thermal balance and
chemistry in interstellar clouds is the strength of the FUV field,
18
19. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 21. (top panel) Radial distribution of the surface density of
hydrogen in the Galactic plane. We also show the contribution
of the atomic and molecular hydrogen gas. (lower panel) Radial
distribution of the different ISM components, including the cold
and warm neutral medium (atomic gas), the CO–dark H2 compo-
nent, and the H2 gas that is traced by 12
CO and 13
CO. All surface
densities have been corrected to account for the contribution of
He.
χ0 (in units of the Draine 1978 field). The gas heating in cold,
diffuse regions is dominated by the photoelectric effect resulting
from the absorption of FUV photons by dust grains and PAHs.
The FUV field also plays a critical role in the formation and de-
struction of CO, determining the column density at which the
C+
/C0
/CO transition takes place. It is therefore of interest to de-
termine the typical strength of the FUV field to which the inter-
stellar gas is exposed and how this FUV field varies from place
to place in the plane of the Milky Way.
PDR model calculations suggest that the [C ii]/12
CO inte-
grated intensity ratio is primarily a function of χ0 and the total H
(nHI + 2nH2
) volume density (Wolfire et al. 1989; Kaufman et al.
1999). The reason for this dependence is that the 12
CO emission
becomes optically thick quickly after a modest fraction of the
gas–phase carbon is converted to CO. The [C ii]/12
CO ratio is
Table 2. Mass of Milky Way ISM components
Component Mass
109
M⊙
H2 from CO 1.9
H2 CO–dark 0.7
H2 Total 2.6
H i CNM 0.9
H i WNM 1.6
H i Total 2.5
Total H i+H2 5.1
Fig. 22. Comparison between the [C ii] and 12
CO emissivities
corresponding to different Galactocentric rings, for gas associ-
ated with Mask 3 (red circles) and Mask 4 (black boxes). The
straight lines represent fits to the data. Typical uncertainties are
0.02 and 0.1 K km s−1
kpc−1
, for [C ii] and 12
CO, respectively.
thus determined by the column density of C+
and the tempera-
ture of the line–emitting region. Both quantities depend, in turn,
on the strength of FUV field and H volume density. The solution
for a given value of the [C ii]/12
CO ratio is not unique, however,
and several pairs of χ0 and nH can reproduce the observations.
Therefore, we can only use the [C ii]/12
CO ratio to determine a
range of plausible values of the FUV radiation field and H vol-
ume density that characterize the line–emitting region.
In a preliminary study of [C ii], 12
CO, and 13
CO velocity
components on 16 GOT C+ LOSs, Pineda et al. (2010b) used
PDR model calculations to constrain the strength of the FUV
field to be mostly χ0 =1–10, over a wide range of H2 volume
densities, thus suggesting that most of the observed [C ii] emis-
sion associated with 12
CO and 13
CO is exposed to weak FUV
radiation fields. A similar result, was obtained from PDR mod-
eling of the [C ii] emission observed by COBE by Cubick et al.
(2008), suggesting that most of the [C ii] in our Galaxy originates
in a clumpy medium exposed to an FUV field of χ0 ≃ 60.
With the complete GOT C+ survey, we can study the
[C ii]/12
CO ratio over the entire Galactic plane and determine
how the strength of the FUV field is distributed in the Galaxy.
We consider the azimuthally averaged emissivity of [C ii] cal-
culated from spaxels where both 12
CO and 13
CO emission is
detected (Mask 4), and where 12
CO is detected but 13
CO is not
19
20. Pineda, Langer, Velusamy, and Goldsmith: A Herschel [C ii] Galactic Plane Survey
Fig. 23. Radial distribution of the [C ii] to 12
CO emissivity ra-
tio for Mask 3 (red circles) and Mask 4 (black boxes). We also
show the radial distribution of the [C ii]/12
CO ratio resulting
from the combined emission from Mask 3 and 4 (blue triangles).
The horizontal lines correspond to the average value for each
Mask region between 3–10kpc. The horizontal lines are labeled
with a range of pairs of the FUV field and H2 volume densities
(χ0, nH2
), that reproduce their corresponding [C ii]/12
CO ratio,
as predicted by the Kaufman et al. (1999) PDR model. To facil-
itate the comparison with the PDR model, the ratios were calcu-
lated using [C ii] and 12
CO emissivities expressed in units of erg
s−1
cm−2
sr−1
kpc−1
. In these units, typical uncertainties in the ra-
tios are 180, 33, and 35 for Mask 3, Mask 4, and the combined
emission from both Mask regions, respectively.
(Mask 3; See Figure 9). As discussed in Section 4, gas associated
with Mask 3 might represent low–column density gas surround-
ing the high–column density regions associated with Mask 4. In
Figure 22, we show a comparison between the [C ii] and 12
CO
intensities for different Galactocentric rings, for gas associated
with Mask 3 and 4. In both mask regions we see a good corre-
lation between these two emissivities. A straight line fit results
in I(12
CO) = 7.8I([Cii]), for Mask 3, and I(12
CO) = 3.3I([Cii])
for Mask 4.
In Figure 23, we show the radial distribution of the [C ii]
to 12
CO emissivity ratio for Masks 3 and 4. We also include
the radial distribution of the [C ii]/12
CO ratio resulting from the
combined emission from Masks 3 and 4. The ratio is computed
considering emissivities in units of erg s−1
cm−2
sr−1
kpc−1
.
We restrict the range in Galactocentric distance to be between
3 and 10 kpc because, for these regions, both [C ii] and 12
CO
have significant emission in this range. As expected, given the
linear correlation between [C ii] and 12
CO, the ratio shows lit-
tle variation between 3 and 10 kpc. We also include horizontal
lines representing the average [C ii]/12
CO ratio for each mask
region. These horizontal lines are labeled with a range of pairs
of the FUV field and H2 volume densities (χ0, nH2
), that can
reproduce the corresponding values of the [C ii]/12
CO ratio, as
predicted by the PDR model calculations from Kaufman et al.
(1999). As mentioned before, Mask 3 might represent regions
with lower column densities compared to those in Mask 4. This
column density difference might also translate into a difference
in volume densities because we do not expect a large difference
in the spatial extent of such regions. We thus show the results of
the PDR model for ranges in nH2
that, based on the analysis in
Section 5.2.2, might be appropriate. We considered the range of
H2 volume density 102
−103
cm−3
for Mask 3, and 103
−104
cm−3
for Mask 4. For the combined emission from Mask 3 and Mask 4,
we considered a wider range of possible H2 volume densities
102
− 104
cm−3
. Note that the PDR model calculations presented
by Kaufman et al. (1999) are in terms of the total H volume den-
sity, including atomic and molecular hydrogen. For the compari-
son between the observations and model predictions we assumed
that the contribution of atomic hydrogen to the total H volume
density is negligible and show the results of the PDR model in
terms of the H2 volume density.
We find that over the selected range of H2 volume densities,
the [C ii]/12
CO ratio in both Mask 3 and Mask 4 suggest values
of χ0 that are in the range 1–30, while we do not find any system-
atic variation in χ0 with Galactocentric distance between 3 kpc
and 10 kpc. The same range of χ0 is suggested by the [C ii]/12
CO
ratio resulting from the combined emission from Mask 3 and 4,
over a wider range of H2 volume densities. Our results therefore
suggest that on average the [C ii] emission associated with 12
CO
and/or 13
CO observed in the Galactic plane by the GOT C+ sur-
vey emerges from gas exposed to modest FUV radiation fields,
away from massive star–forming regions.
7. Summary
In this paper we have presented results of our study of the dis-
tribution and properties of the different ISM components in the
plane of the Milky Way using spatially and velocity resolved
observations of the [C ii] 158µm line. Our results can be summa-
rized as follows:
1. We presented the first longitude–velocity maps of the [C ii]
158µm line in the plane of the Milky Way. We found that
the [C ii] emission is mostly associated with the spiral arms,
tracing the envelopes of evolved clouds as well as clouds
that are in the transition between the atomic and molecular
phases.
2. We found that most of the [C ii] emission in the Galactic
plane emerges from Galactocentric distances between 4 kpc
and 11 kpc.
3. We estimated that most of the observed [C ii] emission
emerges from dense photon dominated regions (∼47%), with
smaller contributions from CO–dark H2 gas (∼28%), cold
atomic gas (∼21%), and ionized gas (∼4%).
4. We used the [C ii] emission to separate the WNM and CNM
contributions in the Galactic plane. We find that most of the
atomic gas inside the Solar radius is in the form of cold neu-
tral medium, while the warm neutral medium gas dominates
the outer Galaxy. The average fraction of the total atomic gas
that is CNM is ∼43%.
5. We found that the warm and diffuse CO–dark H2 is dis-
tributed over a larger range of Galactocentric distances (4–
11 kpc) than the cold and dense H2 gas traced by 12
CO and
13
CO (4–8 kpc). The fraction of the total H2 gas that is CO-
dark H2 increases with Galactocentric distance, ranging from
∼20% at 4 kpc up to ∼80% at 10 kpc. We estimate that the
CO–dark H2 gas component accounts for ∼30% of the total
molecular gas mass in the Milky Way.
6. We estimated the radial distribution of the CO–to–H2 con-
version factor. When N(H2) is derived from 12
CO and
13
CO only, the CO–to–H2 conversion factor increases with
20