1. Thomas Madigan, M.Sc
In collaboration with colleagues in the
Physical Sciences Department
Suffolk County Community College
Selden, NY 11784
madigat@sunysuffolk.edu
The Sun and all stars are dynamic, self-regulating systems, each powered by a
huge nuclear fusion reactor in their core. These cores of the sun and other stars
in a similar evolutionary state currently produce helium and a tremendous
amount of energy. From the 15 million-degree core plasma produced by these
nuclear fusion reactors flows a stream of protons, electrons and helium nuclei,
collectively referred to as the solar wind.
Sunspot numbers are an indicator of internal solar activity; increased sunspot
numbers is an indicator of increased solar output and activity. Our sun has an 11-
year activity cycle. Currently, solar activity is waning. Considering the sun’s
nature as a giant, roiling, super-heated, self-regulating ball of plasma that is
modeled as a fluid we expect certain irregularities in the sun’s behavior and
activity, aspects of solar dynamics that give rise to solar storms and outbursts,
phenomenae whose frequency of occurrence are directly linked to the solar
cycle.
is captured at SCCC and recorded as a SID event. Beginning with the first spike, it is immediately observed at 16:10 UT with
almost complete signal attenuation at 17:00 UT. This is followed by an M-class event at 18:40 UT. The difference in magnitude of both events is clearly evident: the X class
event almost completely suppresses the signal with the ionosphere D-level recovery presenting as a characteristic tail which then flows into the M class event that presents
in a similar manner but smaller in magnitude. Local sunrise and sunset are indicated by the light blue arrows at 11:00 UT and 23:00 UT respectively. The X-class event and
the M-class event had a measured X-ray flux of 2.1x10-4 Watts/m2 and 1.0x10-5 Watts/m2 respectively. Received signal strength is measured as a function of time.
http://sdoisgo.blogspot.com/2015/03/the-first-x-class-flare-of-2015.html
While they are both indicative of a dynamic and changing environment, they are,
at the same time, quite different in nature, yet have certain commonalities. A
CME is a huge bubble of magnetized gas that is ejected into space, an event that
may take several hours to complete. A solar flare is far more temporal and short-
lived and much smaller in scale. They both have associated with them streams of
high-energy protons, electrons and alpha particles (helium nuclei). Hence, the
large difference between solar flares and CMEs is mostly one of size. Both can
occur together but can also occur in the absence of the other.
Million-degree gas produces X-rays; solar flares, short-lived and temporal, are
often associated with sunspots, cooler regions of the sun’s photosphere resulting
from magnetic anomalies that cause a breach in energy transmission from the
solar interior. Solar flares emit radiation in the visible, the ultraviolet, X-ray and
gamma ray regimes of the electromagnetic spectrum. The X-rays and gamma
rays, being of the highest energy, are associated with localized, super-heated gas.
Solar flares are thus categorized according to a logarithmic X-ray intensity scale
from A being the weakest to X being the strongest. The measured flux at the
Earth/Sun distance is
A = 1.0x10-8 (Watts m-2)
B = 1.0x10-7 (Watts m-2)
C = 1.0x10-6 (Watts m-2)
M = 1.0x10-5 (Watts m-2)
X = 1.0x10-4 (Watts m-2)
Some conditions in space have the potential to seriously affect life on Earth. We call these conditions “Space Weather”. The effects of the solar wind can be measured, either as the continuous, daily stream of charged particles bombarding the
Ionosphere, the upper, tenuous region of the Earth’s atmosphere or as the result of a solar flare. An aspect of Space Weather, this interaction with the Ionosphere above 85 kilometers in altitude, produces the beautiful auroral displays we observe as
the Northern and Southern Lights. Another aspect of Space Weather, and one that is central to this research, is the response of the E and F layers of the Ionosphere to the daily irradiance of high-energy solar radiation, predominantly solar ultraviolet
and soft X-rays. In short, the lower D layer of the Ionosphere is produced by the ionization of the E and F layers during the day; at night, the electrons and ions quickly recombine in the absence of solar irradiance and the D layer disappears. This
ionization and its effects can be measured and quantified by the interaction of VLF (very low frequency) radio waves with these layers and is at the heart of this research. Compared to the charged particles of the solar wind which take 2 or 3 days to
reach the Earth, X-rays and ultraviolet radiation travel at the speed of light and take a little over 8 minutes to reach the Earth, allowing their effects on the Ionosphere to be measured and observed within minutes of occurring on the sun.
Composite image from
the orbiting Solar
Dynamics Observatory
recording an M-class solar
flare at 03:08 UT, 15th
March, 2015 at the
Extreme Ultraviolet (EUV)
wavelengths of 94, 193
and 335 Angstroms
A Sudden Ionospheric Disturbance or SID is the response of the Ionosphere to a rapid influx of high-energy ultraviolet or X-ray radiation. Although this radiation is most
often attributed to the sun, the source could theoretically originate in deep space from supernovae or a Gamma Ray Burst. One method of detecting SIDs involves
measuring the effect Ionospheric changes have on reflected VLF (very low frequency, 3 – 30 Khz) radio signals. When a solar flare occurs, high-energy X-rays irradiate the
sunlit side of the Earth, striking the E and F layers of the Ionosphere. These X-rays will penetrate to the D-layer, releasing electrons that will rapidly increase absorption,
causing VLF (3 – 30 kHz) signals to be reflected by the D layer where the increased atmospheric density will usually increase the absorption of the signal and thus
dampen it. This effect is clearly observed in our data. As soon as the flare ends, the X-rays abate and the SID ends as the electrons and ions in the D-region recombine
rapidly and the signal strengths return to normal.
The flare that produced the SID illustrated.
Images obtained from the orbiting Solar
Dynamics Observatory at 16:56 UT at the
Extreme Ultraviolet (EUV) wavelengths of 94,
193 and 335 Angstroms
The Sun and Other Stars
Solar Activity
Solar Flares vs Coronal Mass Ejections
Solar Flares
The SID (Sudden lonospheric Disturbance) Effect
Space Weather
Hi resolution solar images obtained through public license from the orbiting Solar Dynamics Observatory: sdo.gsfc.nasa.gov
In 2007, through a grant obtained by the SCCC Physical
Sciences Department, Professor Thomas Madigan built
the 2 meter “loop wire” antenna mounted atop the
Smithtown Science Building. The antenna is connected
to a VLF (3 – 30 Khz) receiver, which, in turn, is
connected to a dedicated computer. At 00:00 UT (8:00
PM) every day, the data is uploaded to Stanford
University’s Solar Center for inclusion in their
worldwide database. Visit sid.stanford.edu and select
“SFCC” as the site ID to view the college’s daily results,
for more information or to get involved. For the
Stanford Solar Center’s home page, visit: solar-
center.stanford.edu .
11 March 2015 Solar Flare
SCCC Loop Antenna