Interparticle Interactions and Dynamics in Solutions of Copper (II), Cobalt (...Dmitry Novikov
This presentation is a report from the PLMMP-2018 conference. For any information contact me here: dmitrynovikovs@gmail.com
Abstract
This work is a continuation of the systematic study of unsymmetrical electrolytes in non-aqueous media, carried out at the Department of Inorganic Chemistry of V.N. Karazin Kharkiv National University [1].
Here we report the results of the conductometric study of diluted solutions of Cu(BF4)2, Zn(BF4)2 and Co(BF4)2 in acetonitrile (AN) at 5-55 oC. The extended Lee-Wheaton equation was used to procced conductometric data and obtain primary association constants, limiting equivalent conductance of electrolytes and limiting ionic conductivities. The primary association constants were then used to interpret the contribution of the ionic solvation and association in terms of contact ionic pairs, solvent-separated ionic pairs and short-range non-Coulomb interionic potential.
Obtained values of total limiting equivalent conductivity of electrolyte and the limiting conventional transference numbers allowed us to divide the equivalent conductivity on ionic constituents. These data were later proceeded to evaluate the parameter of dynamics of ionic solvation, within the modified theory of the dielectric friction.
Additionally, densimetric study was carried out to derive structural parameters of ion solvation of Cu(BF4)2, Zn(BF4)2 and Co(BF4)2 in AN at 5-55 oC.
Finally, molecular dynamics simulations were performed on the same electrolyte/AN systems by means of MDNAES package [2] to elucidate particle dynamics and microscopic structure within the first and second co-ordination shells of copper (II), cobalt (II) and zinc (II) cations in AN at 25 °C.
References
[1] O.N. Kalugin, V.N. Agieienko and N.A. Otroshko, J. Molec. Liquids, 165, 78-86 (2012).
[2] O. N. Kalugin, M. N. Volobuev, and Y. V. Kolesnik, Khar. Univ. Bull., Chem. Ser. 454, 58-80 (1999).
Interparticle Interactions and Dynamics in Solutions of Copper (II), Cobalt (...Dmitry Novikov
This presentation is a report from the PLMMP-2018 conference. For any information contact me here: dmitrynovikovs@gmail.com
Abstract
This work is a continuation of the systematic study of unsymmetrical electrolytes in non-aqueous media, carried out at the Department of Inorganic Chemistry of V.N. Karazin Kharkiv National University [1].
Here we report the results of the conductometric study of diluted solutions of Cu(BF4)2, Zn(BF4)2 and Co(BF4)2 in acetonitrile (AN) at 5-55 oC. The extended Lee-Wheaton equation was used to procced conductometric data and obtain primary association constants, limiting equivalent conductance of electrolytes and limiting ionic conductivities. The primary association constants were then used to interpret the contribution of the ionic solvation and association in terms of contact ionic pairs, solvent-separated ionic pairs and short-range non-Coulomb interionic potential.
Obtained values of total limiting equivalent conductivity of electrolyte and the limiting conventional transference numbers allowed us to divide the equivalent conductivity on ionic constituents. These data were later proceeded to evaluate the parameter of dynamics of ionic solvation, within the modified theory of the dielectric friction.
Additionally, densimetric study was carried out to derive structural parameters of ion solvation of Cu(BF4)2, Zn(BF4)2 and Co(BF4)2 in AN at 5-55 oC.
Finally, molecular dynamics simulations were performed on the same electrolyte/AN systems by means of MDNAES package [2] to elucidate particle dynamics and microscopic structure within the first and second co-ordination shells of copper (II), cobalt (II) and zinc (II) cations in AN at 25 °C.
References
[1] O.N. Kalugin, V.N. Agieienko and N.A. Otroshko, J. Molec. Liquids, 165, 78-86 (2012).
[2] O. N. Kalugin, M. N. Volobuev, and Y. V. Kolesnik, Khar. Univ. Bull., Chem. Ser. 454, 58-80 (1999).
Vyom Shah recently spoke on Crowdfunding & Crowdsourcing at Vidarbha Management Association (VMA)
Businesses often rely on Debts (Bank Loans, Bonds etc.) or Equity (Share divestment, IPO etc.) for financing. However, a new alternative means of financing has emerged - Crowdfunding that does away with all the challenges and negativities of Debts and Equity. Crowdfunding has gained traction globally and in India too, and is increasingly been used by many orgnaizations. Several platforms have emerged to support this medium. Besides, similar to crowdfunding, companies have even started to get ideas and work delivered from public, through Crowdsourcing.
CONVERSIONS TO USE
METRIC PREFIXES
This table uses liters (L) as the base unit, but you can use this table for ANY base unit. For example, 1 s = 1×106 µs.
OR Base Unit Prefix
OR
OR
OR
OR
OR
OR
OR
OR
OR
NOTE: Two equivalence statements are written for each prefix. Either is equally correct (they are exactly the
same). Use whichever makes more sense to you.
OTHER CONVERSIONS
All of these are exact numbers except those marked with *
METRIC tt METRIC ENGLISH tt
ENGLISH
ENGLISH tt
METRIC
LENGTH 1 cm = 1×108 Å
(Å is the symbol for
angstroms)
12 in. = 1 ft.
3 ft. = 1 yd.
5280 ft. = 1 mi.
1 in. = 2.54 cm
1 mile = 1.609 km*
MASS / WEIGHT 1000 kg = 1 metric ton 2000 lb. = 1 ton
16 oz. = 1 lb.
1 lb. = 453.6 g*
VOLUME 1 L = 1 dm3
1 mL = 1 cm3
1000 L = 1 m3
3 tsp. = 1 Tbsp.
16 Tbsp. = 1 cup
2 cups = 1 pint
2 pints = 1 quart
4 quarts = 1 gal.
8 fluid oz. = 1 cup
1 qt. = 0.9464 L*
1 fluid oz. = 29.57 mL*
1 ft3 = 28.32 L*
TEMPERATURE TK = TC + 273.15 TF = 1.8(TC) + 32
TC = (TF - 32) / 1.8
ENERGY 1 cal = 4.184 J
NOTE: The ounces that measure mass are completely different from and unrelated to the fluid
ounces that measure volume.
DO NOT WRITE ON THIS SHEET
DO NOT WRITE ON THIS SHEET
Symbol Meaning Base Unit Prefix
giga, G billion 1 L = 1×10–9 GL
mega, M million 1 L = 1×10–6 ML
kilo, k thousand 1 L = 0.001 kL
deci, d tenth 1 L = 10 dL
centi, c hundredth 1 L = 100 cL
milli, m thousandth 1 L = 1000 mL
micro, µ millionth 1 L = 1×106 µL
nano, n billionth 1 L = 1×109 nL
pico, p trillionth 1 L = 1×1012 pL
1×109 L = 1 GL
1×106 L = 1 ML
1000 L = 1 kL
0.1 L = 1 dL
0.01 L = 1 cL
0.001 L = 1 mL
1×10–6 L = 1 µL
1×10–9 L = 1 nL
1×10–12 L = 1 pL
SOME CONSTANTS AND EQUATIONS
density =
mass
volume
mass % element in a compound = g element
g compound
⨯ 100
c = speed of light = 3.00x108 m/s
Ephoton = h Planck’s constant = 6.626x10–34 J´s
E = hc
λ
Avogadro’s Number = 6.022x1023
ELECTROMAGNETIC SPECTRUM
ELECTRONEGATIVITIES FOR SOME OF THE ELEMENTS
H
2.1
Li
1.0
Be
1.5
B
2.0
C
2.5
N
3.0
O
3.5
F
4.0
Na
0.9
Mg
1.2
Al
1.5
Si
1.8
P
2.1
S
2.5
Cl
3.0
K
0.8
Ca
1.0
Sc
1.3
Ti
1.5
V
1.6
Cr
1.6
Mn
1.5
Fe
1.8
Co
1.9
Ni
1.9
Cu
1.9
Zn
1.6
Ga
1.6
Ge
1.8
As
2.0
Se
2.4
Br
2.8
Rb
0.8
Sr
1.0
Y
1.2
Zr
1.4
Nb
1.6
Mo
1.8
Tc
1.9
Ru
2.2
Rh
2.2
Pd
2.2
Ag
1.9
Cd
1.7
In
1.7
Sn
1.8
Sb
1.9
Te
2.1
I
2.5
Cs
0.7
Ba
0.9
La
1.0
Hf
1.3
Ta
1.5
W
1.7
Re
1.9
Os
2.2
Ir
2.2
Pt
2.2
Au
2.4
Hg
1.9
Tl
1.8
Pb
1.9
Bi
1.9
Po
2.0
At
2.2
Hp
0.7
Hm
0.8
Ws
1.0
Ss
1.2
Lp
1.3
Bl
1.5
Ad
1.7
Nv
1.9
Le
2.0
Mc
2.1
Rs
2.3
Gh
1.8
An
1.8
Fd
1.9
Sw
1.9
Gm
2.0
Gf
2.1
DO NOT WRITE ...
Library Orientation through power point presentation by the Indraprastha College Librarian Mr. Vijay Kumar Gautam to the Freashers of Undergraduate students
Vyom Shah recently spoke on Crowdfunding & Crowdsourcing at Vidarbha Management Association (VMA)
Businesses often rely on Debts (Bank Loans, Bonds etc.) or Equity (Share divestment, IPO etc.) for financing. However, a new alternative means of financing has emerged - Crowdfunding that does away with all the challenges and negativities of Debts and Equity. Crowdfunding has gained traction globally and in India too, and is increasingly been used by many orgnaizations. Several platforms have emerged to support this medium. Besides, similar to crowdfunding, companies have even started to get ideas and work delivered from public, through Crowdsourcing.
CONVERSIONS TO USE
METRIC PREFIXES
This table uses liters (L) as the base unit, but you can use this table for ANY base unit. For example, 1 s = 1×106 µs.
OR Base Unit Prefix
OR
OR
OR
OR
OR
OR
OR
OR
OR
NOTE: Two equivalence statements are written for each prefix. Either is equally correct (they are exactly the
same). Use whichever makes more sense to you.
OTHER CONVERSIONS
All of these are exact numbers except those marked with *
METRIC tt METRIC ENGLISH tt
ENGLISH
ENGLISH tt
METRIC
LENGTH 1 cm = 1×108 Å
(Å is the symbol for
angstroms)
12 in. = 1 ft.
3 ft. = 1 yd.
5280 ft. = 1 mi.
1 in. = 2.54 cm
1 mile = 1.609 km*
MASS / WEIGHT 1000 kg = 1 metric ton 2000 lb. = 1 ton
16 oz. = 1 lb.
1 lb. = 453.6 g*
VOLUME 1 L = 1 dm3
1 mL = 1 cm3
1000 L = 1 m3
3 tsp. = 1 Tbsp.
16 Tbsp. = 1 cup
2 cups = 1 pint
2 pints = 1 quart
4 quarts = 1 gal.
8 fluid oz. = 1 cup
1 qt. = 0.9464 L*
1 fluid oz. = 29.57 mL*
1 ft3 = 28.32 L*
TEMPERATURE TK = TC + 273.15 TF = 1.8(TC) + 32
TC = (TF - 32) / 1.8
ENERGY 1 cal = 4.184 J
NOTE: The ounces that measure mass are completely different from and unrelated to the fluid
ounces that measure volume.
DO NOT WRITE ON THIS SHEET
DO NOT WRITE ON THIS SHEET
Symbol Meaning Base Unit Prefix
giga, G billion 1 L = 1×10–9 GL
mega, M million 1 L = 1×10–6 ML
kilo, k thousand 1 L = 0.001 kL
deci, d tenth 1 L = 10 dL
centi, c hundredth 1 L = 100 cL
milli, m thousandth 1 L = 1000 mL
micro, µ millionth 1 L = 1×106 µL
nano, n billionth 1 L = 1×109 nL
pico, p trillionth 1 L = 1×1012 pL
1×109 L = 1 GL
1×106 L = 1 ML
1000 L = 1 kL
0.1 L = 1 dL
0.01 L = 1 cL
0.001 L = 1 mL
1×10–6 L = 1 µL
1×10–9 L = 1 nL
1×10–12 L = 1 pL
SOME CONSTANTS AND EQUATIONS
density =
mass
volume
mass % element in a compound = g element
g compound
⨯ 100
c = speed of light = 3.00x108 m/s
Ephoton = h Planck’s constant = 6.626x10–34 J´s
E = hc
λ
Avogadro’s Number = 6.022x1023
ELECTROMAGNETIC SPECTRUM
ELECTRONEGATIVITIES FOR SOME OF THE ELEMENTS
H
2.1
Li
1.0
Be
1.5
B
2.0
C
2.5
N
3.0
O
3.5
F
4.0
Na
0.9
Mg
1.2
Al
1.5
Si
1.8
P
2.1
S
2.5
Cl
3.0
K
0.8
Ca
1.0
Sc
1.3
Ti
1.5
V
1.6
Cr
1.6
Mn
1.5
Fe
1.8
Co
1.9
Ni
1.9
Cu
1.9
Zn
1.6
Ga
1.6
Ge
1.8
As
2.0
Se
2.4
Br
2.8
Rb
0.8
Sr
1.0
Y
1.2
Zr
1.4
Nb
1.6
Mo
1.8
Tc
1.9
Ru
2.2
Rh
2.2
Pd
2.2
Ag
1.9
Cd
1.7
In
1.7
Sn
1.8
Sb
1.9
Te
2.1
I
2.5
Cs
0.7
Ba
0.9
La
1.0
Hf
1.3
Ta
1.5
W
1.7
Re
1.9
Os
2.2
Ir
2.2
Pt
2.2
Au
2.4
Hg
1.9
Tl
1.8
Pb
1.9
Bi
1.9
Po
2.0
At
2.2
Hp
0.7
Hm
0.8
Ws
1.0
Ss
1.2
Lp
1.3
Bl
1.5
Ad
1.7
Nv
1.9
Le
2.0
Mc
2.1
Rs
2.3
Gh
1.8
An
1.8
Fd
1.9
Sw
1.9
Gm
2.0
Gf
2.1
DO NOT WRITE ...
Library Orientation through power point presentation by the Indraprastha College Librarian Mr. Vijay Kumar Gautam to the Freashers of Undergraduate students
How to Split Bills in the Odoo 17 POS ModuleCeline George
Bills have a main role in point of sale procedure. It will help to track sales, handling payments and giving receipts to customers. Bill splitting also has an important role in POS. For example, If some friends come together for dinner and if they want to divide the bill then it is possible by POS bill splitting. This slide will show how to split bills in odoo 17 POS.
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Synthetic Fiber Construction in lab .pptxPavel ( NSTU)
Synthetic fiber production is a fascinating and complex field that blends chemistry, engineering, and environmental science. By understanding these aspects, students can gain a comprehensive view of synthetic fiber production, its impact on society and the environment, and the potential for future innovations. Synthetic fibers play a crucial role in modern society, impacting various aspects of daily life, industry, and the environment. ynthetic fibers are integral to modern life, offering a range of benefits from cost-effectiveness and versatility to innovative applications and performance characteristics. While they pose environmental challenges, ongoing research and development aim to create more sustainable and eco-friendly alternatives. Understanding the importance of synthetic fibers helps in appreciating their role in the economy, industry, and daily life, while also emphasizing the need for sustainable practices and innovation.
This is a presentation by Dada Robert in a Your Skill Boost masterclass organised by the Excellence Foundation for South Sudan (EFSS) on Saturday, the 25th and Sunday, the 26th of May 2024.
He discussed the concept of quality improvement, emphasizing its applicability to various aspects of life, including personal, project, and program improvements. He defined quality as doing the right thing at the right time in the right way to achieve the best possible results and discussed the concept of the "gap" between what we know and what we do, and how this gap represents the areas we need to improve. He explained the scientific approach to quality improvement, which involves systematic performance analysis, testing and learning, and implementing change ideas. He also highlighted the importance of client focus and a team approach to quality improvement.
Unit 8 - Information and Communication Technology (Paper I).pdfThiyagu K
This slides describes the basic concepts of ICT, basics of Email, Emerging Technology and Digital Initiatives in Education. This presentations aligns with the UGC Paper I syllabus.
The Art Pastor's Guide to Sabbath | Steve ThomasonSteve Thomason
What is the purpose of the Sabbath Law in the Torah. It is interesting to compare how the context of the law shifts from Exodus to Deuteronomy. Who gets to rest, and why?
Ethnobotany and Ethnopharmacology:
Ethnobotany in herbal drug evaluation,
Impact of Ethnobotany in traditional medicine,
New development in herbals,
Bio-prospecting tools for drug discovery,
Role of Ethnopharmacology in drug evaluation,
Reverse Pharmacology.
Welcome to TechSoup New Member Orientation and Q&A (May 2024).pdfTechSoup
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The Roman Empire A Historical Colossus.pdfkaushalkr1407
The Roman Empire, a vast and enduring power, stands as one of history's most remarkable civilizations, leaving an indelible imprint on the world. It emerged from the Roman Republic, transitioning into an imperial powerhouse under the leadership of Augustus Caesar in 27 BCE. This transformation marked the beginning of an era defined by unprecedented territorial expansion, architectural marvels, and profound cultural influence.
The empire's roots lie in the city of Rome, founded, according to legend, by Romulus in 753 BCE. Over centuries, Rome evolved from a small settlement to a formidable republic, characterized by a complex political system with elected officials and checks on power. However, internal strife, class conflicts, and military ambitions paved the way for the end of the Republic. Julius Caesar’s dictatorship and subsequent assassination in 44 BCE created a power vacuum, leading to a civil war. Octavian, later Augustus, emerged victorious, heralding the Roman Empire’s birth.
Under Augustus, the empire experienced the Pax Romana, a 200-year period of relative peace and stability. Augustus reformed the military, established efficient administrative systems, and initiated grand construction projects. The empire's borders expanded, encompassing territories from Britain to Egypt and from Spain to the Euphrates. Roman legions, renowned for their discipline and engineering prowess, secured and maintained these vast territories, building roads, fortifications, and cities that facilitated control and integration.
The Roman Empire’s society was hierarchical, with a rigid class system. At the top were the patricians, wealthy elites who held significant political power. Below them were the plebeians, free citizens with limited political influence, and the vast numbers of slaves who formed the backbone of the economy. The family unit was central, governed by the paterfamilias, the male head who held absolute authority.
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Roman architecture and engineering achievements were monumental. They perfected the arch, vault, and dome, constructing enduring structures like the Colosseum, Pantheon, and aqueducts. These engineering marvels not only showcased Roman ingenuity but also served practical purposes, from public entertainment to water supply.
The Indian economy is classified into different sectors to simplify the analysis and understanding of economic activities. For Class 10, it's essential to grasp the sectors of the Indian economy, understand their characteristics, and recognize their importance. This guide will provide detailed notes on the Sectors of the Indian Economy Class 10, using specific long-tail keywords to enhance comprehension.
For more information, visit-www.vavaclasses.com
1. ELEMENTS OF SCIENCE
G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Hea
Me
Boi
lt
l
K
K
14.01
20.28
14.304
2.20
1400
4.002602(2)2 4 0.0001785 0.956
4.22
5.193
–
0.008
1560
3.582
0.98
20
Density
g / cm3
t
J/g·
Neg10
Abundance
mg / kg
K
the Greek'hydr
1
H
Hydrogen
o' and 'genes'
meaningwater-
1.0082 3 4 9
0.0000898
1
1
18
1
1
2
6.942 3 4 5 9
0.534
2
2
9.012182(3)
1.85
1560
2742
1.825
1.57
2.8
13
2
10.812 3 4 9
2.34
2349
4200
1.026
2.04
10
14
2
12.0112 4 9
2.267
3800
4300
0.709
2.55
200
15
2
14.0072 4 9
0.0012506 63.15
77.36
1.04
3.04
19
8
forming
the Greek
2
He
Helium
'helios'
meaning sun
the Greek
3
Li
Lithium
'lithos'
meaningstone
453.6
9
the Greek
4
Be
Beryllium
name for beryl,
'beryllo'
the Arabic'bura
5
B
Boron
q', which was
the name for
borax
the Latin'carbo',
6
C
Carbon
meaningcharco
al
the Greek
'nitron' and
7
N
Nitrogen
'genes'
meaningnitreforming
2. G
Sym
Element
r
ri
weight
u
name[1]
Atomic
o
Origin of
e
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
the Greek 'oxy'
8
O
Oxygen
and 'genes'
16
2
15.9992 4 9
0.001429
54.36
90.20
0.918
3.44
461000
17
2
18.9984032(5)
0.001696
53.53
85.03
0.824
3.98
585
18
meaningacid-
2
20.1797(6)2 3
0.0008999 24.56
27.07
1.03
–
0.005
1
3
1156
1.228
0.93
23600
2
3
24.3059
1.738
1363
1.023
1.31
23300
13
3
26.9815386(8)
2.698
2792
0.897
1.61
82300
14
3
28.0854 9
2.3296
3538
0.705
1.9
282000
forming
the Latin
9
F
Fluorine
'fluere',
meaning to
flow
the Greek
10
Ne
Neon
'neos',
meaning new
the Englishwor
11
Na
Sodium
d soda(natrium
in Latin)
[2]
22.98976928(
2)
0.971
370.8
7
Magnesia, a
12
Mg
Magnesium
district of
EasternThessal
923
y inGreece
the Latin name
for alum,
13
Al
Aluminium
'alumen'
meaningbitter
933.4
7[3]
salt
the Latin 'silex'
14
Si
Silicon
or 'silicis',
meaning flint
1687
3. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
the Greek
15
P
Phosphorus
'phosphoros',
meaningbringer
317.3
15
3
30.973762(2)
1.82
550
0.769
2.19
1050
16
3
32.062 4 9
2.067
717.87
0.71
2.58
350
17
3
35.452 3 4 9
0.003214
171.6 239.11
0.479
3.16
145
18
3
39.948(1)2 4
0.0017837 83.80
87.30
0.52
–
3.5
1
4
39.0983(1)
0.862
1032
0.757
0.82
20900
2
4
40.078(4)2
1.54
1115
1757
0.647
1
41500
3
4
44.955912(6)
2.989
1814
3109
0.568
1.36
22
0
of light
Either from
the Sanskrit'sul
vere', or the
16
S
Sulfur
Latin
'sulfurium', both
388.3
6
names for
sulfur[2]
the Greek
17
Cl
Chlorine
'chloros',
meaninggreeni
sh yellow
the Greek,
18
Ar
Argon
'argos',
meaning idle
the English
19
K
Potassium
word potash(ka
lium in Latin)[2]
20
Ca
Calcium
21
Sc
Scandium
the Latin 'calx'
meaninglime
336.5
3
Scandinavia(wi
th the Latin
nameScandia)
4. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
Titans, the
sons of the
22
Ti
Titanium
Earth goddess
4
4
47.867(1)
4.54
1941
3560
0.523
1.54
5650
5
4
50.9415(1)
6.11
2183
3680
0.489
1.63
120
6
4
51.9961(6)
7.15
2180
2944
0.449
1.66
102
7
4
54.938045(5)
7.44
1519
2334
0.479
1.55
950
8
4
55.845(2)
7.874
1811
3134
0.449
1.83
56300
9
4
58.933195(5)
8.86
1768
3200
0.421
1.88
25
of Greek
mythology
Vanadis, an
old Norsename
23
V
Vanadium
for the
Scandinavian
goddessFreyja
the Greek
24
Cr
Chromium
'chroma',
meaningcolour
Either the Latin
'magnes',
meaningmagne
t or from
25
Mn
Manganese
theblack
magnesium
oxide,
'magnesia
nigra'
the Anglo26
Fe
Iron
Saxon nameire
n (ferrumin
Latin)
the Germanwor
27
Co
Cobalt
d 'kobald',
meaninggoblin
5. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Hea
Me
Boi
lt
l
K
K
1728
3186
0.444
1.91
84
2835
0.385
1.9
60
1180
0.388
1.65
70
2477
0.371
1.81
19
3106
0.32
2.01
1.5
t
J/g·
Neg10
Abundance
mg / kg
K
the shortened
of the German
'kupfernickel'
28
Ni
Nickel
meaning
either devil's
10
4
58.6934(4)
8.912
11
4
63.546(3)4
8.96
12
4
65.38(2)
7.134
13
4
69.723(1)
5.907
14
4
72.630(8)
5.323
copper or St.
Nicholas's
copper
the Old English
namecoper in
turn derived
29
Cu
Copper
from the Latin
'Cyprium aes',
1357.
77[3]
meaning a
metal
fromCyprus
the German,
'zinc', which
may in turn be
30
Zn
Zinc
derived from
thePersian wor
692.8
8
d 'sing',
meaningstone
France (with
31
Ga
Gallium
the Latin
name Gallia)
302.9
146
Germany(with
32
Ge
Germanium
the Latin
nameGermania
)
1211.
40
6. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
the Greek
name
33
As
Arsenic
'arsenikon'
for the yellow
15
4
74.92160(2)
5.776
16
4
78.96(3)4
17
4
18
1090
7
887
0.329
2.18
1.8
4.809
453
958
0.321
2.55
0.05
79.9049
3.122
265.8
332.0
0.474
2.96
2.4
4
83.798(2)2 3
0.003733
119.93
0.248
3
<0.001
1
5
85.4678(3)2
1.532
961
0.363
0.82
90
2
5
87.62(1)2 4
2.64
1050
1655
0.301
0.95
370
3
5
88.90585(2)
4.469
1799
3609
0.298
1.22
33
4
5
91.224(2)2
6.506
2128
4682
0.278
1.33
165
pigmentorpime
nt
Moon (with the
34
Se
Selenium
Greek
nameselene)
the Greek
35
Br
Bromine
'bromos'
meaningstench
the Greek
36
Kr
Krypton
'kryptos',
meaninghidden
115.7
9
the Latin
37
Rb
Rubidium
'rubidius',
meaningdeepe
312.4
6
st red
Strontian, a
38
Sr
Strontium
small town
inScotland
39
Y
Yttrium
40
Zr
Zirconium
Ytterby,Swede
n
the Persian
'zargun',
meaninggold
7. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
coloured
Niobe,
daughter of
41
Nb
Niobium
king Tantalusfr
5
5
92.90638(2)
8.57
2750
5017
0.265
1.6
20
6
5
95.96(2)2
10.22
2896
4912
0.251
2.16
1.2
7
5
[98]1
11.5
2430
4538
–
1.9
<0.001
8
5
101.07(2)2
12.37
2607
4423
0.238
2.2
0.001
9
5
102.90550(2)
12.41
2237
3968
0.243
2.28
0.001
10
5
106.42(1)2
12.02
3236
0.244
2.2
0.015
om Greek
mythology
the Greek
42
Mo
Molybdenum
'molybdos'
meaninglead
the Greek
43
Tc
Technetium
'tekhnetos'
meaningartifici
al
Russia (with
44
Ru
Ruthenium
the Latin
nameRuthenia)
the Greek
45
Rh
Rhodium
'rhodon',
meaningrose
coloured
the then
recentlydiscovered
46
Pd
Palladium
asteroidPallas,
considered a
planet at the
time
1828.
05
8. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
the Anglo47
Ag
Silver
Saxon namesio
lfur(argentum i
11
5
107.8682(2)2
10.501
12
5
112.411(8)2
8.69
13
5
114.818(1)
7.31
14
5
118.710(7)2
7.287
15
5
121.760(1)2
6.685
16
5
127.60(3)2
6.232
17
5
126.90447(3)
4.93
1234.
93[3]
2435
0.235
1.93
0.075
1040
0.232
1.69
0.159
2345
0.233
1.78
0.25
2875
0.228
1.96
2.3
1860
0.207
2.05
0.2
1261
0.202
2.1
0.001
457.4
0.214
2.66
0.45
n Latin)[2]
the Latin name
48
Cd
Cadmium
for the mineral
calmine,
594.2
2
'cadmia'
the Latin
49
In
Indium
'indicium',
meaningviolet
429.7
5
orindigo
the AngloSaxon
50
Sn
Tin
wordtin (stannu
min Latin,
505.0
8
meaninghard)
the Greek 'anti
– monos',
51
Sb
Antimony
meaning not
alone(stibium i
903.7
8
n Latin)
Earth, the third
planet on solar
52
Te
Tellurium
system (with
the Latin
722.6
6
word tellus)
53
I
Iodine
the Greek
'iodes'
386.8
9. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
meaningviolet
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
5
the Greek
54
Xe
Xenon
'xenos'
meaningstrang
131.293(6)2 3
18
5
0.005887
1
6
2
6
137.327(7)
3.594
6
138.90547(7)2
6
161.4 165.03
0.158
2.6
<0.001
944
0.242
0.79
3
1000
2170
0.204
0.89
425
6.145
1193
3737
0.195
1.1
39
140.116(1)2
6.77
1068
3716
0.192
1.12
66.5
6
140.90765(2)
6.773
1208
3793
0.193
1.13
9.2
6
144.242(3)2
7.007
1297
3347
0.19
1.14
41.5
er
the Latin
55
Cs
Caesium
'caesius',
meaning sky
132.9054519(
2)
1.873
301.5
9
blue
the Greek
56
Ba
Barium
'barys',
meaningheavy
the Greek
57
La
Lanthanum
'lanthanein',
meaning to lie
hidden
Ceres,
58
Ce
Cerium
theRoman God
of agriculture
the Greek
'prasios
59
Pr
Praseodymium
didymos'
meaninggreen
twin
60
Nd
Neodymium
the Greek
'neos didymos'
meaning new
10. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
twin
Prometheusof
Greek
mythology who
61
Pm
Promethium
stole fire from
6
[145]1
7.26
1315
3273
–
1.13
<0.001
6
150.36(2)2
7.52
1345
2067
0.197
1.17
7.05
6
151.964(1)2
5.243
1099
1802
0.182
1.2
2
6
157.25(3)2
7.895
1585
3546
0.236
1.2
6.2
6
158.92535(2)
8.229
1629
3503
0.182
1.2
1.2
6
162.500(1)2
8.55
1680
2840
0.17
1.22
5.2
6
164.93032(2)
8.795
1734
2993
0.165
1.23
1.3
the Gods and
gave it to
humans
Samarskite, the
name of the
62
Sm
Samarium
mineral from
which it was
first isolated
63
Eu
Europium
Europe
Johan Gadolin,
64
Gd
Gadolinium
chemist,
physicist and
mineralogist
65
Tb
Terbium
Ytterby,
Sweden
the Greek
66
Dy
Dysprosium
'dysprositos',
meaninghard to
get
67
Ho
Holmium
Stockholm,
Sweden (with
the Latin
11. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
nameHolmia)
68
Er
Erbium
Ytterby,
6
167.259(3)2
9.066
1802
3141
0.168
1.24
3.5
6
168.93421(2)
9.321
1818
2223
0.16
1.25
0.52
6
173.054(5)2
6.965
1097
1469
0.155
1.1
3.2
3
6
174.9668(1)2
9.84
1925
3675
0.154
1.27
0.8
4
6
178.49(2)
13.31
2506
4876
0.144
1.3
3
5
6
180.94788(2)
16.654
3290
5731
0.14
1.5
2
6
6
183.84(1)
19.25
3695
5828
0.132
2.36
1.3
Sweden
Thule, the
69
Tm
Thulium
ancient name
for Scandinavia
70
Yb
Ytterbium
Ytterby,
Sweden
Paris, France
71
Lu
Lutetium
(with the
Roman
nameLutetia)
Copenhagen,
72
Hf
Hafnium
Denmark (with
the Latin
nameHafnia)
KingTantalus,
73
Ta
Tantalum
father of Niobe
from Greek
mythology
the Swedish
'tung sten'
meaningheavy
74
W
Tungsten
stone(W
iswolfram, the
old name of the
tungsten
mineral
12. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
wolframite)[2]
Rhine, a river
that flows
from Grisonsin
the
easternSwiss
75
Re
Rhenium
Alps to
7
6
186.207(1)
21.02
3459
5869
0.137
1.9
<0.001
8
6
190.23(3)2
22.61
3306
5285
0.13
2.2
0.002
9
6
192.217(3)
22.56
2719
4701
0.131
2.2
0.001
10
6
195.084(9)
21.46
4098
0.133
2.28
0.005
11
6
196.966569(4)
19.282
3129
0.129
2.54
0.004
12
6
200.592(3)
13.5336
629.88
0.14
2
0.085
the North
Sea coast in
theNetherlands
(with the Latin
nameRhenia)
the Greek
76
Os
Osmium
'osme',
meaningsmell
Iris, the Greek
77
Ir
Iridium
goddess of the
rainbow
the Spanish'pla
78
Pt
Platinum
tina',
meaning little
2041.
4[3]
silver
the AngloSaxon
79
Au
Gold
wordgold (auru
m in Latin,
1337.
33[3]
meaningglow
of sunrise)[2]
80
Hg
Mercury
Mercury, the
first planet in
234.4
13. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
the Solar
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
3
System (Hg
from former
namehydrargyr
um,from
Greekhydrwater
and argyrossilv
er)
the Greek
81
Tl
Thallium
'thallos',
meaning a
13
6
204.389
11.85
14
6
207.2(1)2 4
11.342
15
6
208.98040(1)1
9.807
16
6
[209]1
17
6
[210]1
577
1746
0.129
1.62
0.85
2022
0.129
1.87
14
544.7
1837
0.122
2.02
0.009
9.32
527
1235
–
2.0
<0.001
7
575
610
–
2.2
<0.001
green twig
the Anglo82
Pb
Lead
Saxon lead(plu
mbum in
600.6
1
Latin)[2]
the German
'Bisemutum' a
83
Bi
Bismuth
corruption of
'Weisse Masse'
meaningwhite
mass
Poland, the
native country
84
Po
Polonium
of Marie Curie,
who first
isolated the
element
85
At
Astatine
the Greek
'astatos',
meaningunstab
14. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
le
Fromradium,
as it was first
detected as an
86
Rn
Radon
emission from
18
6
[222]1
0.00973
202
211.3
0.094
2.2
<0.001
1
7
[223]1
1.87
300
950
–
0.7
<0.001
2
7
[226]1
5.5
973
2010
0.094
0.9
<0.001
7
[227]1
10.07
1323
3471
0.12
1.1
<0.001
2
11.72
2115
5061
0.113
1.3
9.6
231.03588(2)1
15.37
1841
4300
–
1.5
<0.001
radium during
radioactive
decay
France, where
87
Fr
Francium
it was first
discovered
the Latin
88
Ra
Radium
'radius',
meaning ray
the Greek
89
Ac
Actinium
'actinos',
meaning a ray
Thor, the
90
Th
Thorium
Scandinavian
7
232.03806(2)1
god of thunder
the Greek
'protos',
meaning first,
as a prefix to
91
Pa
Protactinium
the element
actinium, which
is produced
through the
radioactive
decay of
7
15. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
protactinium
Uranus, the
92
U
Uranium
seventh planet
in the Solar
7
238.02891(3)1
18.95
7
[237]1
20.45
7
[244]1
7
1405.
4404
0.116
1.38
2.7
917
4273
–
1.36
<0.001
19.84
912.5
3501
–
1.28
<0.001
[243]1
13.69
1449
2880
–
1.13
<0.001
7
[247]1
13.51
1613
3383
–
1.28
<0.001
7
[247]1
14.79
1259
2900
–
1.3
<0.001
3
System
Neptune, the
93
Np
Neptunium
eighth planet in
the Solar
System
Pluto, a dwarf
94
Pu
Plutonium
planet in the
Solar System
Americas, the
continent
95
Am
Americium
where the
element was
first
synthesized
Pierre Curie, a
physicist,
96
Cm
Curium
and Marie
Curie, a
physicist and
chemist
Berkeley,
97
Bk
Berkelium
California,
USA, where
the element
was first
16. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
synthesized
State of
California,
98
Cf
Californium
USA, where
7
[251]1
15.1
1173
7
[252]1
8.84
1133
7
[257]1
–
7
[258]1
–
7
[259]1
–
3
7
[262]1
–
4
7
[267]1
(23.2)11
the element
(1743)1
–
1.3
<0.001
1
–
1.3
08
–
–
1.3
08
–
–
1.3
08
–
–
1.3
08
–
–
1.3
08
–
–
08
1
was first
synthesized
99
Es
Einsteinium
100
Fm
Fermium
Albert Einstein,
physicist
Enrico Fermi,
physicist
(1125
)11
(1269)1
Dmitri
101
Md
Mendelevium
Mendeleyev,
chemist and
(1100
)11
inventor
Alfred Nobel,
chemist,
102
No
Nobelium
engineer,
innovator, and
(1100
)11
armaments
manufacturer
Ernest O.
103
Lr
Lawrencium
Lawrence,
physicist
104
Rf
Rutherfordium
Ernest
Rutherford,
chemist and
(1900
)11
(2400 (5800)1
)11
1
17. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
physicist
105
Db
Dubnium
Dubna, Russia
106
Sg
Seaborgium
Seaborg,
5
7
[268]1
(29.3)11
–
–
–
–
08
6
7
[269]1
(35.0)11
–
–
–
–
08
7
7
[270]1
(37.1)11
–
–
–
–
08
8
7
[269]1
(40.7)11
–
–
–
–
08
9
7
[278]1
(37.4)11
–
–
–
–
08
10
7
[281]1
(34.8)11
–
–
–
–
08
11
7
[281]1
(28.7)11
–
–
–
–
08
Glenn T.
scientist
107
Bh
Bohrium
Niels Bohr,
physicist
Hesse,
Germany,
108
Hs
Hassium
where the
element was
first
synthesized
109
Mt
Meitnerium
Lise Meitner,
physicist
Darmstadt,
Germany,
110
Ds
Darmstadtium
where the
element was
first
synthesized
Wilhelm
111
Rg
Roentgenium
Conrad
Röntgen,
physicist
18. G
Sym
Element
Origin of
name[1]
r
e
Atomic
o
ri
weight
u
o
u ()
p
Z
P
d
Density
g / cm3
Me
Boi
lt
l
K
K
Hea
t
J/g·
Neg10
Abundance
mg / kg
K
Nicolaus
112
Cn
Copernicium
Copernicus,
12
7
[285]1
(23.7)11
13
7
[286]1
(16)11
14
7
[289]1
(14)11
15
7
[288]1
(13.5)11
16
7
[293]1
(12.9)11
17
7
[294]1
(7.2)11
18
7
[294]1
(5.0)11 13
–
357 12
–
–
08
1
–
–
08
(420)11
–
–
08
–
–
08
1
–
–
08
(823)11
–
–
08
(263)11
–
–
08
astronomer
IUPACsystema
113
Uut
Ununtrium
tic element
(700)1 (1400)1
1
name
Georgy
114
Fl
Flerovium
Flyorov,
(340)1
1
physicist
IUPACsystema
115
Uup
Ununpentium
tic element
(700)1 (1400)1
1
1
name
Lawrence
Livermore
National
Laboratory(inLi
116
Lv
Livermorium
vermore,
California)
(708. (1085)1
5)11
which
collaborated
with JINR on its
synthesis
IUPACsystema
117
Uus
Ununseptium
tic element
(673)1
1
name
IUPACsystema
118
Uuo
Ununoctium
tic element
name
(258)1
1
19. Metal
Alkali metal
Alkaline earth metal
Lanthanide
Nonmetal
Actinide
Transition metal
Poor metal
Metalloid
Polyatomic nonmetal
Diatomic nonmeta