Introdução
Grupo: 13 or III A
Peso atômico: 204.3833
Período: 6
Número CAS: 7440-28-0
Classificação
Não Isótopos Estáveis
Sólido
Líquido
Gás
Sólido (previsto)
Descrição • Usos / Função
Thallium was discovered spectroscopically in 1861 by Crookes. The element was named after the beautiful green spectral line, which identifiedthe element. The metal was isolated both by Crookes and Lamy in 1862 about the same time. Thallium occurs in crooksite, lorandite, and hutchinsonite.It is also present in pyrites and is recovered from the roasting of this ore in connection with the production of sulfuric acid. It is also obtained fromthe smelting of lead and zinc ores. Extraction is somewhat complex and depends on the source of the thallium. Manganese nodules, found on the oceanfloor, contain thallium. When freshly exposed to air, thallium exhibits a metallic luster, but soon develops a bluish-gray tinge, resembling lead inappearance. A heavy oxide builds up on thallium if left in air, and in the presence of water the hydroxide is formed. The metal is very soft and malleable.It can be cut with a knife. forty seven isotopic forms of thallium, with atomic masses ranging from 179 to 210 are recognized. Natural thallium is amixture of two isotopes. The element and its compounds are toxic and should be handled carefully. Contact of the metal with skin is dangerous, andwhen melting the metal adequate ventilation should be provided. Thallium is suspected of carcinogenic potential for man. Thallium sulfate has beenwidely employed as a rodenticide and ant killer. It is odorless and tasteless, giving no warning of its presence. Its use, however, has been prohibitedin the U.S. since 1975 as a household insecticide and rodenticide. The electrical conductivity of thallium sulfide changes with exposure to infraredlight, and this compound is used in photocells. Thallium bromide-iodide crystals have been used as infrared optical materials. Thallium has been used,with sulfur or selenium and arsenic, to produce low melting glasses which become fluid between 125 and 150°C. These glasses have properties at roomtemperatures similar to ordinary glasses and are said to be durable and insoluble in water. Thallium oxide has been used to produce glasses with a highindex of refraction. Thallium has been used in treating ringworm and other skin infections; however, its use has been limited because of the narrowmargin between toxicity and therapeutic benefits. A mercury-thallium alloy, which forms a eutectic at 8.5% thallium, is reported to freeze at –60°C,some 20° below the freezing point of mercury. Thallium metal (99.999%) costs about $1/g. 1
• "has no practical uses as a free metal." 2
Propriedades físicas
Ponto de fusão:3* 304 °C = 577.15 K = 579.2 °F
Configuração Electron: [Xe] 6s2 4f14 5d10 6p1
n = 6
Eletronegatividade (escala Pauling):5 1.8
Calor específico: 0.129 J/g°C 9 = 26.365 J/mol°C = 0.031 cal/g°C = 6.301 cal/mol°C
Terra - Os compostos de origem: sulfides 15
Links externos:
(1) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 4:31.
Ponto de ebulição:3* 1473 °C = 1746.15 K = 2683.4 °F
Ponto de sublimação:3
Ponto Triplo:3
Ponto crítico:3
Densidade:4 11.8 g/cm3
* - at 1 atm
Configuração Electron
Quadra: p
Mais alto nível de energia Ocupado: 6
Elétrons de valência: 3
Números quânticos:
ℓ = 1
mℓ = -1
ms = +½
Colagem
Electropositivity (escala Pauling): 2.2
Electron Affinity:6 0.2 eV
oxidação Unidos: +1,3
Função no trabalho:7 4.02 eV = 6.44004E-19 J
potencial de ionização
eV 8
kJ/mol
1
6.1082
589.4
potencial de ionização
eV 8
kJ/mol
2
20.428
1971.0
potencial de ionização
eV 8
kJ/mol
3
29.83
2878.2
Termoquímica
Condutividade térmica: 46.1 (W/m)/K, 27°C 10
Calor de fusão: 4.142 kJ/mol 11 = 20.3 J/g
Calor da vaporização: 164.1 kJ/mol 12 = 802.9 J/g
Estado da matéria
Entalpia de formação (ΔHf°)13
entropia (S°)13
Gibbs Energia Livre (ΔGf°)13
(kcal/mol)
(kJ/mol)
(cal/K)
(J/K)
(kcal/mol)
(kJ/mol)
(s)
0
0
15.34
64.18256
0
0
(g)
43.55
182.2132
43.225
180.8534
35.24
147.44416
isótopos
nuclide
Massa 14
Meia vida 14
spin nuclear 14
Energia de ligação
176Tl
176.00059(21)#
5.2(+30-14) ms
(3-,4-,5-)
1,357.18 MeV
177Tl
176.996427(27)
18(5) ms
(1/2+)
1,374.57 MeV
178Tl
177.99490(12)#
255(10) ms
1,382.64 MeV
179Tl
178.99109(5)
270(30) ms
(1/2+)
1,390.71 MeV
180Tl
179.98991(13)#
1.5(2) s
1,408.09 MeV
181Tl
180.986257(10)
3.2(3) s
1/2+#
1,416.17 MeV
182Tl
181.98567(8)
2.0(3) s
2-#
1,424.24 MeV
183Tl
182.982193(10)
6.9(7) s
1/2+#
1,432.31 MeV
184Tl
183.98187(5)
9.7(6) s
2-#
1,440.38 MeV
185Tl
184.97879(6)
19.5(5) s
1/2+#
1,457.77 MeV
186Tl
185.97833(20)
40# s
(2-)
1,465.84 MeV
187Tl
186.975906(9)
~51 s
(1/2+)
1,473.91 MeV
188Tl
187.97601(4)
71(2) s
(2-)
1,481.98 MeV
189Tl
188.973588(12)
2.3(2) min
(1/2+)
1,490.05 MeV
190Tl
189.97388(5)
2.6(3) min
2(-)
1,498.12 MeV
191Tl
190.971786(8)
20# min
(1/2+)
1,506.19 MeV
192Tl
191.97223(3)
9.6(4) min
(2-)
1,514.27 MeV
193Tl
192.97067(12)
21.6(8) min
1/2(+#)
1,522.34 MeV
194Tl
193.97120(15)
33.0(5) min
2-
1,530.41 MeV
195Tl
194.969774(15)
1.16(5) h
1/2+
1,547.79 MeV
196Tl
195.970481(13)
1.84(3) h
2-
1,546.55 MeV
197Tl
196.969575(18)
2.84(4) h
1/2+
1,563.94 MeV
198Tl
197.97048(9)
5.3(5) h
2-
1,562.69 MeV
199Tl
198.96988(3)
7.42(8) h
1/2+
1,580.08 MeV
200Tl
199.970963(6)
26.1(1) h
2-
1,578.84 MeV
201Tl
200.970819(16)
72.912(17) h
1/2+
1,586.91 MeV
202Tl
201.972106(16)
12.23(2) d
2-
1,594.98 MeV
203Tl
202.9723442(14)
ESTÁVEL
1/2+
1,603.05 MeV
204Tl
203.9738635(13)
3.78(2) a
2-
1,611.12 MeV
205Tl
204.9744275(14)
ESTÁVEL
1/2+
1,619.19 MeV
206Tl
205.9761103(15)
4.200(17) min
0-
1,627.26 MeV
207Tl
206.977419(6)
4.77(2) min
1/2+
1,635.34 MeV
208Tl
207.9820187(21)
3.053(4) min
5(+)
1,634.09 MeV
209Tl
208.985359(8)
2.161(7) min
(1/2+)
1,642.16 MeV
210Tl
209.990074(12)
1.30(3) min
(5+)#
1,640.92 MeV
211Tl
210.99348(22)#
1# min [>300 ns]
1/2+#
1,648.99 MeV
212Tl
211.99823(32)#
30# s [>300 ns]
5+#
1,657.06 MeV
Os valores marcados # não são puramente derivado a partir de dados experimentais, mas, pelo menos, parcialmente a partir de tendências sistemáticas. Gira com argumentos de atribuição fracos estão entre parênteses. 14
Abundância
Terra - A água do mar: 0.000019 mg/L 16
Terra -
crosta:
0.85 mg/kg = 0.000085% 16
Terra -
Total:
3.86 ppb 17
Planeta Mercúrio) -
Total:
0.044 ppb 17
Vênus -
Total:
4.05 ppb 17
condritos - Total: 0.001 (relative to 106 atoms of Si) 18
compostos
thallium(I) acetate; thallous acetate
thallium(I) bromide
thallium(I) carbonate; thallous carbonate
thallium(I) chlorate
thallium(I) chloride; thallous chloride
thallium(I) cyanide
thallium(I) ethoxide
thallium(I) fluoride
thallium(I) formate
thallium(I) hexafluorophosphate
Informação de Segurança
Material Safety Data Sheet - ACI Alloys, Inc.
Para maiores informações
American Elements
Chemical & Engineering News
Chemical Elements
ChemGlobe
Chemicool
Environmental Chemistry
Fontes
(2) - Whitten, Kenneth W., Davis, Raymond E., and Peck, M. Larry. General Chemistry 6th ed.; Saunders College Publishing: Orlando, FL, 2000; p 933.
(3) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 4:132.
(4) - Lide, David R. CRC Handbook of Chemistry and Physics, 84th ed.; CRC Press: Boca Raton, FL, 2002; p 4:39-4:96.
(5) - Dean, John A. Lange's Handbook of Chemistry, 11th ed.; McGraw-Hill Book Company: New York, NY, 1973; p 4:8-4:149.
(6) - Lide, David R. CRC Handbook of Chemistry and Physics, 84th ed.; CRC Press: Boca Raton, FL, 2002; p 10:147-10:148.
(7) - Speight, James. Lange's Handbook of Chemistry, 16th ed.; McGraw-Hill Professional: Boston, MA, 2004; p 1:132.
(8) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 10:178 - 10:180.
(9) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 4:133.
(10) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; pp 6:193, 12:219-220.
(11) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; pp 6:123-6:137.
(12) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; pp 6:107-6:122.
(13) - Dean, John A. Lange's Handbook of Chemistry, 12th ed.; McGraw-Hill Book Company: New York, NY, 1979; p 9:4-9:94.
(14) - Atomic Mass Data Center. http://amdc.in2p3.fr/web/nubase_en.html (accessed July 14, 2009).
(15) - Silberberg, Martin S. Chemistry: The Molecular Nature of Matter and Change, 4th ed.; McGraw-Hill Higher Education: Boston, MA, 2006, p 965.
(16) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 14:17.
(17) - Morgan, John W. and Anders, Edward, Proc. Natl. Acad. Sci. USA 77, 6973-6977 (1980)
(18) - Brownlow, Arthur. Geochemistry; Prentice-Hall, Inc.: Englewood Cliffs, NJ, 1979, pp 15-16.