テルル

導入

原子番号: 52
グループ: 16 or VI A
原子量: 127.6
期間: 5
CAS番号: 13494-80-9

分類

カルコゲン
ハロゲン
希ガス
ランタノイド元素
アクチノイド元素
希土類元素
プラチナグループメタル
超ウラン
いいえ安定同位体ません
固体
液体
ガス
固体 (予測)

説明 • 用途/機能

Discovered by Muller von Reichenstein in 1782; named by Klaproth, who isolated it in 1798. Tellurium is occasionally found native, but is more often found asthe telluride of gold (calaverite), and combined with other metals. It is recovered commercially from the anode muds produced during the electrolyticrefining of blister copper. The U.S., Canada, Peru, and Japan are the largest Free World producers of the element. Crystalline tellurium has a silverywhiteappearance, and when pure exhibits a metallic luster. It is brittle and easily pulverized. Amorphous tellurium is formed by precipitating telluriumfrom a solution of telluric or tellurous acid. Whether this form is truly amorphous, or made of minute crystals, is open to question. Tellurium is a ptypesemiconductor, and shows greater conductivity in certain directions, depending on alignment of the atoms. Its conductivity increases slightly withexposure to light. It can be doped with silver, copper, gold, tin, or other elements. In air, tellurium burns with a greenish-blue flame, forming the dioxide.Molten tellurium corrodes iron, copper, and stainless steel. Tellurium and its compounds are probably toxic and should be handled with care. Workmenexposed to as little as 0.01 mg/m^3 of air, or less, develop “tellurium breath,” which has a garlic-like odor. Forty two isotopes and isomers of telluriumare known, with atomic masses ranging from 106 to 138. Natural tellurium consists of eight isotopes, two of which are radioactive with very long halflives.Tellurium improves the machinability of copper and stainless steel, and its addition to lead decreases the corrosive action of sulfuric acid on leadand improves its strength and hardness. Tellurium is used as a basic ingredient in blasting caps, and is added to cast iron for chill control. Telluriumis used in ceramics. Bismuth telluride has been used in thermoelectric devices. Tellurium costs about 20¢/g, with a purity of about 99.5%. The metalwith a purity of 99.9999% costs about $2/g. 1

• "It is added to some metals, particularly lead, to increase electrical resistance and improve resistance to heat, corrosion, mechanical shock, and wear." 2

物理的特性

融点:3*  449.51 °C = 722.66 K = 841.118 °F
沸点:3* 988 °C = 1261.15 K = 1810.4 °F
昇華点:3 
三重点:3 
臨界点:3 
密度:4  6.24 g/cm3

* - at 1 atm

電子構成

電子構成: [Kr] 5s2 4d10 5p4
ブロック: p
最高占有エネルギーレベル: 5
ヴァランス電子: 6

量子数:

n = 5
ℓ = 1
m = -1
ms = -½

ボンディング

電気陰性度 (ポーリングスケール):5 2.1
Electropositivity (ポーリングスケール): 1.9
電子親和力:6 1.9708 eV
酸化状態: +4,6,-2
仕事関数:7 4.70 eV = 7.5294E-19 J

イオン化ポテンシャル   eV 8  kJ/mol  
1 9.0096    869.3
2 18.6    1794.6
イオン化ポテンシャル   eV 8  kJ/mol  
3 27.96    2697.7
4 37.41    3609.5
イオン化ポテンシャル   eV 8  kJ/mol  
5 58.75    5668.5
6 70.7    6821.5
7 137    13218.5

熱化学

比熱: 0.202 J/g°C 9 = 25.775 J/mol°C = 0.048 cal/g°C = 6.160 cal/mol°C
熱伝導率: 2.35 (W/m)/K, 27°C 10
融解熱: 17.49 kJ/mol 11 = 137.1 J/g
気化熱: 52.55 kJ/mol 12 = 411.8 J/g
物質の状態 生成エンタルピー (ΔHf°)13 エントロピ (S°)13 ギブズ自由エネルギー (ΔGf°)13
(kcal/mol) (kJ/mol) (cal/K) (J/K) (kcal/mol) (kJ/mol)
(s) 0 0 11.88 49.70592 0 0
(g) 47.02 196.73168 43.65 182.6316 37.55 157.1092

同位体

核種 質量 14 人生の半分 14 核スピン 14 結合エネルギー
105Te 104.94364(54)# 1# μs 5/2+# 862.69 MeV
106Te 105.93750(14) 70(20) μs [70(+20-10) μs] 0+ 880.08 MeV
107Te 106.93501(32)# 3.1(1) ms 5/2+# 888.15 MeV
108Te 107.92944(11) 2.1(1) s 0+ 905.54 MeV
109Te 108.92742(7) 4.6(3) s (5/2+) 913.61 MeV
110Te 109.92241(6) 18.6(8) s 0+ 921.68 MeV
111Te 110.92111(8) 19.3(4) s (5/2)+# 929.75 MeV
112Te 111.91701(18) 2.0(2) min 0+ 947.14 MeV
113Te 112.91589(3) 1.7(2) min (7/2+) 955.21 MeV
114Te 113.91209(3) 15.2(7) min 0+ 963.28 MeV
115Te 114.91190(3) 5.8(2) min 7/2+ 971.35 MeV
116Te 115.90846(3) 2.49(4) h 0+ 988.74 MeV
117Te 116.908645(14) 62(2) min 1/2+ 996.81 MeV
118Te 117.905828(16) 6.00(2) d 0+ 1,004.88 MeV
119Te 118.906404(9) 16.05(5) h 1/2+ 1,012.95 MeV
120Te 119.90402(1) STABLE 0+ 1,021.02 MeV
121Te 120.904936(28) 19.16(5) d 1/2+ 1,029.10 MeV
122Te 121.9030439(16) STABLE 0+ 1,037.17 MeV
123Te 122.9042700(16) >600E+12 a 1/2+ 1,045.24 MeV
124Te 123.9028179(16) STABLE 0+ 1,053.31 MeV
125Te 124.9044307(16) STABLE 1/2+ 1,061.38 MeV
126Te 125.9033117(16) STABLE 0+ 1,069.45 MeV
127Te 126.9052263(16) 9.35(7) h 3/2+ 1,077.52 MeV
128Te 127.9044631(19) 2.2(3)E+24 a 0+ 1,085.59 MeV
129Te 128.9065982(19) 69.6(3) min 3/2+ 1,093.67 MeV
130Te 129.9062244(21) 790(100)E+18 a 0+ 1,101.74 MeV
131Te 130.9085239(21) 25.0(1) min 3/2+ 1,109.81 MeV
132Te 131.908553(7) 3.204(13) d 0+ 1,117.88 MeV
133Te 132.910955(26) 12.5(3) min (3/2+) 1,116.64 MeV
134Te 133.911369(11) 41.8(8) min 0+ 1,124.71 MeV
135Te 134.91645(10) 19.0(2) s (7/2-) 1,132.78 MeV
136Te 135.92010(5) 17.63(8) s 0+ 1,131.54 MeV
137Te 136.92532(13) 2.49(5) s 3/2-# 1,139.61 MeV
138Te 137.92922(22)# 1.4(4) s 0+ 1,147.68 MeV
139Te 138.93473(43)# 500# ms [>300 ns] 5/2-# 1,146.43 MeV
140Te 139.93885(32)# 300# ms [>300 ns] 0+ 1,154.51 MeV
141Te 140.94465(43)# 100# ms [>300 ns] 5/2-# 1,153.26 MeV
142Te 141.94908(64)# 50# ms [>300 ns] 0+ 1,161.33 MeV
値は、#は、純粋に実験データから派生しますが、少なくとも部分的に体系的な傾向からしていないとマーク。弱い代入引数は括弧で囲まれていてスピン。 14

豊富

地球 - ソース化合物: sulfides 15
地球 -  地殻:  0.001 mg/kg = 0.0000001% 15
地球 -  合計:  1490 ppb 16
マーキュリー(惑星) -  合計:  122 ppb 16
金星 -  合計:  830 ppb 16
コンドライト - 合計: 0.60 (relative to 106 atoms of Si) 17

化合物

安全情報


安全データシート - ACI Alloys, Inc.

詳細については

外部リンク:

ソース

(1) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 4:31.
(2) - Whitten, Kenneth W., Davis, Raymond E., and Peck, M. Larry. General Chemistry 6th ed.; Saunders College Publishing: Orlando, FL, 2000; p 953.
(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) - Lide, David R. CRC Handbook of Chemistry and Physics, 84th ed.; CRC Press: Boca Raton, FL, 2002; p 10:147-10:148.
(6) - Speight, James. Lange's Handbook of Chemistry, 16th ed.; McGraw-Hill Professional: Boston, MA, 2004; p 1:132.
(7) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 10:178 - 10:180.
(8) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 4:133.
(9) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; pp 6:193, 12:219-220.
(10) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; pp 6:123-6:137.
(11) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; pp 6:107-6:122.
(12) - Dean, John A. Lange's Handbook of Chemistry, 12th ed.; McGraw-Hill Book Company: New York, NY, 1979; p 9:4-9:94.
(13) - Atomic Mass Data Center. http://amdc.in2p3.fr/web/nubase_en.html (accessed July 14, 2009).
(14) - Silberberg, Martin S. Chemistry: The Molecular Nature of Matter and Change, 4th ed.; McGraw-Hill Higher Education: Boston, MA, 2006, p 965.
(15) - Lide, David R. CRC Handbook of Chemistry and Physics, 83rd ed.; CRC Press: Boca Raton, FL, 2002; p 14:17.
(16) - Morgan, John W. and Anders, Edward, Proc. Natl. Acad. Sci. USA 77, 6973-6977 (1980)
(17) - Brownlow, Arthur. Geochemistry; Prentice-Hall, Inc.: Englewood Cliffs, NJ, 1979, pp 15-16.