Monday, February 21, 2011

物質材料研究機構成功開發出世界最小的強介電體 www.tool-tool.com

日 本物質材料研究機構於今(2010)年10/26公開發表,其將厚度為分子等級的氧化物奈米薄片(nano sheet)交互重疊,成功開發出世界最小的強介電體。新技術在成為強介電體奈米材料設計應用研究方針的同時,對於使用以低電壓便可運作之強介電體奈米薄 膜製成的低耗電記憶體、IC晶片卡之開發也有密不可分的關係。

圖說:人工超晶格之透過型電子顯微鏡影像

研究團隊利用人工超晶格(Superlattice)技術製造全世界厚度最薄、僅10奈米的薄膜,開發出奈米等級的強介電體。新產品在室溫下展現出優越的強誘電性,這是首次以奈米物質之組合製作出強介電體。

新 產品擁有與強介電體代表材料之鋯鈦酸鉛(Lead Zirconate Titanate, PZT)類似的構造,並使用兩種不含有毒物質鉛金屬的氧化物奈米薄片將之相互重疊製作人工超晶格。研究團隊讓接合部分的離子變位、容易分極以使新產品擁有 強誘電性。由於這項技術不需要用到薄膜製程主流的大型真空設備或昂貴的成膜裝置,所以能夠以低成本方式進行生產;特別是不必經過熱處理程序,在室溫下就能 製造強介電體薄膜,故可朝玻璃基板、塑膠基板上製作強介電體裝置等用途繼續研究。

資料來源: 日刊工業新聞/材料世界網編譯

引用出處:

http://www.materialsnet.com.tw/DocView.aspx?id=9005

歡迎來到Bewise Inc.的世界,首先恭喜您來到這接受新的資訊讓產業更有競爭力,我們是提供專業刀具製造商,應對客戶高品質的刀具需求,我們可以協助客戶滿足您對產業的不同要求,我們有能力達到非常卓越的客戶需求品質,這是現有相關技術無法比擬的,我們成功的滿足了各行各業的要求,包括:精密HSS DIN切削刀具協助客戶設計刀具流程DIN or JIS 鎢鋼切削刀具設計NAS986 NAS965 NAS897 NAS937orNAS907 航太切削刀具,NAS航太刀具設計超高硬度的切削刀具醫療配件刀具設計複合式再研磨機PCD地板專用企口鑽石組合刀具粉末造粒成型機主機版專用頂級電桿PCBN刀具PCD刀具單晶刀具PCD V-Cut捨棄式圓鋸片組粉末成型機航空機械鉸刀主機版專用頂級電汽車業刀具設計電子產業鑽石刀具木工產業鑽石刀具銑刀與切斷複合再研磨機銑刀與鑽頭複合再研磨機銑刀與螺絲攻複合再研磨機等等。我們的產品涵蓋了從民生刀具到工業級的刀具設計;從微細刀具到大型刀具;從小型生產到大型量產;全自動整合;我們的技術可提供您連續生產的效能,我們整體的服務及卓越的技術,恭迎您親自體驗!!

BW Bewise Inc. Willy Chen willy@tool-tool.com bw@tool-tool.com www.tool-tool.com skype:willy_chen_bw mobile:0937-618-190 Head &Administration Office No.13,Shiang Shang 2nd St., West Chiu Taichung,Taiwan 40356 http://www.tool-tool.com/ / FAX:+886 4 2471 4839 N.Branch 5F,No.460,Fu Shin North Rd.,Taipei,Taiwan S.Branch No.24,Sec.1,Chia Pu East Rd.,Taipao City,Chiayi Hsien,Taiwan

Welcome to BW tool world! We are an experienced tool maker specialized in cutting tools. We focus on what you need and endeavor to research the best cutter to satisfy users demand. Our customers involve wide range of industries, like mold & die, aerospace, electronic, machinery, etc. We are professional expert in cutting field. We would like to solve every problem from you. Please feel free to contact us, its our pleasure to serve for you. BW product including: cutting toolaerospace tool .HSS DIN Cutting toolCarbide end millsCarbide cutting toolNAS Cutting toolNAS986 NAS965 NAS897 NAS937orNAS907 Cutting Tools,Carbide end milldisc milling cutter,Aerospace cutting toolhss drillФрезерыCarbide drillHigh speed steelCompound SharpenerMilling cutterINDUCTORS FOR PCD’CVDD(Chemical Vapor Deposition Diamond )’PCBN (Polycrystalline Cubic Boron Nitride) Core drillTapered end millsCVD Diamond Tools Inserts’PCD Edge-Beveling Cutter(Golden FingerPCD V-CutterPCD Wood toolsPCD Cutting toolsPCD Circular Saw BladePVDD End Millsdiamond tool. INDUCTORS FOR PCD . POWDER FORMING MACHINE Single Crystal Diamond Metric end millsMiniature end millsСпециальные режущие инструментыПустотелое сверло Pilot reamerFraisesFresas con mango PCD (Polycrystalline diamond) ‘FresePOWDER FORMING MACHINEElectronics cutterStep drillMetal cutting sawDouble margin drillGun barrelAngle milling cutterCarbide burrsCarbide tipped cutterChamfering toolIC card engraving cutterSide cutterStaple CutterPCD diamond cutter specialized in grooving floorsV-Cut PCD Circular Diamond Tipped Saw Blade with Indexable Insert PCD Diamond Tool Saw Blade with Indexable InsertNAS toolDIN or JIS toolSpecial toolMetal slitting sawsShell end millsSide and face milling cuttersSide chip clearance sawsLong end millsend mill grinderdrill grindersharpenerStub roughing end millsDovetail milling cuttersCarbide slot drillsCarbide torus cuttersAngel carbide end millsCarbide torus cuttersCarbide ball-nosed slot drillsMould cutterTool manufacturer.

Bewise Inc. www.tool-tool.com

ようこそBewise Inc.の世界へお越し下さいませ、先ず御目出度たいのは新たな

情報を受け取って頂き、もっと各産業に競争力プラス展開。

弊社は専門なエンドミルの製造メーカーで、客先に色んな分野のニーズ

豊富なパリエーションを満足させ、特にハイテク品質要求にサポート致します。

弊社は各領域に供給できる内容は:

(1)精密HSSエンドミルのR&D

(2)Carbide Cutting tools設計

(3)鎢鋼エンドミル設計

(4)航空エンドミル設計

(5)超高硬度エンドミル

(6)ダイヤモンドエンドミル

(7)医療用品エンドミル設計

(8)自動車部品&材料加工向けエンドミル設計

弊社の製品の供給調達機能は:

(1)生活産業~ハイテク工業までのエンドミル設計

(2)ミクロエンドミル~大型エンドミル供給

(3)小Lot生産~大量発注対応供給

(4)オートメーション整備調達

(5)スポット対応~流れ生産対応

弊社の全般供給体制及び技術自慢の総合専門製造メーカーに貴方のご体験を御待ちしております。

Bewise Inc. talaşlı imalat sanayinde en fazla kullanılan ve üç eksende (x,y,z) talaş kaldırabilen freze takımlarından olan Parmak Freze imalatçısıdır. Çok geniş ürün yelpazesine sahip olan firmanın başlıca ürünlerini Karbür Parmak Frezeler, Kalıpçı Frezeleri, Kaba Talaş Frezeleri, Konik Alın Frezeler, Köşe Radyüs Frezeler, İki Ağızlı Kısa ve Uzun Küresel Frezeler, İç Bükey Frezeler vb. şeklinde sıralayabiliriz.

BW специализируется в научных исследованиях и разработках, и снабжаем самым высокотехнологичным карбидовым материалом для поставки режущих / фрезеровочных инструментов для почвы, воздушного пространства и электронной индустрии. В нашу основную продукцию входит твердый карбид / быстрорежущая сталь, а также двигатели, микроэлектрические дрели, IC картонорезальные машины, фрезы для гравирования, режущие пилы, фрезеры-расширители, фрезеры-расширители с резцом, дрели, резаки форм для шлицевого вала / звездочки роликовой цепи, и специальные нано инструменты. Пожалуйста, посетите сайт www.tool-tool.com для получения большей информации.

BW is specialized in R&D and sourcing the most advanced carbide material with high-tech coating to supply cutting / milling tool for mould & die, aero space and electronic industry. Our main products include solid carbide / HSS end mills, micro electronic drill, IC card cutter, engraving cutter, shell end mills, cutting saw, reamer, thread reamer, leading drill, involute gear cutter for spur wheel, rack and worm milling cutter, thread milling cutter, form cutters for spline shaft/roller chain sprocket, and special tool, with nano grade. Please visit our web www.tool-tool.com for more info.

產總研開發出耐熱超過1000℃的金屬薄膜 www.tool-tool.com

日本產業技術總合研究所秋山守人組長所領軍的研究團隊開發出可耐熱攝氏1000千度以上高溫之金屬薄膜製造技術。研究團隊先做出兩種金屬薄膜,然後再將之製為合金。

以 往的薄膜只要超過攝氏1000度就容易與空氣中的氧氣或氮氣進行化學反應,因此存在著會自貼附的基板上剝離的問 題。新開發的製造方法則是在耐熱材料氧化鋯基板上製作厚度約100奈米的釕(ruthenium)薄膜,然後於釕薄膜上方製作同樣厚度的鎢 (tungsten)薄膜;最後再以攝氏1450度加熱一個小時,使釕與鎢結合為合金。研究團隊藉由加熱實驗來確保新產品的導電性並確認不會有剝離或破碎 的情況發生。假使以其他的鉑系元素如銠(Rhodium)或鉑來取代釕、以鉻(chromium)或鎳(Nickel)等其他高熔點的金屬來取代鎢的話, 也能夠達到同樣的性能。

噴射引擎、發電用渦輪、鐵工廠高溫爐等周邊往往都超過攝氏 1000度高溫,為了檢測故障狀況便需要可長時間調查震動 或壓力等的感應器;然而一直以來卻沒有可用於1000度以上的感應器,所以必須要先停止機器的運轉後才能進行檢查。此次開發的新產品除將以高溫環境異常檢 測感應器之電極為應用目標外,研究團隊今後也將以開發可耐攝氏2000度以上的金屬薄膜為主要研究方向。

資料來源: 日經產業新聞/材料新聞網編譯

引用出處:

http://www.materialsnet.com.tw/DocView.aspx?id=9127

歡迎來到Bewise Inc.的世界,首先恭喜您來到這接受新的資訊讓產業更有競爭力,我們是提供專業刀具製造商,應對客戶高品質的刀具需求,我們可以協助客戶滿足您對產業的不同要求,我們有能力達到非常卓越的客戶需求品質,這是現有相關技術無法比擬的,我們成功的滿足了各行各業的要求,包括:精密HSS DIN切削刀具協助客戶設計刀具流程DIN or JIS 鎢鋼切削刀具設計NAS986 NAS965 NAS897 NAS937orNAS907 航太切削刀具,NAS航太刀具設計超高硬度的切削刀具醫療配件刀具設計複合式再研磨機PCD地板專用企口鑽石組合刀具粉末造粒成型機主機版專用頂級電桿PCBN刀具PCD刀具單晶刀具PCD V-Cut捨棄式圓鋸片組粉末成型機航空機械鉸刀主機版專用頂級電汽車業刀具設計電子產業鑽石刀具木工產業鑽石刀具銑刀與切斷複合再研磨機銑刀與鑽頭複合再研磨機銑刀與螺絲攻複合再研磨機等等。我們的產品涵蓋了從民生刀具到工業級的刀具設計;從微細刀具到大型刀具;從小型生產到大型量產;全自動整合;我們的技術可提供您連續生產的效能,我們整體的服務及卓越的技術,恭迎您親自體驗!!

BW Bewise Inc. Willy Chen willy@tool-tool.com bw@tool-tool.com www.tool-tool.com skype:willy_chen_bw mobile:0937-618-190 Head &Administration Office No.13,Shiang Shang 2nd St., West Chiu Taichung,Taiwan 40356 http://www.tool-tool.com/ / FAX:+886 4 2471 4839 N.Branch 5F,No.460,Fu Shin North Rd.,Taipei,Taiwan S.Branch No.24,Sec.1,Chia Pu East Rd.,Taipao City,Chiayi Hsien,Taiwan

Welcome to BW tool world! We are an experienced tool maker specialized in cutting tools. We focus on what you need and endeavor to research the best cutter to satisfy users demand. Our customers involve wide range of industries, like mold & die, aerospace, electronic, machinery, etc. We are professional expert in cutting field. We would like to solve every problem from you. Please feel free to contact us, its our pleasure to serve for you. BW product including: cutting toolaerospace tool .HSS DIN Cutting toolCarbide end millsCarbide cutting toolNAS Cutting toolNAS986 NAS965 NAS897 NAS937orNAS907 Cutting Tools,Carbide end milldisc milling cutter,Aerospace cutting toolhss drillФрезерыCarbide drillHigh speed steelCompound SharpenerMilling cutterINDUCTORS FOR PCD’CVDD(Chemical Vapor Deposition Diamond )’PCBN (Polycrystalline Cubic Boron Nitride) Core drillTapered end millsCVD Diamond Tools Inserts’PCD Edge-Beveling Cutter(Golden FingerPCD V-CutterPCD Wood toolsPCD Cutting toolsPCD Circular Saw BladePVDD End Millsdiamond tool. INDUCTORS FOR PCD . POWDER FORMING MACHINE Single Crystal Diamond Metric end millsMiniature end millsСпециальные режущие инструментыПустотелое сверло Pilot reamerFraisesFresas con mango PCD (Polycrystalline diamond) ‘FresePOWDER FORMING MACHINEElectronics cutterStep drillMetal cutting sawDouble margin drillGun barrelAngle milling cutterCarbide burrsCarbide tipped cutterChamfering toolIC card engraving cutterSide cutterStaple CutterPCD diamond cutter specialized in grooving floorsV-Cut PCD Circular Diamond Tipped Saw Blade with Indexable Insert PCD Diamond Tool Saw Blade with Indexable InsertNAS toolDIN or JIS toolSpecial toolMetal slitting sawsShell end millsSide and face milling cuttersSide chip clearance sawsLong end millsend mill grinderdrill grindersharpenerStub roughing end millsDovetail milling cuttersCarbide slot drillsCarbide torus cuttersAngel carbide end millsCarbide torus cuttersCarbide ball-nosed slot drillsMould cutterTool manufacturer.

Bewise Inc. www.tool-tool.com

ようこそBewise Inc.の世界へお越し下さいませ、先ず御目出度たいのは新たな

情報を受け取って頂き、もっと各産業に競争力プラス展開。

弊社は専門なエンドミルの製造メーカーで、客先に色んな分野のニーズ

豊富なパリエーションを満足させ、特にハイテク品質要求にサポート致します。

弊社は各領域に供給できる内容は:

(1)精密HSSエンドミルのR&D

(2)Carbide Cutting tools設計

(3)鎢鋼エンドミル設計

(4)航空エンドミル設計

(5)超高硬度エンドミル

(6)ダイヤモンドエンドミル

(7)医療用品エンドミル設計

(8)自動車部品&材料加工向けエンドミル設計

弊社の製品の供給調達機能は:

(1)生活産業~ハイテク工業までのエンドミル設計

(2)ミクロエンドミル~大型エンドミル供給

(3)小Lot生産~大量発注対応供給

(4)オートメーション整備調達

(5)スポット対応~流れ生産対応

弊社の全般供給体制及び技術自慢の総合専門製造メーカーに貴方のご体験を御待ちしております。

Bewise Inc. talaşlı imalat sanayinde en fazla kullanılan ve üç eksende (x,y,z) talaş kaldırabilen freze takımlarından olan Parmak Freze imalatçısıdır. Çok geniş ürün yelpazesine sahip olan firmanın başlıca ürünlerini Karbür Parmak Frezeler, Kalıpçı Frezeleri, Kaba Talaş Frezeleri, Konik Alın Frezeler, Köşe Radyüs Frezeler, İki Ağızlı Kısa ve Uzun Küresel Frezeler, İç Bükey Frezeler vb. şeklinde sıralayabiliriz.

BW специализируется в научных исследованиях и разработках, и снабжаем самым высокотехнологичным карбидовым материалом для поставки режущих / фрезеровочных инструментов для почвы, воздушного пространства и электронной индустрии. В нашу основную продукцию входит твердый карбид / быстрорежущая сталь, а также двигатели, микроэлектрические дрели, IC картонорезальные машины, фрезы для гравирования, режущие пилы, фрезеры-расширители, фрезеры-расширители с резцом, дрели, резаки форм для шлицевого вала / звездочки роликовой цепи, и специальные нано инструменты. Пожалуйста, посетите сайт www.tool-tool.com для получения большей информации.

BW is specialized in R&D and sourcing the most advanced carbide material with high-tech coating to supply cutting / milling tool for mould & die, aero space and electronic industry. Our main products include solid carbide / HSS end mills, micro electronic drill, IC card cutter, engraving cutter, shell end mills, cutting saw, reamer, thread reamer, leading drill, involute gear cutter for spur wheel, rack and worm milling cutter, thread milling cutter, form cutters for spline shaft/roller chain sprocket, and special tool, with nano grade. Please visit our web www.tool-tool.com for more info.

粘贴碳纤维胶 www.tool-tool.com

度 钢-钢粘接强度(Mpa) 21

抗拉强度(Mpa) 42 钢-钢剪切强度(Mpa) 16

弹性模量(Mpa) 1.5×10³ 钢- 砼粘接强度(Mpa) 3.5

伸长率(%) 1.7

可操作时间(min) 40 接触干时间(20℃ h) 1.5

推荐比例(重量比) 甲:乙=2:1

该产品各项性能指标均符合《混凝土结构加固设计规范》(GB50367-2006)中A级要求

使用说明

1. 基层要求:粘结面必须平整、坚实、无杂质,修补胶已经硬化,且表面干燥,没有露水、冰霜等。

2. 调胶:按照粘结面积计算用量,准确称取甲、乙组份,在一清洁容器中充分搅拌均匀。调好的胶应在适用期内用完。

3. 涂刷底胶:将按比列混合均匀的MT-202碳纤维底胶直接涂刷到混凝土基层上,混凝土的表面应含胶饱满。硬化后进行下一道工序。

4. 粘贴碳纤维:

① 用硬毛刷将调好的MT-202浸渍胶均匀地涂刷到粘贴结面上,胶量必须充足、饱满。涂刷量约300~500g∕㎡。

② 将裁好的碳纤维布贴于混凝土粘贴面,使用硬橡胶棍或塑料刮板往复碾压,促使碳纤维平直、延展,粘合剂充分渗透。碳纤维布长向上接头搭长度应为10-20cm。

③ 在碳纤维表面部分涂刷粘合剂,继续往复刮涂碾压,赶出气泡,并使粘合剂均匀覆盖碳纤维布。涂刷量约200 g∕㎡.

④ 静置1-2小时至指干,重复碾压消除因碳纤维浮起或错开可能引起的气泡、粘结布实等。

⑤ 多层粘粘,可重复以上操作。

⑥ 粘合剂固化后,在被粘贴的碳纤维表面上再刮涂一层胶。

施工要点

施工前用根据环境、温度、工艺等综合情况试验调制最佳配方

用金刚片打磨混凝土表面,直至露出沙石新面层,再将灰尘清洗干净

粘贴碳纤维片材时要使浸渍胶充分浸透片材并且布得损伤碳纤维片材

注意事项

1、 配胶时,应在适当的通风环境下进行。

2、 操作人员使用安全镜,配戴防护面罩。

3、 雨天、霜雾天气不得进行户外施工。

4、 碳纤维是导电纤维,因此,施工操作时必须远离电源,避免发生触电伤亡事故。户外靠近带电体(电线等)施工时,如果风大应停止施工,以免碳纤维布被风刮起接触导电体而发生事故。

5、 碳纤维布纤维方向为单方向,单位重量、厚度、抗拉强度、弹性模量等各项指标必须符合有关要求。

包装贮存

1、 密封包装,存放或使用时必须远离火源,避免日光直射。

2、 包装规格:甲:14公斤∕桶,乙:7公斤∕桶。

典型工程应用

荷华大厦粘碳纤维加固改造

团中央粘碳纤维布加固改造工程

引用出處:

http://www.hudong.com/wiki/%E7%B2%98%E8%B4%B4%E7%A2%B3%E7%BA%A4%E7%BB%B4%E8%83%B6

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Tuesday, February 15, 2011

Tellurium www.tool-tool.com

Tellurium ( /tɪˈlʊəriəm/ or /tɛˈl(j)ʊəriəm/ te-LOOR-ee-əm) is a chemical element that has the symbol Te and atomic number 52. A brittle, mildly toxic, silver-white metalloid which looks similar to tin, tellurium is chemically related to selenium and sulfur. Tellurium was discovered in 1782 by Franz-Joseph Müller von Reichenstein in a mineral containing gold and tellurium. Martin Heinrich Klaproth named the new element in 1798 after the Latin word for "earth", tellus.

Although several gold deposits contain tellurium minerals, the main commercial source for tellurium is as a by-product of copper and lead production. Tellurium is primarily used in alloys, foremost in steel and copper to improve machinability. Applications in solar panels and as a semiconductor material also consume a considerable fraction of tellurium production.

Tellurium has no biological function, although fungi can incorporate it in place of sulfur and selenium into amino acids such as telluro-cysteine and telluro-methionine.[3] In humans, tellurium is partly metabolized into dimethyl telluride, (CH3)2Te, a gas with a garlic-like odor which is exhaled in the breath of victims of tellurium toxicity or exposure.

Contents

[hide]

  • 1 Characteristics
    • 1.1 Physical properties
    • 1.2 Chemical properties
    • 1.3 Isotopes
    • 1.4 Occurrence
  • 2 Production
  • 3 Compounds
  • 4 History
  • 5 Applications
    • 5.1 Metallurgy
    • 5.2 Semiconductor and electronic industry uses
    • 5.3 Other uses
  • 6 Biological role
  • 7 Precautions
  • 8 References
  • 9 External links

[edit] Characteristics

[edit] Physical properties

When crystalline, tellurium is silvery-white and when it is in pure state it has a metallic luster. It is a brittle and easily pulverized metalloid. Amorphous tellurium is found by precipitating it from a solution of tellurous or telluric acid (Te(OH)6).[4] Tellurium is a p-type semiconductor that shows a greater electrical conductivity in certain directions which depends on atomic alignment; the conductivity increases slightly when exposed to light (photoconductivity).[5] When in its molten state, tellurium is corrosive to copper, iron and stainless steel.

[edit] Chemical properties

Tellurium adopts a polymeric structure, consisting of zig-zag chains of Te atoms. This gray material resists oxidation by air and is nonvolatile.

[edit] Isotopes

Main article: Isotopes of tellurium

Naturally occurring tellurium has eight isotopes. Four of those isotopes, 122Te, 124Te, 125Te and 126Te, are stable. The other four, 120Te, 123Te, 128Te and 130Te, have been observed to be radioactive.[6][7] The stable isotopes make up only 33.2 % of the naturally occurring tellurium; this is possible due to the long half-lives of the unstable isotopes. They are in the range from 1013 to 2.2 1024 years. This makes 128Te the isotope with the longest half life among all radioisotopes.[8]

There are 38 known nuclear isomers of tellurium with atomic masses that range from 105 to 142. Tellurium is the lightest element known to undergo alpha decay, with isotopes 106Te to 110Te being able to undergo this mode of decay.[6] The atomic mass of tellurium (127.60 g·mol−1) exceeds that of the following element iodine (126.90 g·mol−1).[9]

[edit] Occurrence

See also Category: Telluride minerals

Tellurium on quartz (Moctezuma, Sonora, Mexico)

With an abundance in the Earth's crust comparable to that of platinum, tellurium is one of the rarest stable solid elements in the Earth's crust. Its abundance is about 1 µg/kg.[10] In comparison, even the rarest of the lanthanides have crustal abundances of 500 µg/kg (see Abundance of the chemical elements).[11]

The extreme rarity of tellurium in the Earth's crust is not a reflection of its cosmic abundance, which is in fact greater than that of rubidium, even though rubidium is ten thousand times more abundant in the Earth's crust. The extraordinarily low abundance of tellurium on Earth is rather thought to be due to conditions in the Earth's formation, when the stable form of certain elements, in the absence of oxygen and water, was controlled by the reductive power of free hydrogen. Under this scenario, certain elements such as tellurium which form volatile hydrides were severely depleted during the formation of the Earth's crust, through evaporation of these hydrides. Tellurium and selenium are the heavy elements most depleted in the Earth's crust by this process.[citation needed]

Tellurium is sometimes found in its native (elemental) form, but is more often found as the tellurides of gold (calaverite, krennerite, petzite, sylvanite and others). Tellurium compounds are the most common chemical compounds of gold found in nature (rare non-tellurides such as gold aurostibite and bismuthide are known). Tellurium is also found combined with elements other than gold, in salts of other metals. In contrast to selenium, tellurium is not able to replace sulfur in its minerals. This is due to the large difference in ion radius of sulfur and tellurium. In consequence, many sulfide minerals contain considerable amounts of selenium, but only traces of tellurium.[12]

In the gold rush of 1893, diggers in Kalgoorlie discarded a pyritic material which got in their way as they searched for pure gold. The Kalgoorlie waste was thus used to fill in potholes or as part of sidewalks. Three years passed before it was realized that this waste was calaverite, a telluride of gold that had not been recognized. This led to a second gold rush in 1896 which included mining the streets.[13]

[edit] Production

The principal source of tellurium is from anode sludges produced during the electrolytic refining of blister copper. It is a component of dusts from blast furnace refining of lead. Treatment of 500 tons of copper ore typically yields one pound (0.45 kg) of tellurium. Tellurium is produced mainly in the United States, Peru, Japan, and Canada.[14] For the year 2006 the British Geological Survey gives the following numbers: United States 50 t, Peru 37 t, Japan 24 t and Canada 11 t.[15]

Tellurium production 2006

The anode sludges contain the selenides and tellurides of the noble metals in compounds with the formula M2Se or M2Te (M = Cu, Ag, Au). At temperatures of 500 °C the anode sludges are roasted with sodium carbonate under air. The metal ions are reduced to the metals, while the telluride is converted to sodium tellurite.[16]

M2Te + O2 + Na2CO3 → Na2TeO3 + 2 M + CO2

Tellurites can be leached from the mixture with water and are normally present as hydrotellurites HTeO3- in solution. Selenites are also formed during this process, but they can be separated by adding sulfuric acid. The hydrotellurites are converted into the insoluble tellurium dioxide while the selenites stay in solution.[16]

HTeO3- + OH- + H2SO4 → TeO2 + 2 SO42− + 2 H2O

The reduction to the metal is done either by electrolysis or by reacting the tellurium dioxide with sulfur dioxide in sulfuric acid.[16]

TeO2 + 2 SO2 + 2H2O → Te + SO42− + 4 H+

Commercial-grade tellurium is usually marketed as minus 200-mesh powder but is also available as slabs, ingots, sticks, or lumps. The year-end price for tellurium in 2000 was US$14 per pound. In recent years, the tellurium price was driven up by increased demand and limited supply, reaching as high as US$100 per pound in 2006.[17][18]

[edit] Compounds

See also Category: Tellurium compounds

Tellurium belongs to the same chemical family as oxygen, sulfur, selenium and polonium: the chalcogen family. Tellurium and selenium compounds are similar. It exhibits the oxidation states −2, +2, +4 and +6, with the +4 state being most common.[4]

Tellurides

Reduction of Te metal produces the Tellurides and polytellurides, Ten2-. The −2 oxidation state is exhibited in binary compounds with many metals, such as zinc telluride, ZnTe, formed by heating tellurium with zinc.[19] Decomposition of ZnTe with hydrochloric acid yields hydrogen telluride (H2Te), a highly unstable analogue of the other chalcogen hydrides, H2O, H2S and H2Se:

ZnTe + 2 HCl → ZnCl2 + H2Te

H2Te is unstable, whereas salts of its conjugate base [TeH]- are stable.

Halides

The +2 oxidation state is exhibited by the dihalides, TeCl2, TeBr2 and TeI2. The dihalides have not been obtained in pure form,[20]:274 although they are known decomposition products of the tetrahalides in organic solvents, and their derived tetrahalotellurates are well-characterized:

Te + X2 + 2 X− → TeX2−

4

where X is Cl, Br, or I. These anions are square planar in geometry.[20]:281 Polynuclear anionic species also exist, such as the dark brown Te2I2−

6,[20]:283 and the black Te4I2−

14.[20]:285

Fluorine forms two halides with tellurium: the mixed-valence Te2F4 and TeF6. In the +6 oxidation state, the –OTeF5 structural group occurs in a number of compounds such as HOTeF5, B(OTeF5)3, Xe(OTeF5)2, Te(OTeF5)4 and Te(OTeF5)6.[21] The square antiprismatic anion TeF2−

8 is also attested.[16] The other halogens do not form halides with tellurium in the +6 oxidation state, but only tetrahalides (TeCl4, TeBr4 and TeI4) in the +4 state, and other lower halides (Te3Cl2, Te2Cl2, Te2Br2, Te2I and two forms of TeI). In the +4 oxidation state, halotellurate anions are known, such as TeCl2−

6 and Te2Cl2−

10. Halotellurium cations are also attested, including TeI+

3, found in TeI3AsF6.[22]

Oxocompounds

A sample of tellurium dioxide powder

Tellurium monoxide was first reported in 1883 as a black amorphous solid formed by the heat decomposition of TeSO3 in vacuum, disproportionating into tellurium dioxide, TeO2 and elemental tellurium upon heating.[23][24] Since then, however, some doubt has been cast on its existence in the solid phase, although it is known as a vapor phase fragment; the black solid may be merely an equimolar mixture of elemental tellurium and tellurium dioxide.[25]

Tellurium dioxide is formed by heating tellurium in air, causing it to burn with a blue flame.[19] Tellurium trioxide, β-TeO3, is obtained by thermal decomposition of Te(OH)6. The other two forms of trioxide reported in the literature, the α- and γ- forms, were found not to be true oxides of tellurium in the +6 oxidation state, but a mixture of Te4+, OH− and O−

2.[26] Tellurium also exhibits mixed-valence oxides, Te2O5 and Te4O9.[26]

The tellurium oxides and hydrated oxides form a series of acids, including tellurous acid (H2TeO3), orthotelluric acid (Te(OH)6) and metatelluric acid ((H2TeO4)n).[25] The two forms of telluric acid form tellurate salts containing the TeO2–

4 and TeO6−

6 anions, respectively. Tellurous acid forms tellurite salts containing the anion TeO2−

3. Other tellurium cations include TeF2+

8, which consists of two fused tellurium rings and the polymeric TeF2+

7.

Zintl cations

When tellurium is treated with concentrated sulfuric acid, it forms red solutions containing the Zintl ion, Te2+

4.[27] The oxidation of tellurium by AsF5 in liquid SO2 also produces this square planar cation, as well as with the trigonal prismatic, yellow-orange Te4+

6:[16]

4 Te + 3 AsF5 → Te2+

4(AsF−

6)2 + AsF3

6 Te + 6 AsF5 → Te4+

6(AsF−

6)4 + 2 AsF3

Other tellurium Zintl cations include the polymeric Te2+

7 and the blue-black Te2+

8, which consists of two fused 5-membered tellurium rings. The latter cation is formed by the reaction of tellurium with tungsten hexachloride:[16]

8 Te + 2 WCl6 → Te2+

8(WCl−

6)2

Interchalcogen cations also exist, such as Te2Se2+

6 (distorted cubic geometry) and Te2Se2+

8. These are formed by oxidizing mixtures of tellurium and selenium with AsF5 or SbF5.[16]

Organotellurium compounds

Main article: Organotellurium chemistry

Tellurium does not readily form analogues of alcohols and thiols, with the functional group –TeH and are called tellurols. The –TeH functional group is also attributed to using the prefix tellanyl-.[28] Like H2Te, these species are unstable with respect to loss of H2. Telluraethers (R-Te-R) are more stable as are telluroxides.

[edit] History

Klaproth named the new element and credited von Reichenstein with its discovery

Tellurium (Latin tellus meaning "earth") was discovered in the 18th century in a gold ore from the mines in Zlatna, near what is now Sibiu, Transylvania. This ore was known as "Faczebajer weißes blättriges Golderz" (white leafy gold ore from Faczebaja) or antimonalischer Goldkies (antimonic gold pyrite), and, according to Anton von Rupprecht, was Spießglaskönig (argent molybdique), containing native antimony.[29][30] In 1782 Franz-Joseph Müller von Reichenstein, who was then serving as the Austrian chief inspector of mines in Transylvania, concluded that the ore did not contain antimony, but that it was bismuth sulfide.[31] The following year, he reported that this was erroneous and that the ore contained mostly gold and an unknown metal very similar to antimony. After a thorough investigation which lasted for three years and consisted of more than fifty tests, Müller determined the specific gravity of the mineral and noted the radish-like odor of the white smoke which passed off when the new metal was heated, the red color which the metal imparts to sulfuric acid, and the black precipitate which this solution gives when diluted with water. Nevertheless, he was not able to identify this metal and gave it the names aurum paradoxium and metallum problematicum, as it did not show the properties predicted for the expected antimony.[32][33][34]

In 1789, another Hungarian scientist, Pál Kitaibel, also discovered the element independently in an ore from Deutsch-Pilsen which had been regarded as argentiferous molybdenite, but later he gave the credit to Müller. In 1798, it was named by Martin Heinrich Klaproth who earlier isolated it from the mineral calaverite.[33][34][35]

Tellurium was used as a chemical bonder in the making of the outer shell of the first atomic bomb. The 1960s brought growth in thermoelectric applications for tellurium, as well as its use in free-machining steel, which became the dominant use.[citation needed]

[edit] Applications

[edit] Metallurgy

The largest consumer of tellurium is metallurgy, where it is used in iron, copper and lead alloys. When added to stainless steel and copper it makes these metals more machinable. It is alloyed into cast iron for promoting chill for spectroscopic purposes, as the presence of electrically conductive free graphite tends to deleteriously affect spark emission testing results. In lead it improves strength and durability and decreases the corrosive action of sulfuric acid.[36]

[edit] Semiconductor and electronic industry uses

A CdTe photovoltaic array

Tellurium is used in cadmium telluride (CdTe) solar panels. National Renewable Energy Laboratory lab tests using this material achieved some of the highest efficiencies for solar cell electric power generation. Massive commercial production of CdTe solar panels by First Solar in recent years has significantly increased tellurium demand.[37][38][39] If some of the cadmium in CdTe is replaced by zinc then (Cd,Zn)Te is formed which is used in solid-state x-ray detectors.[40]

Alloyed with both cadmium and mercury, to form mercury cadmium telluride, an infrared sensitive semiconductor material is formed.[41] Organotellurium compounds such as dimethyl telluride, diethyl telluride, diisopropyl telluride, diallyl telluride and methyl allyl telluride are used as precursors for Metalorganic vapor phase epitaxy growth of II-VI compound semiconductors.[42] Diisopropyl telluride (DIPTe) is employed as the preferred precursor for achieving the low-temperature growth of CdHgTe by MOVPE.[43] For these processes highest purity metalorganics of both selenium and tellurium are used. The compounds for semiconductor industry and are prepared by adduct purification.[44][45]

Tellurium as a tellurium suboxide is used in the media layer of several types of rewritable optical discs, including ReWritable Compact Discs (CD-RW), ReWritable Digital Video Discs (DVD-RW) and ReWritable Blu-ray Discs.[46][47]

Tellurium is used in the new phase change memory chips.[48] developed by Intel.[49] Bismuth telluride (Bi2Te3) and lead telluride are working elements of thermoelectric devices. Lead telluride is used in far-infrared detectors.

[edit] Other uses

  • Used to color ceramics.[50]
  • The strong increase in optical refraction upon the addition of selenides and tellurides into glass is used in the production of glass fibers for telecommunications. These chalcogenide glasses are widely used.[51][52]
  • Mixtures of Selenium and tellurium are used with barium peroxide as oxidizer in the delay powder of electric blasting caps.[53]
  • Organic tellurides have been employed as initiators for living radical polymerization and electron-rich mono- and di-tellurides possess antioxidant activity.
  • Rubber can be vulcanized with tellurium instead of sulfur or selenium. The rubber produced in this way shows improved heat resistance.[54]
  • Tellurite agar is used to identify member of the corynebacterium genus, most typically Corynebacterium diphtheriae, the pathogen responsible for diphtheria.[55]

[edit] Biological role

Tellurium has no known biological function, although fungi can incorporate it in place of sulfur and selenium into amino acids such as telluro-cysteine and telluro-methionine.[citation needed] Organisms have shown a highly variable tolerance to tellurium compounds. Most organisms metabolize tellurium partly to form dimethyl telluride although dimethyl ditelluride is also formed by some species. Dimethyl telluride has been observed in hot springs at very low concentrations.[56][57][58]

[edit] Precautions

Tellurium and tellurium compounds are considered to be mildly toxic and need to be handled with care, although acute poisoning is rare.[59] Tellurium is not reported to be carcinogenic.[59]

Humans exposed to as little as 0.01 mg/m3 or less in air develop "tellurium breath", which has a garlic-like odor.[50] The garlic odor that is associated with human intake of tellurium compounds is caused from the tellurium being metabolized by the body. When the body metabolizes tellurium in any oxidation state, the tellurium gets converted into dimethyl telluride, (CH3)2Te, which is volatile and is the cause of the garlic-like smell. Even though the metabolic pathways of tellurium are not known, it is generally assumed that they resemble those of the more extensively studied selenium, because the final methylated metabolic products of the two elements are similar.[60][61][62]

引用出處:

http://en.wikipedia.org/wiki/Tellurium

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碲Te www.tool-tool.com

碲,原子序数 52,原子量127.60,元素名来源于拉丁文,原意是“地球”。 碲1782年赖兴施泰因在含金的矿石中发现碲。碲在地壳中的含量为千万分之二,主要矿物有针碲金矿、叶碲矿、碲银矿等。碲为银白色有金属光泽的固体,熔点 452°C,沸点1390°C,密度6.25克/厘米3;有两种同素异形体:无定形碲和晶体碲。

纠错 编辑摘要

目录

  • 1 概述
  • 2 性质
  • 3 元素描述
  • 4 发现
  • 5 资源
  • 1 概述
  • 2 性质
  • 3 元素描述
  • 4 发现
  • 5 资源
  • 6 制取
  • 7 用途

碲 - 概述

碲 是一种化学元素,它的化学符号是Te,它的原子序数是52,碲(音帝):TELLURIUM,源自tellus意为“土地”。1782年发现。除了兼具金 属和非金属的 特性外,碲还有几点不平常的地方:它在周期表的位置形成“颠倒是非”的现象-碲比碘的原子序数低,具有较大的原子量。如果人吸入它的蒸气,从嘴里呼出的气 会有一股蒜味。碲是稀散金属之一,有两种同素异形体,一种为结晶形,具有银白色金属光泽;另一种为无定形,为黑色粉末。结晶形碲的熔点为449.8℃,沸 点990℃,密度为6.24克/厘米3。碲在常温下性脆,加热后可挤压加工,碲晶体的许多物理性质,如强度、热膨胀、光吸收、电导率、电磁性等都具有各向 异性。碲及其合金和金属间化合物都具有半导体和温差性能,碲单晶的禁带宽度为0.32eV,电子迁移率为9x10-2m2/(V"s),空穴迁移率为 5.9x10-2m2/(V"s),常温电阻率4.36x105SZ'm,碲的薄膜呈红棕色到紫色,能透过红外线而不透过可见光,碲的光电效应微弱,仅为 灰硒的0.01%0碲的外电子层构型为[Kr]4d105s25p4,有-2.0,+2,+4,+6多种价态,其中+4价化合物最稳定。碲的化学性质与硒 相似,碲在常温空气中较稳定,在空气或氧中燃烧生成二氧化碲,发出蓝色火焰;易和卤素剧烈反应生成碲的卤化物,在高温下不与氢作用。碲不与水和无氧化性酸 作用,不溶于盐酸,可溶于热浓硫酸、硝酸和存在氧化剂的苛性碱中。碲不与氢、碳、氮等作用,碲与硫在熔融状态下可以互溶,碲几乎能与所有的金属反应生成碲 化物,碱金属碲化物可溶于水,重金属碲化物不溶于水。二氧化碲具有两性性质。碲易生成亚碲酸(H2TeO3),碲酸(H2TeO4)、正碲酸 (H2TeO6)和相应的碲酸盐。碲-128及碲-130是最常见的碲同位素,但它们都有微弱的放射性。主要用作合金及半导体。碲化铋用作热电装置中。碲 是制造碲化镉太阳能薄膜电池的主要原料。

碲 - 性质

元素名称:碲

元素符号:Te

元素英文名称:TELLURIUM

元素类型:非金属元素

原子体积:(立方厘米/摩尔):20.5

碲锭

元素在海水中的含量:(ppm)

太平洋表面 0.00000019

地壳中含量:(ppm):0.005

相对原子质量:127.6

原子序数:52

质子数:52

摩尔质量:128

所属周期:5

所属族数:VIA

电子层排布: 2-8-18-18-6

晶体结构:晶胞为六方晶胞。

氧化态:Main Te+4

Other Te-2, Te-1, Te0, Te+2, Te+5, Te+6

化学键能: (kJ /mol)

Te-H 240

Te-O 268

Te-F 335

Te-Cl 251

Te-Te 235

晶胞参数:

a = 445.72 pm

b = 445.72 pm

c = 592.9 pm

α = 90°

β = 90°

γ = 120°

莫氏硬度:2.25

声音在其中的传播速率:(m/S):2610

碲铜棒

电离能 (kJ /mol)

M - M+ 869.2

M+ - M2+ 1795

M2+ - M3+ 2698

M3+ - M4+ 3610

M4+ - M5+ 5668

M5+ - M6+ 6822

M6+ - M7+ 13200

M7+ - M8+ 15800

M8+ - M9+ 18500

M9+ - M10+ 21200

碲 - 元素描述

有 结晶形和无定形两种同素异形体。电离能9.009电子伏特。结晶碲具有银白色的金属外 观,密度6.25克/厘米3,熔点452℃,沸点1390℃,硬度是2.5(莫氏硬度)。不溶于同它不发生反应的所有溶剂,在室温时它的分子量至今还不清 楚。无定形碲(褐色),密度6.00克/厘米3,熔点449.5±0.3℃,沸点989.8±3.8℃。碲在空气中燃烧带有蓝色火焰,生成二氧化碲;可与 卤素反应,但不与硫、硒反应。溶于硫酸、硝酸、氢氧化钾和氰化钾溶液。易传热和导电。

碲 - 发现

碲(te)

1782年德要矿物学家米勒•冯•赖兴施泰因在研究德国金矿石时,得到一种未知物质。1798年德国人克拉普罗特证实了此发现,并测定了这一物质的特性,按拉丁文Tellus(地球)命名为tellurium。

碲 在自然界有一种同金在一起的合金。1782年奥地利首 都维也纳一家矿场监督牟勒从这种矿石中提取出碲,最初误认为是锑,后来发现它的性质与锑不同,因而确定是一种新金属元素。为了获得其他人的证实,牟勒曾将 少许样品寄交瑞典化学家柏格曼,请他鉴定。由于样品数量太少,柏格曼也只能证明它不是锑而已。牟勒的发现被忽略了16年后,1798年1月25日克拉普罗 特在柏林科学院宣读一篇关于特兰西瓦尼亚的金矿论文时,才重新把这个被人遗忘的元素提出来。他将这种矿石溶解在王水中,用过量碱使溶液部分沉淀,除去金和 铁等,在沉淀中发现这一新元素,命名为tellurium(碲),元素符号定为Te。这一词来自拉丁文tellus(地球)。克拉普罗特一再申明,这一新 元素是1782年牟勒发现的。

碲 - 资源

碲的地壳丰度为 lx10-7%,查明储量16万吨,主要分布在美国、加拿大、中国、智利等国家。尚未发现有碲的独立工业矿物。碲矿资源分布稀散,多伴生在其它矿物中或以 杂质形式存在于其它矿中。中国四川石棉县大水沟碲矿是至今发现的唯一碲独立矿床[1]。碲主要与黄铁矿、黄铜矿、闪锌矿等共生,含量仅 0.001%-0.1%;主要碲矿物有碲铅矿、碲铋矿、辉碲铋矿以及碲金矿、碲铜矿等。以上矿物很少见均无工业价值。 1993年,中国碲的工业储量1.3446万吨,当年产量为3.990吨。美国、加拿大、日本、秘鲁和斐济等国1979年产金属碲约290吨,大约消费 280吨。前苏联也是碲的重要生产国。中国辽宁、湖南、广东、台湾等地有工业规模的碲生产。1979年工业纯碲的价格为44.1-50.7美元/公斤。

碲 - 制取

硒和碲与硫的化学性质相近,它们均属典型的亲铜元素,因此硒和碲主要伴生在黄铜矿、斑铜矿、黄铁矿。硒和碲的生产主要取决于铜的生产状况,铜阳极泥是生产硒和碲的主要原料(一般含硒3%-28%,碲1.5%-10%)。

硒和碲的另一重要来源是铅或镍的阳极泥和有色金属冶炼的烟尘,硫酸生产中产出含硒、碲的酸泥分别波动在3%-52%和0.2%-14%。从这些原料中提取硒和碲主要包括富集和硒碲的制取和提纯两大环节,回收方法因原料不同而异,一般分为Seq和Teq制备。

铜 电解精炼所得的阳极泥是碲的主要来源。处理阳极泥的主要方法是硫酸化焙烧法。其他方法如苏打烧结法等应用较少。据阳极泥中碲含量的高低,采用不同的处理方 法:对含碲高的阳极泥,干燥后在250℃下进行硫酸化焙烧,然后在700℃使二氧化硒挥发,碲则留在焙烧渣中。对含碲低的铜阳极泥和铅电解阳极泥混合处理 时,可进行还原熔炼。对于高纯碲的制取主要采用电解法。

碲 - 用途

碲 主要用于冶金、电子工业、化学工业、玻璃等方面,约55%碲在冶金中用作合金添加剂增强钢、铜及铜合金、铅等的机械性能;化学工业中用碲作橡胶硫化过程 的加速剂、有机反应催化剂;玻璃陶瓷工业用碲作脱色剂、着色剂和制造特种光学玻璃;制药工业用谛作消毒剂、杀虫剂、灭菌剂和抗氧化剂。碲也用于复印机。碲 金属化合物是制造太阳能电池、辐射探测器和红外探测器的材料,用于夜视仪、地面资源勘探。碲热电转换器用于宇航动力系统的热发电机、微波装置、水底导弹特 殊冷却装置等方面。

在冶金工业中应用

碲在冶金工业中的用量约占碲的总消费量的80%以上。钢和铜合金加入少量碲,可增加钢 得延展性,能改善低碳钢、不锈钢和铜的 切削加工性能并增加硬度;在白口铸铁中碲被用作碳化物稳定剂,使表面坚固耐磨;含少量碲的铅,可提高材料的耐蚀性、耐磨性和强度,用作海底电缆的护套;铅 中加入碲能增加铅的硬度,用来制作电池极板和印刷铅字。碲可用作石油裂解催化剂的添加剂以及制取乙二醇的催化剂。氧化碲用作蓝、棕、红色玻璃的着色剂高纯 碲可作温差电材料的合金组分。高纯碲可用作温差电材料的合金组分,其中碲化铋为良好的制冷材料。碲和若干碲化物As32Te48Si20是制作电子计算机 存贮器的半导体材料。超纯碲单晶是新型的红外材料。高纯碲用量虽少,作用颇大。

引用出處:

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Monday, February 14, 2011

Selenium www.tool-tool.com

Selenium ( /sɪˈliːniəm/ si-LEE-nee-əm) is a chemical element with the atomic number 34, represented by the chemical symbol Se, an atomic mass of 78.96. It is a nonmetal, chemically related to sulfur and tellurium, and rarely occurs in its elemental state in nature.

Isolated selenium occurs in several different forms, the most stable of which is a dense purplish-gray semi-metal (semiconductor) form that is, in terms of structure, a trigonal polymer chain. It conducts electricity better in the light than in the dark, and is used in photocells (see section Allotropes below). Selenium also exists in many non-conductive forms: a black glass-like allotrope, as well as several red crystalline forms built of eight-membered ring molecules, like its lighter cousin sulfur.

Selenium is found in economic quantities in sulfide ores such as pyrite, partially replacing the sulfur in the ore matrix. Minerals that are selenide or selenate compounds are also known, but are rare. The chief commercial uses for selenium today are in glassmaking and in chemicals and pigments. Uses in electronics, once important, have been supplanted by silicon semiconductor devices.

Selenium salts are toxic in large amounts, but trace amounts of the element are necessary for cellular function in most, if not all, animals, forming the active center of the enzymes glutathione peroxidase and thioredoxin reductase (which indirectly reduce certain oxidized molecules in animals and some plants) and three known deiodinase enzymes (which convert one thyroid hormone to another). Selenium requirements in plants differ by species, with some plants, it seems, requiring none.[3]

Contents

[hide]

  • 1 History and global demand
  • 2 Occurrence
  • 3 Production and allotropic forms
  • 4 Isotopes
  • 5 Health effects and nutrition
    • 5.1 Indicator plants
    • 5.2 Toxicity
    • 5.3 Deficiency
    • 5.4 Controversial health effects
  • 6 Non-biologic applications
  • 7 Biologic applications
    • 7.1 Detection in biological fluids
  • 8 Evolution in biology
  • 9 Chemistry
    • 9.1 Chalcogen compounds
    • 9.2 Halogen compounds
    • 9.3 Selenides
    • 9.4 Other compounds
  • 10 See also
  • 11 References
  • 12 External links

[edit] History and global demand

Selenium (Greek σελήνη selene meaning "Moon") was discovered in 1817 by Jöns Jakob Berzelius,[4] who found the element associated with tellurium (named for the Earth). It was discovered as a byproduct of sulfuric acid production.

It came to medical notice later because of its toxicity to humans working in industry. It was also recognized as an important veterinary toxin, seen in animals eating high-selenium plants. In 1954, the first hints of specific biological functions of selenium were discovered in microorganisms. Its essentiality for mammalian life was discovered in 1957. In the 1970s, it was shown to be present in two independent sets of enzymes. This was followed by the discovery of selenocysteine in proteins. During the 1980s, it was shown that selenocysteine is encoded by the codon TGA. The recoding mechanism was worked out first in bacteria and then in mammals (see SECIS element).

In industry, growth in selenium consumption has been driven by steady development of new uses, including applications in rubber compounding, steel alloying, and selenium rectifiers. Selenium is also an essential material in the drums of laser printers and copiers. By 1970, selenium in rectifiers had largely been replaced by silicon, but its use as a photoconductor in plain-paper copiers had become its leading application. During the 1980s, the photoconductor application declined (although it was still a large end-use) as more and more copiers using organic photoconductors were produced. At the current time, the largest use of selenium worldwide is in glass manufacturing, followed by uses in chemicals and pigments. Electronics use, despite a number of continued applications, continues to decline.[5]

In the late 1990s, the use of selenium (usually with bismuth) as an additive to plumbing brasses to meet no-lead environmental standards became important. At present, total world selenium production continues to increase modestly.

[edit] Occurrence

Native selenium

See also: Category:Selenide minerals

Selenium occurs naturally in a number of inorganic forms, including selenide, selenate, and selenite. In soils, selenium most often occurs in soluble forms such as selenate (analogous to sulfate), which are leached into rivers very easily by runoff.

Selenium has a biological role, and it is found in organic compounds such as dimethyl selenide, selenomethionine, selenocysteine, and methylselenocysteine. In these compounds, selenium plays a role analogous to that of sulfur.

Selenium is most commonly produced from selenide in many sulfide ores, such as those of copper, silver, or lead. It is obtained as a byproduct of the processing of these ores, from the anode mud of copper refineries and the mud from the lead chambers of sulfuric acid plants. These muds can be processed by a number of means to obtain free selenium.

Natural sources of selenium include certain selenium-rich soils, and selenium that has been bioconcentrated by certain plants. Anthropogenic sources of selenium include coal burning and the mining and smelting of sulfide ores.[6]

[edit] Production and allotropic forms

Structure of trigonal selenium

Native selenium is a rare mineral, which does not usually form good crystals, but, when it does, they are steep rhombohedrons or tiny acicular (hair-like) crystals.[7] Isolation of selenium is often complicated by the presence of other compounds and elements.

Most elemental selenium comes as a byproduct of refining copper or producing sulfuric acid.[8][9]

Industrial production of selenium often involves the extraction of selenium dioxide from residues obtained during the purification of copper. Common production begins by oxidation with sodium carbonate to produce selenium dioxide. The selenium dioxide is then mixed with water and the solution is acidified to form selenous acid (oxidation step). Selenous acid is bubbled with sulfur dioxide (reduction step) to give elemental selenium.

Elemental selenium produced in chemical reactions invariably appears as the amorphous red form: an insoluble, brick-red powder. When this form is rapidly melted, it forms the black, vitreous form, which is usually sold industrially as beads. The most thermodynamically stable and densest form of selenium is the electrically conductive gray (trigonal) form, which is composed of long helical chains of selenium atoms (see figure).[10] The conductivity of this form is notably light-sensitive. Selenium also exists in three different deep-red crystalline monoclinic forms, which are composed of Se8 molecules, similar to many allotropes of sulfur.[11][12] However, selenium does not exhibit the unusual changes in viscosity that sulfur undergoes when gradually heated.[12][13]

[edit] Isotopes

Main article: Isotopes of selenium

Selenium has six naturally occurring isotopes, five of which are stable: 74Se, 76Se, 77Se, 78Se, and 80Se. The last three also occur as fission products, along with 79Se, which has a half-life of 327,000 years.[14][15] The final naturally occurring isotope, 82Se, has a very long half-life (~1020 yr, decaying via double beta decay to 82Kr), which, for practical purposes, can be considered to be stable. Twenty-three other unstable isotopes have been characterized.

See also Selenium-79 for more information on recent changes in the measured half-life of this long-lived fission product, important for the dose calculations performed in the frame of the geological disposal of long-lived radioactive waste.

[edit] Health effects and nutrition

NFPA 704

0

2

0

Fire diamond for elemental selenium

Although it is toxic in large doses, selenium is an essential micronutrient for animals. In plants, it occurs as a bystander mineral, sometimes in toxic proportions in forage (some plants may accumulate selenium as a defense against being eaten by animals, but other plants such as locoweed require selenium, and their growth indicates the presence of selenium in soil).[3] See more on plant nutrition below.

Selenium is a component of the unusual amino acids selenocysteine and selenomethionine. In humans, selenium is a trace element nutrient that functions as cofactor for reduction of antioxidant enzymes, such as glutathione peroxidases[16] and certain forms of thioredoxin reductase found in animals and some plants (this enzyme occurs in all living organisms, but not all forms of it in plants require selenium).

The glutathione peroxidase family of enzymes (GSH-Px) catalyze certain reactions that remove reactive oxygen species such as hydrogen peroxide and organic hydroperoxides:

2 GSH + H2O2----GSH-Px → GSSG + 2 H2O

Selenium also plays a role in the functioning of the thyroid gland and in every cell that uses thyroid hormone, by participating as a cofactor for the three known thyroid hormone deiodinases, which activate and then deactivate various thyroid hormones and their metabolites.[17] It may inhibit Hashimotos's disease, in which the body's own thyroid cells are attacked as alien. A reduction of 21% on TPO antibodies was reported with the dietary intake of 0.2 mg of selenium.[18]

Dietary selenium comes from nuts, cereals, meat, mushrooms, fish, and eggs. Brazil nuts are the richest ordinary dietary source (though this is soil-dependent, since the Brazil nut does not require high levels of the element for its own needs). In descending order of concentration, high levels are also found in kidney, tuna, crab, and lobster.[19][20]

The human body's content of selenium is believed to be in the 13-20 milligram range.[21]

[edit] Indicator plants

Certain species of plants are considered indicators of high selenium content of the soil, since they require high levels of selenium to thrive. The main selenium indicator plants are Astragalus species (including some locoweeds), prince's plume (Stanleya sp.), woody asters (Xylorhiza sp.), and false goldenweed (Oonopsis sp.)[22]

[edit] Toxicity

Although selenium is an essential trace element, it is toxic if taken in excess. Exceeding the Tolerable Upper Intake Level of 400 micrograms per day can lead to selenosis.[23] This 400 microgram (µg) Tolerable Upper Intake Level is based primarily on a 1986 study of five Chinese patients who exhibited overt signs of selenosis and a follow up study on the same five people in 1992.[24] The 1992 study actually found the maximum safe dietary Se intake to be approximately 800 micrograms per day (15 micrograms per kilogram body weight), but suggested 400 micrograms per day to not only avoid toxicity, but also to avoid creating an imbalance of nutrients in the diet and to account for data from other countries.[25] The Chinese people who suffered from selenium toxicity ingested selenium by eating corn grown in extremely selenium-rich stony coal (carbonaceous shale). This coal was shown to have selenium content as high as 9.1%, the highest concentration in coal ever recorded in literature.[26] A dose of selenium as small as 5 milligram (5000 µg) per day can be lethal for many humans.[27]

Reference ranges for blood tests, showing selenium in purple in center

Symptoms of selenosis include a garlic odor on the breath, gastrointestinal disorders, hair loss, sloughing of nails, fatigue, irritability, and neurological damage. Extreme cases of selenosis can result in cirrhosis of the liver, pulmonary edema, and death.[28] Elemental selenium and most metallic selenides have relatively low toxicities because of their low bioavailability. By contrast, selenates and selenites are very toxic, having an oxidant mode of action similar to that of arsenic trioxide. The chronic toxic dose of selenite for humans is about 2400 to 3000 micrograms of selenium per day for a long time.[29] Hydrogen selenide is an extremely toxic, corrosive gas.[30] Selenium also occurs in organic compounds, such as dimethyl selenide, selenomethionine, selenocysteine and methylselenocysteine, all of which have high bioavailability and are toxic in large doses. Nano-size selenium has equal efficacy, but much lower toxicity.[31]

On 19 April 2009, twenty-one polo ponies began to die shortly before a match in the United States Polo Open. Three days later, a pharmacy released a statement explaining that the horses had received an incorrect dose of one of the ingredients used in a vitamin/mineral supplement compound, with which the horses had been injected. Such nutrient injections are common to promote recovery after a match, but this mixture had been compounded by a compounding pharmacy not familiar with it. Analysis of blood levels of inorganic compounds in the supplement indicated the selenium concentrations were ten to fifteen times higher than normal in the horses' blood samples, and 15 to 20 times higher than normal in their liver samples. It was later confirmed that selenium was the ingredient in question.[32] Selenium is active in only tiny amounts, and has a history of causing accidental poisonings in supplements when the dose that is supposed to be in micrograms is given by mistake in milligrams (1000 times as much).

Selenium poisoning of water systems may result whenever new agricultural runoff courses through normally dry, undeveloped lands. This process leaches natural soluble selenium compounds (such as selenates) into the water, which may then be concentrated in new "wetlands" as the water evaporates. High selenium levels produced in this fashion have been found to have caused certain congenital disorders in wetland birds.[33]

[edit] Deficiency

Main article: selenium deficiency

Selenium deficiency is rare in healthy, well-nourished individuals. It can occur in patients with severely compromised intestinal function, those undergoing total parenteral nutrition, and[34] on advanced-aged people (over 90). Also, people dependent on food grown from selenium-deficient soil are at risk. Although New Zealand has low levels of selenium in its soil, adverse health effects have not been detected.[35]

Selenium deficiency may only occur when a low selenium status is linked with an additional stress, such as chemical exposure or increased oxidant stress due to vitamin E deficiency.[36]

There are interactions between selenium and other nutrients, such as iodine and vitamin E. The interaction is observed in the etiology of many deficiency diseases in animals, and pure selenium deficiency is, in fact, rare. The effect of selenium deficiency on health remains uncertain, in particular, in relation to Kashin-Beck disease.[37]

[edit] Controversial health effects

Cancer

Several studies have suggested a possible link between cancer and selenium deficiency.[38][39][40][41] One study, known as the NPC, was conducted to test the effect of selenium supplementation on the recurrence of skin cancers on selenium-deficient men. It did not demonstrate a reduced rate of recurrence of skin cancers, but did show a reduced occurrence of total cancers, although without a statistically significant change in overall mortality.[42] The preventative effect observed in the NPC was greatest in those with the lowest baseline selenium levels.[43] In 2009, the 5.5 year SELECT study reported selenium and vitamin E supplementation, both alone and together, did not significantly reduce the incidence of prostate cancer in 35,000 men who "generally were replete in selenium at baseline".[43] The SELECT trial reported vitamin E did not reduce prostate cancer as it had in the alpha-tocopherol, beta carotene (ATBC) study, but the ATBC had a large percentage of smokers, while the SELECT trial did not.[43] There was a slight trend toward more prostate cancer in the SELECT trial, but in the vitamin E only arm of the trial, where no selenium was given.

Dietary selenium prevents chemically-induced carcinogenesis in many rodent studies.[44] It has been proposed that selenium may help prevent cancer by acting as an antioxidant or by enhancing immune activity. Not all studies agree on the cancer-fighting effects of selenium. One study of naturally occurring levels of selenium in over 60,000 participants did not show a significant correlation between those levels and cancer.[45] The SU.VI.MAX study[46] concluded low-dose supplementation (with 120 mg of ascorbic acid, 30 mg of vitamin E, 6 mg of beta carotene, 100 µg of selenium, and 20 mg of zinc) resulted in a 30% reduction in the incidence of cancer and a 37% reduction in all-cause mortality in males, but did not get a significant result for females.[47] However, there is evidence selenium can help chemotherapy treatment by enhancing the efficacy of the treatment, reducing the toxicity of chemotherapeutic drugs, and preventing the body's resistance to the drugs.[48] Studies of cancer cells in vitro showed that chemotherapeutic drugs, such as taxol and Adriamycin, were more toxic to strains of cancer cells when selenium was added.[49][50]

In March 2009, vitamin E (400 IU) and selenium (200 micrograms) supplements were reported to affect gene expression and can act as a tumor suppressor.[51] Eric Klein, MD from the Glickman Urological and Kidney Institute in Ohio said the new study “lend[s] credence to the previous evidence that selenium and vitamin E might be active as cancer preventatives”.[52] In an attempt to rationalize the differences between epidemiological and in vitro studies and randomized trials like SELECT, Klein said randomized controlled trials “do not always validate what we believe biology indicates and that our model systems are imperfect measures of clinical outcomes in the real world”.[52]

HIV/AIDS

Some research has indicated a geographical link between regions of selenium-deficient soils and peak incidences of HIV/AIDS infection. For example, much of sub-Saharan Africa is low in selenium. However, Senegal is not, and also has a significantly lower level of AIDS infection than the rest of the continent. AIDS appears to involve a slow and progressive decline in levels of selenium in the body. Whether this decline in selenium levels is a direct result of the replication of HIV[53] or related more generally to the overall malabsorption of nutrients by AIDS patients remains debated.

Low selenium levels in AIDS patients have been directly correlated with decreased immune cell count and increased disease progression and risk of death.[54] Selenium normally acts as an antioxidant, so low levels of it may increase oxidative stress on the immune system, leading to its more rapid decline. Others have argued T-cell-associated genes encode selenoproteins similar to human glutathione peroxidase. Depleted selenium levels in turn lead to a decline in CD4 helper T-cells, further weakening the immune system.[55]

Regardless of the cause of depleted selenium levels in AIDS patients, studies have shown selenium deficiency does strongly correlate with the progression of the disease and the risk of death.[56][57][58]

Tuberculosis

Some research has suggested selenium supplementation, along with other nutrients, can help prevent the recurrence of tuberculosis.[59]

Diabetes

A well-controlled study showed selenium intake is positively correlated with the risk of developing type 2 diabetes. Because high serum selenium levels are positively associated with the prevalence of diabetes, and because selenium deficiency is rare, supplementation is not recommended in well-nourished populations, such as the U.S.[60] More recent studies, however, have indicated selenium may help inhibit the development of type 2 diabetes in men, though the mechanism for the possible preventative effect is not known.[61]

Mercury

Experimental findings have demonstrated a protective effect of selenium on methylmercury toxicity, but epidemiological studies have been inconclusive in linking selenium to protection against the adverse effects of methylmercury.[62]

[edit] Non-biologic applications

Chemistry

Selenium is a catalyst in many chemical reactions and is widely used in various industrial and laboratory syntheses, especially organoselenium chemistry. It is also widely used in structure determination of proteins and nucleic acids by X-ray crystallography (incorporation of one or more Se atoms helps with MAD and SAD phasing.)

Manufacturing and materials use

The largest use of selenium worldwide is in glass and ceramic manufacturing, where it is used to give a red color to glasses, enamels and glazes as well as to remove color from glass by counteracting the green tint imparted by ferrous impurities.

Selenium is used with bismuth in brasses to replace more toxic lead. It is also used to improve abrasion resistance in vulcanized rubbers.

Electronics

Because of its photovoltaic and photoconductive properties, selenium is used in photocopying, photocells, light meters and solar cells. It was once widely used in rectifiers. These uses have mostly been replaced by silicon-based devices, or are in the process of being replaced. The most notable exception is in power DC surge protection, where the superior energy capabilities of selenium suppressors make them more desirable than metal oxide varistors.

Sheets of amorphous selenium convert x-ray images to patterns of charge in xeroradiography and in solid-state, flat-panel x-ray cameras.

Photography

Selenium is used in the toning of photographic prints, and it is sold as a toner by numerous photographic manufacturers including Kodak and Fotospeed. Its use intensifies and extends the tonal range of black and white photographic images as well as improving the permanence of prints.

Early photographic light meters used selenium but this application is now obsolete.

[edit] Biologic applications

Medical use

The substance loosely called selenium sulfide (approximate formula SeS2) is the active ingredient in some anti-dandruff shampoos.[63] The selenium compound kills the scalp fungus Malassezia, which causes shedding of dry skin fragments. The ingredient is also used in body lotions to treat Tinea versicolor due to infection by a different species of Malassezia fungus.[64]

Nutrition

Selenium is used widely in vitamin preparations and other dietary supplements, in small doses (typically 50 to 200 micrograms per day for adult humans). Some livestock feeds are fortified with selenium as well.

[edit] Detection in biological fluids

Selenium may be measured in blood, plasma, serum or urine to monitor excessive environmental or occupational exposure, confirm a diagnosis of poisoning in hospitalized victims or to assist in a forensic investigation in a case of fatal overdosage. Some analytical techniques are capable of distinguishing organic from inorganic forms of the element. Both organic and inorganic forms of selenium are largely converted to monosaccharide conjugates (selenosugars) in the body prior to being eliminated in the urine. Cancer patients receiving daily oral doses of selenothionine may achieve very high plasma and urine selenium concentrations.[65]

[edit] Evolution in biology

Main article: Evolution of dietary antioxidants

Over three billion years ago, blue-green algae were the most primitive oxygenic photosynthetic organisms and are ancestors of multicellular eukaryotic algae.[66] Algae that contain the highest amount of antioxidant selenium, iodide, and peroxidase enzymes were the first living cells to produce poisonous oxygen in the atmosphere. It has been suggested that algal cells required a protective antioxidant action, in which selenium and iodides, through peroxidase enzymes, have had this specific role.[66][67] Selenium, which acts synergistically with iodine,[68] is a primitive mineral antioxidant, greatly present in the sea and prokaryotic cells, where it is an essential component of the family of glutathione peroxidase (GSH-Px) antioxidant enzymes; seaweeds accumulate high quantity of selenium and iodine.[66] In 2008, a study showed that iodide also scavenges reactive oxygen species (ROS) in algae, and that its biological role is that of an inorganic antioxidant, the first to be described in a living system, active also in an in vitro assay with the blood cells of today’s humans."[69]

From about three billion years ago, prokaryotic selenoprotein families drive selenocysteine evolution. Selenium is incorporated into several prokaryotic selenoprotein families in bacteria, archaea and eukaryotes as selenocysteine,[70] where selenoprotein peroxiredoxins protect bacterial and eukaryotic cells against oxidative damage. Selenoprotein families of GSH-Px and the deiodinases of eukaryotic cells seem to have a bacterial phylogenetic origin. The selenocysteine-containing form occurs in species as diverse as green algae, diatoms, sea urchin, fish and chicken. Selenium enzymes are involved in utilization of the small reducing molecules glutathione and thioredoxin. One family of selenium-containing molecules (the glutathione peroxidases) destroy peroxide and repair damaged peroxidized cell membranes, using glutathione. Another selenium-containing enzyme in some plants and in animals (thioredoxin reductase) generates reduced thioredoxin, a dithiol that serves as an electron source for peroxidases and also the important reducing enzyme ribonucleotide reductase that makes DNA presursors from RNA precursors.[71]

At about 500 Mya, plants and animals began to transfer from the sea to rivers and land, the environmental deficiency of marine mineral antioxidants (as selenium, iodine, etc.) was a challenge to the evolution of terrestrial life.[66] Trace elements involved in GSH-Px and superoxide dismutase enzymes activities, i.e. selenium, vanadium, magnesium, copper, and zinc, may have been lacking in some terrestrial mineral-deficient areas.[70] Marine organisms retained and sometimes expanded their seleno-proteomes, whereas the seleno-proteomes of some terrestrial organisms were reduced or completely lost. These findings suggest that, with the exception of vertebrates, aquatic life supports selenium utilization, whereas terrestrial habitats lead to reduced use of this trace element.[72] Marine fishes and vertebrate thyroid glands have the highest concentration of selenium and iodine. From about 500 Mya, freshwater and terrestrial plants slowly optimized the production of “new” endogenous antioxidants such as ascorbic acid (Vitamin C), polyphenols (including flavonoids), tocopherols, etc. A few of these appeared more recently, in the last 50–200 million years, in fruits and flowers of angiosperm plants. In fact, the angiosperms (the dominant type of plant today) and most of their antioxidant pigments evolved during the late Jurassic period.

The deiodinase isoenzymes constitute another family of eukaryotic selenoproteins with identified enzyme function. Deiodinases are able to extract electrons from iodides, and iodides from iodothyronines. They are, thus, involved in thyroid-hormone regulation, participating in the protection of thyrocytes from damage by H2O2 produced for thyroid-hormone biosynthesis.[66][67] About 200 Mya, new selenoproteins were developed as mammalian GSH-Px enzymes.[73][74][75][76]

[edit] Chemistry

See also: Category:Selenium compounds and organoselenium chemistry

[edit] Chalcogen compounds

Selenium forms two oxides: selenium dioxide (SeO2) and selenium trioxide (SeO3). Selenium dioxide is formed by the reaction of elemental selenium with oxygen:[12]

Se8 + 8 O2 → 8 SeO2

It is a polymeric solid that forms monomeric SeO2 molecules in the gas phase. It dissolves in water to form selenous acid, H2SeO3. Selenous acid can also be made directly by oxidising elemental selenium with nitric acid:[77]

3 Se + 4 HNO3 → 3 H2SeO3 + 4 NO

Salts of selenous acid are called selenites. These include silver selenite (Ag2SeO3) and sodium selenite (Na2SeO3).

Hydrogen sulfide reacts with aqueous selenous acid to produce selenium disulfide:

H2SeO3 + 2 H2S → SeS2 + 3 H2O

Selenium disulfide consists of 8-membered rings of sulfur atoms with selenium replacing some of the sulfur atoms. It has an approximate composition of SeS2, with individual rings varying in composition, such as Se4S4 and Se2S6. It has various applications, including use in shampoo as an anti-dandruff agent, an inhibitor in polymer chemistry, a glass dye, and a reducing agent in fireworks.[77]

Unlike sulfur, which forms a stable trioxide, selenium trioxide is unstable and decomposes to the dioxide above 185 °C:[12][77]

2 SeO3 → 2 SeO2 + O2 (ΔH = −54 kJ/mol)

Selenium trioxide may be synthesized by dehydrating selenic acid, H2SeO4, which is itself produced by the oxidation of selenium dioxide with hydrogen peroxide:[78]

SeO2 + H2O2 → H2SeO4

Hot, concentrated selenic acid is capable of dissolving gold, forming gold(III) selenate.[79]

[edit] Halogen compounds

Selenium reacts with fluorine to form selenium hexafluoride:

Se8 + 24 F2 → 8 SeF6

Unlike its sulfur counterpart (sulfur hexafluoride) however, SeF6 is more reactive and is a toxic pulmonary irritant.[80] It can cause frostbite and severe irritation on contact with skin.[81]

Other selenium halides include SeF4, Se2Cl2, SeCl4, and Se2Br2. Selenium dichloride (SeCl2), an important reagent in the study of selenium chemistry, may be prepared in pure form by reacting elemental selenium with SO2Cl2 in THF solution.[82] Some of the selenium oxyhalides, such as SeOF2, are useful as nonaqueous solvents.[12]

[edit] Selenides

Like oxygen and sulfur, selenium forms selenides with metals. For example, reaction with aluminum forms aluminum selenide:[12]

3 Se8 + 16 Al → 8 Al2Se3

Other selenides include mercury selenide (HgSe), lead selenide (PbSe), and zinc selenide (ZnSe). An important selenide is copper indium gallium diselenide (Cu(Ga,In)Se2), a semiconductor.

Selenium does not react directly with hydrogen; so hydrogen selenide, the analogue of hydrogen sulfide and water, is prepared by first reacting selenium with a metal to produce a selenide, and then protonating the selenide anion with an acid to produce H2Se.[12]

[edit] Other compounds

Tetraselenium tetranitride, Se4N4, is an explosive orange compound analogous to S4N4.[12][83][84] It can be synthesized by the reaction of SeCl4 with [((CH3)3Si)2N]2Se in dichloromethane solution at −78 °C.[85]

Selenium reacts with cyanides to yield selenocyanates.[12] For example:

8 KCN + Se8 → 8 KSeCN

[edit] See also

引用出處:

http://en.wikipedia.org/wiki/Selenium

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