JoVE Journal > Chemistry
Summary
Abstract
Introduction
Protocol
Risultati
Discussion
Divulgazioni
Acknowledgements
Materials
Riferimenti
Please note that all translations are automatically generated. Click here for the English version.
Chimica

的合成[锡<sub> 10</sub>(SI(SIME<sub> 3</sub>)<sub> 3</sub>)<sub> 4</sub>]<sup> 2</sup<sup> -</sup>使用亚稳锡(I)卤溶液通过共缩聚合成技术

Published: November 28, 2016
doi:
10.3791/54498
, ,
1Chemistry Department, Institute of Inorganic Chemistry,University of Tübingen

Summary

The disproportionation reaction of a metastable Sn(I) chloride solution, obtained via the preparative co-condensation technique, is used for the synthesis of a metalloid tin cluster compound.

Abstract

良好表征金属锡簇,通过施加在空间位苛刻的配体的存在下,亚稳定的Sn(I)的卤化物的歧化合成的数目,在最近几年已经增加。亚锡(I)卤化物在通过制备共缩聚技术“外太空条件”的合成。由此,subhalide是在高温烘箱合成,约1300℃,并在通过元素锡的卤化氢气体(例如 HCl)的反应减压。所述subhalide(例如氯化亚锡)在-196℃下被捕获的惰性溶剂的基质内,如甲苯。固体基质加热至-78℃,使subhalide的亚稳态溶液。亚稳subhalide溶液是高度反应性的,但可存储在-78℃下几个星期。上加热该溶液到室温时,发生歧化反应,导致元素锡和相应的二卤化物。通过采用大体积配体与Si(SIME 3)3,中间金属原子簇化合物可以完成歧化元素锡之前捕获。因此,亚稳的Sn(I)Cl溶液与锂硅(森3)3的反应得到[锡10(硅(森3)3)4] 2 1以高收率。1为黑色晶体经由包括盐复分解,歧化,和较大的簇降解的复杂反应顺序形成。此外,1可通过各种方法,如NMR或单晶X-射线结构分析来分析。

Introduction

由于在纳米技术领域的最新进展,分子和固态之间的纳米级尺寸范围内变得越来越重要,并且各种研究工作1的焦点。研究与纳米级化合物是特别适用于金属或半金属的兴趣,如剧变小分子物质的转化过程中发生( 例如,氧化物,卤化物:非导通; 例如, 氯化铝,AUCL 3,GeO 2 )到的通式Mn为R M金属簇2(N> M; M =金属,如铝,金,锡 ; R =配位体如SC 6 H 4 -COOH,-N(SIME 3)2, ),到最终散装元素相(金属:导电;半金属:半导体; 例如,元素的Al,Au或Ge)的3。

一个明确的分子纳米级compou的合成第二是具有挑战性的,由于其性质稳。许多合成方法得到具有一定粒径分布4的金属纳米颗粒,这意味着不同大小的金属原子簇化合物的混合物。因此,要建立一个基础,纳米级材料的结构与性能的关系,合成方法必须制定明确的访问分子纳米级化合物。这些明确的分子化合物(在金属5,6,7的情况下金属簇,8)将在复杂性和看似简单的化学的基本原则,如溶解和金属9的形成线索。

访问各种金属的金属簇一种合成路线,从稳定前体的还原被还原形成金属簇,主要是在低产量( 例如,准金属基14簇像锡15开始</suB>(DippNSiMe 3)6(迪普= 2,6-的iPr 2 -C 6 H 3)10,10脯氨酸(Hyp)6脯氨酸(Hyp =硅(森3)3)11,或Ge 5(CH(SIME 3 2)2)4 12)。 此外,越来越多的硬币金属的金属团簇通过前体的一个俘获配体的存在,如减少合成 将[Ag 44(MBA)30] 4 – (对- MBA =对-巯基苯甲酸)13和Au 102(MBA)44 14。旁施加还原脱卤,Schnöckel 的合成路线。通过将相应的元素的高反应性的亚稳单卤化物的歧化反应引入到金属基13簇的合成路线( 例如,3AlCl→2AL + 氯化铝)。

的合成所需的单卤化物经由制备型共缩合技术,其中在高温下,ALX和GAX的气相分子(X =氯,溴,I)的合成和随后捕获在冷冻溶剂的矩阵( 图1由此进行)15。因此,该技术可以访问新试剂,开辟了道路化学新颖区域( 例如,从亚稳态单卤化物开始,直径在纳米范围内像金属团簇[铝77(N(3)2)20] 2 或[镓84(N(3)2)20 4 可以得到)16,17。

通过歧化反应合成途径因此最有生产力的,导致团簇直径在纳米范围内。然而,这种合成路线是唯一可能的,如果亚稳subhalide是在手该disproportionates在低温(通常远低于0℃)。再次,在基14的情况下,需要单卤化物,如subvalent二卤化物MX 2(M =锗,锡,铅)过于稳定,在远高于100℃的温度下不相称。亚稳态组14一卤化物解决方案的综合通过制备共缩聚技术是可能的。然而,在高得多的温度相对于获得该组13单卤化物,这是容易获得的作为在1000℃的气相物种组14单卤化物。因此,SnBr在最高产量在1250℃18获得的,而GEBR 19,以及的SiCl 2 20,以甚至更高的温度下得到的,高达1600℃。的单卤化物被“困”经由制备型共缩合技术( 图1),从而导致亚稳态单卤化物的解决方案。从这些亚稳的解决方案开始,我们最近能合成各种Ø˚F锗和锡,即[李(THF)2] 3 [葛14脯氨酸(Hyp)5]脯氨酸(Hyp =硅(森)3)21,10脯氨酸(Hyp)6 22,以及新颖的准金属基14簇化合物{ [李([12]冠4)2]} 2 [锡10(羟脯氨酸)4] 23。在这里,我们提出了一个亚稳态锡(I)Cl溶液合成的自制合作冷凝装置内,并描述其与LiHyp反应给金属簇[10锡(羟脯氨酸)4] 2 1高产。

Protocol

注意!请咨询使用前的所有相关材料安全数据表(MSDS)。几个在这些合成中使用的化学品是剧毒,发火,和致癌性。相比,他们的大部分对手纳米材料可能有额外的危害。进行反应时,包括利用工程控制(通风柜和手套箱)和个人防护装备(护目镜,手套,实验室外套,全长裤,封闭趾鞋)的请使用所有适当的安全措施。下面的过程部分涉及标准无空气的Schlenk技术。施加的共缩合?…

Representative Results

在与制备共缩合技术缀合基质隔离技术的原理示出( 图1),以及作为助冷凝装置( 图2)和石墨反应器的设置( 图3)。 图4和图5显示的照片共缩聚装置的组装。在图6中 ,用质量流量控制器的气体供给部件被示出。 图7示出了前不久钢容器固定在主凸缘关闭共缩合装置的主装置。到?…

Discussion

通过将制备共缩合技术( 1)25的基础上,分子新型材料,如得到SnBr。由于在温度,压力,金属,和反应性气体的高弹性,大量的各种高反应性物质的亚稳态溶液可以合成。例如,以这种方式已经获得的硅和锗的subhalides。然而,寻找合适的条件以获得用于进一步合成亚稳溶液是不平凡的,并且溶液通常必须在非常低的温度进行处理( 例如,-78℃)。此外,该合成需?…

Divulgazioni

The authors have nothing to disclose.

Acknowledgements

我们感谢德意志研究联合会(DFG)的资金支持,我们感谢丹尼尔·沃纳博士有益的讨论。

Materials

Tin 99.999% ABCR AB122397
HydrogenchlorideN28  99.8% Air Liquide P0820S10R0A001 Toxic
Toluene anhydrous 99.8% Sigma Aldrich 244511
Tri-n-butylphosphine >93.5% Sigma Aldrich 90827 Toxic
TMEDA, >99.5% Sigma Aldrich 411019
12-crown-4 Sigma Aldrich 194905 Toxic
THF anhydrous, >99.9% Sigma Aldrich 401757
Sodium, 99.95% Sigma Aldrich 262715
Benzophenone, >99% Sigma Aldrich 427551
Differential pressure manometer  MKS MKS Baratron 223B
Mass flow controller  Bronckhorst  Low Δp flow mass flow controller
High frequency generator Trumpf Hüttinger TruHeat MF 5020
NMR spectrometer Bruker Bruker DRX-250
Glovebox GS Systemtechnik
Argon 5.0 Westfalen
Nitrogen 4.8 Westfalen
Graphite SGL
Quartz glass tube Gebr. Rettberg GmbH
Steel transferring cannula Rohre Ketterer
Balance Kern Kern PFB200-3
Oil diffusion pump Balzers Balzers Diff900
Rotary vane pump Balzers Balzers QK100L4D
Pyrometer Sensotherm 6285
Schlenk tubes with glassy stopcocks Gebr. Rettberg GmbH J.-Young-type valve with glassy stopcock
DOWNLOAD MATERIALS LIST

Riferimenti

  1. Goesmann, H., Feldmann, C. Nanoparticulate Functional Materials. Angew. Chem. Int. Ed. 49, 1362-1395 (2010).
  2. Purath, A., Köppe, R., Schnöckel, H. [Al7{N(SiMe3)2}6]-: A first step towards aluminum metal formation by disproportionation. Angew. Chem. Int. Ed. 38, 2926-2927 (1999).
  3. Schnöckel, H. Metalloid Al- and Ga-clusters: a novel dimension in organometallic chemistry linking the molecular and the solid-state areas?. Dalton Trans. , 3131-3136 (2005).
  4. Hu, K. -. J., Plant, S. R., Ellis, P. R., Brown, C. M., Bishop, P. T., Palmer, R. E. Atomic Resolution Observation of a Size-Dependent Change in the Ripening Modes of Mass-Selected Au Nanoclusters Involved in CO Oxidation. J. Am. Chem. Soc. 137 (48), 15161-15168 (2015).
  5. Schnöckel, H. Structures and Properties of Metalloid Al and Ga Clusters Open Our Eyes to the Diversity and Complexity of Fundamental Chemical and Physical Processes during Formation and Dissolution of Metals. Chem. Rev. 110, 4125-4163 (2010).
  6. Schnepf, A. Metalloid Cluster Compounds of Germanium: Novel Structural Motives on the Way to Elemental Germanium!. New J. Chem. 34, 2079 (2010).
  7. Schrenk, C., Schnepf, A. Metalloid Sn clusters: properties and the novel synthesis via a disproportionation reaction of a monohalide. Rev. Inorg. Chem. 34, 93-118 (2014).
  8. Jin, R. Atomically precise metal nanoclusters: stable sizes and optical properties. Nanoscale. 7, 1549-1565 (2015).
  9. Schnepf, A., Dehnen, S. Metalloid. Clusters in Structure and Bonding – Clusters – Contemporary Insight in Structure and Bonding. , (2016).
  10. Brynda, M., Herber, R., Hitchcock, P. B., Lappert, M. F., Nowik, I., Power, P. P., Protchenko, A. V., Ruzicka, A., Steiner, J. Higher-Nuclearity Group 14 Metalloid Clusters: [Sn9{Sn(NRR’)}6]. Angew. Chem. Int. Ed. 45, 4333-4337 (2006).
  11. Klinkhammer, K. W., Xiong, Y., Yao, S. Molecular lead clusters – from unexpected discovery to rational synthesis. Angew. Chem. Int. Ed. 43, 6202-6204 (2004).
  12. Richards, A. F., Brynda, M., Olmstead, M. M., Power, P. P. Characterization of Ge5R4(R = CH(SiMe3)2, C6H3-2,6-Mes2): Germanium Clusters of a New Structural Type with Singlet Biradical. Organometallics. 23, 2841-2844 (2004).
  13. Desireddy, A., et al. Ultrastable silver nanoparticles. Nature. 501, 399-402 (2013).
  14. Jadzinsky, P. D., Calero, G., Ackerson, C. J., Bushnell, D. A., Kornberg, R. D. Structure of a Thiol Monolayer-Protected Gold Nanoparticle at 1.1 Å Resolution. Science. , 430-433 (2007).
  15. Schnepf, A., Schnöckel, H. Metalloid aluminum and gallium clusters: Element modifications on the molecular scale?. Angew. Chem., Int. Ed. 41, 3532-3554 (2002).
  16. Ecker, A., Weckert, E., Schnöckel, H. Synthesis and structural characterization of an Al77 cluster. Nature. 387, 379-381 (1997).
  17. Schnepf, A., Schnöckel, H. Synthesis and structure of a Ga84R204- cluster-a link between metalloid clusters and fullerenes?. Angew. Chem. Int. Ed. 40, 712-715 (2001).
  18. Schrenk, C., Köppe, R., Schellenberg, I., Pöttgen, R., Schnepf, A. Synthesis of tin(I)bromide. A novel binary halide for synthetic chemistry. Z. Anorg. Allg. Chem. 635, 1541-1548 (2009).
  19. Schnepf, A., Köppe, R. Synthese von Germanium(I)bromid. Ein erster Schritt zu neuen Clusterverbindungen des Germaniums?. Z. Anorg. Allg. Chem. 628, 2914-2918 (2002).
  20. Uhlemann, F., Köppe, R., Schnepf, A. Synthesis of metastable Si(II)X2solutions (X = F, Cl). A Novel Binary Halide for Synthesis. Z. Anorg. Allg. Chem. 640, 1658-1664 (2014).
  21. Schenk, C., et al. The Formal Combination of Three Singlet Biradicaloid Entities to a Singlet Hexaradicaloid Metalloid Ge14[Si(SiMe3)3]5Li3(THF)6Cluster. J. Am. Chem. Soc. 133, 2518-2524 (2011).
  22. Schrenk, C., Schellenberg, I., Pöttgen, R., Schnepf, A. The formation of a metalloid Sn10[Si(SiMe3)3]6cluster compound and its relation to the α↔β tin phase transition. Dalton Trans. 39, 1872-1876 (2010).
  23. Schrenk, C., Winter, F., Pöttgen, R., Schnepf, A. {Sn10[Si(SiMe3)3]4}2- : A high reactive metalloid tin cluster with an open ligand shell for further applications. Chem. Eur. J. 21, 2992-2997 (2015).
  24. Gutekunst, G., Brook, A. G. Tris(trimethylsilyl)silyllithium.3 THF: a stable crystalline silyllithium reagent. J. Organomet. Chem. 225, 1-3 (1982).
  25. Timms, P. L. Techniques of Preparative Cryochemistry. Cryochemistry. , 61-136 (1976).
  26. Schrenk, C., Gerke, B., Pöttgen, R., Clayborne, A., Schnepf, A. Reactions with a Metalloid Tin Cluster {Sn10[Si(SiMe3)3]4}2-: Ligand Elimination versus Coordination Chemistry. Chimica. 21, 8222-8228 (2015).
  27. Schnepf, A. Chemistry Applying Metalloid Tin Clusters. Phosphorus, Sulfur and Silicon and the Related Elements. 191, 662-664 (2016).

Tags

Sn(I) Halide SolutionMetastable Metalloid ClustersCo-condensation TechniqueNanotechnologyStructure-property RelationsCoordination ChemistryNovel Materials

Play Video
PDF
DOI
DOWNLOAD MATERIALS LIST
Citazione di questo articolo
Binder, M., Schrenk, C., Schnepf, A. The Synthesis of [Sn10(Si(SiMe3)3)4]2 Using a Metastable Sn(I) Halide Solution Synthesized via a Co-condensation Technique. J. Vis. Exp. (117), e54498, doi:10.3791/54498 (2016).
Scarica citazione
Ristampe e autorizzazioni

View Video

To prove you're not a robot, please enter the text in the image below

CAPTCHA Image
Play CAPTCHA Audio
Refresh Image