Abstract Tungsten is an elegant substance, and its compounds have great significance because of their extensive range of applications in diverse fields such as in gas sensors, photocatalysis, lithium ion batteries, H2 production, electrochromic devices, dyed sensitized solar cells, microchip technology, and liquid crystal displays. Tungsten compounds exhibit a more efficient catalytic behavior, and tungsten-dependent enzymes generally catalyze the transfer of an oxygen atom to or from a physiological donor/acceptor with the metal center. Furthermore, tungsten has an n-type semiconductor band gap. Tungsten forms complexes by reacting with several elements such as H, C, N, O, and P as well as other numerous inorganic elements. Interestingly, all tungsten reactions occur at ambient temperature, usually with tetrahydrofuran and dichloromethane under vacuum. Tungsten has extraordinarily high-temperature properties, making it very useful for X-ray production and heating elements in furnaces. Tungsten coordinates with diverse nonmetallic elements and ligands and produces interesting compounds. This article describes an overview of the synthesis of various organometallic compounds of tungsten.

中文翻译：

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钨的有机金属化合物的合成技术

摘要 钨是一种优雅的物质，其化合物因其在气体传感器、光催化、锂离子电池、制氢、电致变色器件、染料敏化太阳能电池、微芯片技术等多个领域的广泛应用而具有重要意义。液晶显示器。钨化合物表现出更有效的催化行为，并且依赖于钨的酶通常催化氧原子与金属中心的生理供体/受体之间的转移。此外，钨具有n型半导体带隙。钨通过与 H、C、N、O 和 P 等多种元素以及其他多种无机元素反应形成络合物。有趣的是，所有的钨反应都发生在环境温度下，通常与四氢呋喃和二氯甲烷在真空下反应。钨具有非凡的高温特性，使其非常适用于 X 射线产生和熔炉中的加热元件。钨与多种非金属元素和配体协调并产生有趣的化合物。本文概述了钨的各种有机金属化合物的合成。