Innovations in isocyanate synthesis for a sustainable future.

IF 2.9 3区化学 Q1 CHEMISTRY, ORGANIC

Organic & Biomolecular Chemistry Pub Date : 2024-11-20 DOI:10.1039/d4ob01598c

Jorge Andrés Mora Vargas, Ketan S Mandrekar, Radell Echemendía, Antonio C B Burtoloso

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Abstract

Isocyanates play a crucial role as key building blocks in the production of thermoplastic foams, elastomers, adhesives, agrochemicals, and pharmaceuticals. These compounds are essential in the manufacture of various polymeric products, such as polyurethane foams, synthetic rubbers, and surface coatings. Given their significance, and the fact that many isocyanates are highly reactive and toxic, there is an increasing demand for innovative and sustainable methods for their synthesis and detection that emphasize safety, efficiency, and selectivity. Developing processes for isocyanate production that avoid hazardous reagents like phosgene is particularly critical. While several methods exist for the in situ generation of isocyanates, the search for an eco-friendly and sustainable approach for their direct synthesis and isolation continues. Recent advances in isocyanate synthesis promise innovative and efficient strategies with broad industrial and environmental benefits. This review highlights various methods for synthesizing di- and monoisocyanates, emphasizing their isolation and conversion into ureas and carbamates in line with the principles of sustainable and green chemistry.

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创新异氰酸酯合成技术，实现可持续发展的未来。

异氰酸酯是生产热塑性泡沫塑料、弹性体、粘合剂、农用化学品和药品的关键原料。这些化合物在聚氨酯泡沫、合成橡胶和表面涂层等各种聚合物产品的生产中至关重要。鉴于异氰酸酯的重要性，以及许多异氰酸酯具有高活性和毒性的事实，人们越来越需要创新和可持续的方法来合成和检测它们，并强调安全性、效率和选择性。开发避免使用光气等危险试剂的异氰酸酯生产工艺尤为重要。虽然已有几种原位生成异氰酸酯的方法，但人们仍在继续寻找一种生态友好和可持续的方法来直接合成和分离异氰酸酯。异氰酸酯合成技术的最新进展为创新、高效的战略提供了可能，并具有广泛的工业和环境效益。本综述重点介绍了合成二异氰酸酯和单异氰酸酯的各种方法，强调了根据可持续和绿色化学原则将其分离并转化为脲和氨基甲酸酯的方法。

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