Abstract In recent years, chemistry of metal-nitrogen–bonded compounds have attracted tremendous attention mainly because of unusual properties resulting from such a bond involving carbon and other heteroatoms. M−N–bonded compounds, when containing group VI elements, especially selenium, has attracted great attention in materials chemistry. In addition, the increased interest in synthesis of N-containing bioactive compounds with other heteroatoms such as selenium, sulfur, etc is mainly because of their tremendous potential as antioxidants, additives, dyes for polymers, and as insecticides, in solvent extraction, and in nanotechnology. Thus, the synthesis and applications of 1,2,3-selenadiazoles have attracted recent interest of materials scientists, including nanotechnologists, pharmaceutical chemists, and organic chemists. The chemistry of 1,2,3-selenadiazoles is highly rich and has been practiced ever since its first report in 1972. Such N-containing Se-heterocycles form several types of selenadiazoles that are a rich source of selenium for semiconductor nanoparticles of metal selenides. The materials chemistry of such molecules has been documented for over three decades, and their great scope in semiconductors has emerged. This review article is an attempt to bring a variety of materials and biological application of 1,2,3-selenadiazoles for better understanding of the researchers.

中文翻译：

---

1,2,3-硒二唑的材料和生物应用：综述

摘要 近年来，金属氮键化合物的化学引起了极大的关注，主要是因为这种包含碳和其他杂原子的键所产生的不同寻常的性质。M-N键化合物，当含有VI族元素，尤其是硒时，在材料化学中引起了极大的关注。此外，人们对合成含有其他杂原子（如硒、硫等）的含氮生物活性化合物越来越感兴趣，主要是因为它们作为抗氧化剂、添加剂、聚合物染料、杀虫剂、溶剂提取和纳米技术。因此，1,2,3-硒二唑的合成和应用最近引起了材料科学家的兴趣，包括纳米技术学家、药物化学家和有机化学家。1,2的化学，3-硒二唑非常丰富，自 1972 年首次报道以来一直在实践中。这种含氮硒杂环形成几种类型的硒二唑，这些硒二唑是金属硒化物半导体纳米颗粒的硒的丰富来源。这些分子的材料化学已经被记录了三十多年，并且它们在半导体中的广泛应用已经出现。这篇综述文章试图为研究人员带来1,2,3-硒二唑的多种材料和生物学应用。这些分子的材料化学已经被记录了三十多年，并且它们在半导体中的广泛应用已经出现。这篇综述文章试图为研究人员带来1,2,3-硒二唑的多种材料和生物学应用。这些分子的材料化学已经被记录了三十多年，并且它们在半导体中的广泛应用已经出现。这篇综述文章试图为研究人员带来1,2,3-硒二唑的多种材料和生物学应用。