e-ISSN: 2319 - 9849
纳米化学方面是一个新的学科关注的化学和材料科学的发展创新的纳米材料制造过程。这些材料已经研究了各种各样的应用程序,包括电子设备和系统、复合材料、生物技术和医药、甚至纺织品。除非协调表面活性剂用来外套表面的无机纳米材料(金属、金属氧化物或金属硫属化合物),表面极其被动和不稳定。它很简单,看看表面活性剂功能协调配体,以及它如何可能扮演着至关重要的角色不仅在结构稳定而且在结构管理。我们提供直接合成为一个独特的和有效的合成技术生产的各种重要的和迷人的无机纳米材料,并讨论各种衔接概念之间的分子和纳米化学方面的协调。纳米科学是一个多方面的领域包括纳米技术和纳米化学方面的话题。纳米技术用于创建具有独特性能的纳米粒子,并基于他们的生产材料和设备。这是21世纪的热门话题之一的自然科学。从微尺度过渡到纳米尺度与纳米化学方面的。规模效应的发现,这可能被认为是一个新的自由度提供了新的属性化合物,导致先前未被发现的化学反应,发生由于研究纳米尺度的粒子。 The early efforts were focused on the study of atoms, clusters, nanoparticles of various metals, semiconductors, fullerenes, and carbon nanotubes, as well as the physicochemical features of the corresponding materials. The first investigations in the subject of nanochemistry were based on this. For the most thorough examination of nanochemists' contributions. The properties of complex organic compounds, which can include atoms of oxygen, sulphur, and halogens in addition to carbon and hydrogen, as well as the mechanisms of processes involving these compounds, affect advances in biochemistry and nanomedicine. The methods for manufacturing nanoparticles containing complex organic compounds, as well as their physical properties, are investigated in depth. This is partly due to the fact that intermolecular interactions are less than interatomic interactions, and the size dependency of organic nanoparticle physicochemical features is less pronounced than inorganic nanoparticles. Nanoparticles are objects that exist in between compact organic compounds and single molecules. The fact that organic nanoparticle research has just just begun, in contrast to metal nanoparticle research, can be explained by the following two key causes. For starters, organic materials have lower melting temperatures and less thermal stability.