Nanomaterials is rapidly growing and entering into many fields.
纳米材料科学蓬勃发展,已渗透到各个领域。
The basic theories of Nanotechnology & Nanomaterials are summarized.
概述了纳米技术及其材料的基本理论知识。
The recent progress in rare-earth phosphate luminescent nanomaterials is reviewed.
综述了稀土磷酸盐纳米发光材料的最新研究进展。
The mechanics problems caused by the four major effects of nanomaterials were studied.
分析了纳米材料的四大效应所带来的力学问题。
Nanomaterials of rare earths are new type materials, which have made people interested.
稀土纳米材料是一种新型材料,已经引起人们的极大兴趣。
So, the synthesis and application of carbon nanomaterials has been an important subject.
因此,碳纳米材料的制备及应用也已成为当前的一个热点研究课题。
The physical and chemical properties of nanomaterials are relevant to their morphology and dimension.
纳米材料的物理和化学性质与它的基本单元的形状和大小密切相关…
The development and application of nanomaterials materials in automobile coatings are also explained.
还简介了纳米材料在汽车涂料中的研究和应用。
Nanomaterials in recent years have becoming popular in biosensors because of its superior characteristics.
近些年来纳米材料因其优越的特性而在生物传感器中受到重用。
Recently, people have been paid more attention to nanomaterials and single molecule manipulation technology.
近年来,纳米材料和单分子操纵技术越来越受到人们的关注。
KNS Nanomaterials Co., Ltd. is devoted to the research, development and production of calcium carbonate powder.
凯恩斯纳米材料有限公司专业致力于碳酸钙粉体的研究、开发和生产。
The excellent performances of nanomaterials were introduced and the applications of nanomaterials were discussed.
对各种纳米材料的卓越性能进行了概述,并列举了部分优异纳米材料的应用。
The cells of microorganism have many kinds of geometrical shapes and can be used for a template of nanomaterials.
微生物细胞具有各种各样的几何外形,如球状、丝状、螺旋状、玉米状、刺猬状等。
In summary, a new method to synthesize nanomaterials through ligand-assisted low temperature solution has been explored.
探索了一条新颖的配位体辅助低温液相合成纳米材料的方法。
Scientists have greater control than ever over nanomaterials in a variety of substances, and their understanding is growing.
未来,科学家将可以更好地控制各种物质的纳米材料,对纳米技术将有更深入的理解。
Nanomaterials have different physical, chemical characters from macroscopical materials and microscopical atom and molecular.
纳米材料的物理、化学性质不同于微观的原子、分子,也不同于宏观物体。
In this dissertation, we have tried to find new methods to design and construct novel alkanethiolate –protected nanomaterials.
本论文主要的目的是采用简单的方法制备新的烷基硫醇保护的纳米粒子。
The emphasis is put upon the new developments of various approaches taken to prepare hybrid nanomaterials in the recent years.
着重总结了近年来这类杂化材料在功能性研究上新的进展,并对今后研究的发展趋势进行了展望。
So, how to control the growing of the crystals in the process of sintering becomes the key to manufacturing bulk nanomaterials.
因此,控制纳米晶粒在烧结过程中的长大就成为制备块状纳米材料的关键。
The preparation and performance study of nanomaterials based on physics and chemistry are the foundation of the whole nanotechnology.
其中,以物理和化学为理论基础的纳米材料的制备和性能研究是整个纳米科技的基础。
Graphene is one of the thinnest electronic nanomaterials and consists of a single layer of carbon atoms packed in a honeycomb structure.
石墨烯是最薄的电子纳米材料之一,其是由单层蜂窝状结构的单碳原子层组成的。
The properties and preparation methods of nanomaterials were reviewed, its application and development trend in chemical were discussed.
介绍了纳米物质的特性、制备方法及其在精细化工中的应用,对其发展前景进行了展望。
Nanomaterials have good adsorbability because of their huge specific surface area, therefore in the foreground of environmental analysis.
纳米材料具有大的比表面积,拥有优良的吸附性能,因此在环境分析领域的应用逐渐增多。
Nanomaterials have excellent microwave absorbing properties owing to their special structures and unique physical and chemical properties.
由于纳米材料特殊的结构特征及其特殊的物理化学特性,使得纳米材料具有极好的吸波特性。
The application prospects of carbon nanomaterials, one of the new class carbon materials, are outlined with carbon nanotubes as the example.
对以碳纳米材料为首的新型碳材料的应用前景做了前瞻性的预测。
Nanomaterials of 20 kinds of morphologies are selected and their preparation methods, properties and prospects of applications are reviewed.
列举20种形态的纳米光子学材料,阐明它们的制备方法、特性和应用前景。
Nanomaterials have been used in many fields because of their unique properties in optics, electrics, magnetics, mechanics, catalysis and adsorption etc.
纳米材料因其独特的光、电、磁、力、催化和吸附等性能而被广泛应用。
Because of the special physical and chemical character, the nanomaterials has been applied in many fields, and brings enormous progress to people's life.
由于纳米材料的特殊理化性质,使其有广泛的应用领域,给人们的生活带来巨大的进步。
Because of the special physical and chemical character, the nanomaterials has been applied in many fields, and brings enormous progress to people's life.
由于纳米材料的特殊理化性质,使其有广泛的应用领域,给人们的生活带来巨大的进步。
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