molecular electronics
英 [məˈlekjələ(r) ɪˌlekˈtrɒnɪks]
美 [məˈlekjələr ɪˌlekˈtrɑːnɪks]
分子电子学; 缩写为moletronics
双语例句
- Within the last decade, there is an increasing interest in molecular electronics that is one of the important branches of the nanoelectronics.
近些年来,分子电子学已经成为人们十分感兴趣的研究领域,是纳米电子学的重要研究方向和研究领域。 - How to reach the ultimate miniaturization limit of molecular electronics and related nanoscale patterning techniques of organic materials will also be discussed.
亦将讨论如何达到分子电子学和有机材质相关的奈米级制像技术的微缩极限。 - The chemistry of the organic monolayer is not critical; the switch works with many different molecules and so can be used with many different self-assembled molecular electronics systems.
这种有机单分子层的化学性并不是临界的;开关与许多不同的分子一道起作用,开关也能与许多不同的自我组装分子电子系统一块使用。 - An investigation into integrated optics system with a gas sensitive function of molecular electronics
分子电子学气体传感的集成光学系统的研究 - Application of metalloporphyrins in molecular electronics
金属卟啉在分子电子学中的应用 - Molecular electronic technique is a newly developed bionic technology on the basis of molecular electronics in 1970's.
分子电子技术是以分子作为载体,在分子水平上实现电子学的信息处理和存储过程的仿生技术。 - This work is a significant milestone in molecular electronics.
这种分子减法器电路的实现对分子电子学发展有重要的意义。 - Owing to unique properties of ferrocenyl polymer such as redox, electricity and magnetism, its supramolecular systems have extensive applied prospects in sensor, catalysis, molecular electronics, biological and medical fields.
二茂铁基聚合物具有独特的氧化还原、电、磁等性能,其构建成超分子体系后在传感器、催化、分子电子学、生物和医学等领域有着广泛的应用前景。 - Self-assembly is one of the most prospective methods to overcome the contact problem between electrodes and the molecules of organic functional materials, which has attracted particular attention for the construction of molecular electronic devices recently, and became one of the most important directions of molecular electronics development.
自组装技术是解决有机功能分子与电极连接问题最有希望的技术之一,近年来在构筑分子电子器件中得到了越来越多的应用,成为分子电子学发展的一个重要方向。 - Progresses in Organic Field Effect Transistors and Molecular Electronics
有机场效应晶体管和分子电子学研究进展 - This paper reviews the study and application of metalloporphyrins in molecular electronics, such as molecular memory, molecular recognition, picture sensors, biosensors and chemical sensors.
综述了金属卟啉在分子电子学,如分子存储、分子识别、图象传感、生物传感和化学传感等方面的研究及应用。 - In this paper, the basic principle and general appearance of single-electron phenomena in some molecular electronics devices are briefly introduced. Its potential application and prospect in molecular electronic devices are discussed too.
本文介绍了单电子现象的基本物理原理,分析了一些分子电子器件中的单电子现象,并说明了分子电子器件中单电子现象的研究意义及其应用前景。 - The design and sythesis of Keggin type organic-inorganic hybrid compounds is of the great interest owing to extensive theoretical and practical applications in adsorption, catalysis and molecular electronics.
由于具有多种不同的结构和在催化、医药和分子电子学方面有着广泛的应用前景,因此设计和合成Keggin型无机-有机杂化材料成为人们研究的热点。 - The objects and ways of research on molecular electronics
分子电子学的研究目标和途径 - Molecular electronics is one of the novel research fields developed rapidly in recent years and its theoretical successes will result in the production of molecular electronic devices, which can be assembled by using the LB ( Langmuir Blodgett) film techniques.
分子电子学是近年来迅速发展起来的崭新学科,理论上的成功将必然导致新型的分子电子器件的产生,而LB膜技术已成为一种对广义分子电子器件进行组装的新技术。 - The development of scanning probe microscopes ( SPM) techniques and quantum chemistry calculations provides powerful tools for exploring the molecular electronics.
扫面探针显微术和量子化学计算的发展为研究分子电子器件提供了强有力的工具。 - Therefore, if DNA is a conductor, it will be the ideal material for nano-line and molecular electronics.
因此,如果DNA具有导电性,将是纳米导线及分子器件的理想材料。 - In this paper, we present the recent development, main research methods, and theoretic basis in the molecular electronics field first.
首先我们简要介绍了分子器件的发展概况、主要研究方法和理论基础。 - It is important to investigate the adsorption and assembly of organic functional molecules on surfaces for our understanding of the physical, chemical, molecular electronics and nonlinear optical properties as well as the "bottom-up" approach for nano functional devices.
有机功能分子在金属表面的吸附与组装结构的研究对我们认识其物理、化学、分子电子学、非线性光学等特性都有非常重要的意义,也是自下而上构建纳米功能器件的重要途径。 - Recently, along with development of Nanotechnology and molecular synthesis technology, molecular electronics has become a promising research area as well as an important field in Nano-electronics.
近年来,随着纳米技术和分子合成技术的发展,分子电子学逐渐成为人们十分感兴趣的一个研究领域,也成为纳米电子学的重要研究方向。 - Great development of the study on molecular electronics and molecular devices has taken place in theoretical regions as well as in experimental regions in recent years.
近年来,分子电子学、分子器件的研究在实验上和理论上都取得了很大的发展。 - In this paper, we firstly introduce the recent development of molecular devices, molecular rectifiers, and theoretic basis of molecular electronics.
本论文首先介绍了分子器件、分子整流器的研究背景、国内外发展现状、主要的研究方法及基本理论。 - At first, the development of the mesoscopic physics and the quantum transport theory is outlined. Then we review some recent advances in molecular electronics, including some interesting topics and possible development directions.
论文首先介绍了介观物理学和量子输运理论的发展;随后综述了分子电子学的一些进展,包括近年来的部分研究热点以及未来的发展的可能方向。 - One of the most promising solutions is to develop molecular-scale electronics ( Molecular electronics).
解决上述问题的出路之一在于发展分子尺度的电子器件(分子电子器件)。 - Molecular electronics is an emerging discipline, and it focuses on the study of the electronic properties of a single molecule or a few molecules.
分子电子学是一门新兴的学科,它以单个分子或者少数分子的电子学性质为研究对象。 - Research filed of molecular electronics involve the synthesis of variety molecular electronic devices, performance testing and how assemble them to realize certain logical functions.
分子电子学的研究内容包括各种分子电子器件的合成、性能测试以及如何将它们组装在一起以实现一定的逻辑功能。 - And the research of electric and optical properties for these molecular-scale devices has become an independent subject gradually, that is molecular electronics.
同时研究和测量这些分子尺度元器件的电子特性或者光学特性也逐渐发展成一门独立的学科,这就是分子电子学。 - Furthermore, the research of electric and optical properties for these devices has become molecular electronics.
对于这些分子尺度元器件的电学、光学特性的测量和分析发展成为了分子电子学。 - Electromagnetically functionalized micro/ nanostructures of conducting polymers are of special interest due to their potential applications in areas such as electromagnetic interference shielding, microwave absorption, nonlinear optics, molecular electronics, and biomedicine.
导电聚合物电磁功能化的微纳米结构引起了科学家们的广泛兴趣。其在电磁干扰屏蔽、微波吸收、非线性光学、分子电子学、生物医学等领域都有着潜在的应用。