富勒烯分子

C（100）富勒烯分子静电势的理论研究

Theoretical studies on the molecular electrostatic potential of the C_ ( 100 ) fullerenes

压缩变形对C（20）富勒烯分子电子传输特性的影响

Characteristics of Electronic Transmission on Au Electrode-Compressed C_ ( 20 ) Fullerene-Au Electrode Systems

离子辐照聚乙烯合成小于C（60）的富勒烯分子晶体

Synthesis of fullerene crystals smaller than c_ ( 60 ) by ion beam irradiation of polyethylene

在此基础之上，进一步探索其他小富勒烯分子晶体（如C32，C38和C24）存在的确凿证据。

Based on this we are now trying to find evidence for the existence of other small fullerenes , such as C 24 , C 32 , and C 38 .

富勒烯分子由于其特殊的笼状结构而具有良好的稳定性。

Duo to its special cage-like structure fullerene molecules has good stability .

本文较系统地评述了富勒烯分子的各种物理和化学性质。

This article critically reviewed the physical and chemical properties of fullerenes molecula .

中性富勒烯分子的直接电喷雾质谱分析

The Direct Negative-ion ESI-MS Analyses of Neutral Fullerenes

富勒烯分子的光学双稳性

The optical bistability in fullerenes MOLECULAR MATERIALS

富勒烯分子簇三阶非线性光学特性

The Third-Order Optical Nonlinearity of Fullerenes'Molecules

密度泛函理论和从头算方法对富勒烯分子静电势的比较研究

Comparative investigation of the molecular electrostatic potential of fullerenes with density function theory and HF ab initio methods

理论方面：量子环流理论研究富勒烯分子的磁学性质

Quantum Ring Current Theory for Magnetic Properties of the Fullerene The circulation in south-west area of the South China Sea

大于C（60）/C（70）富勒烯的分子构型

The Molecular Configuration of Fullerene More Than C 60 / C 70

介绍了富勒烯碳分子的结构、性质、制备方法及其应用情况。

This paper describes the structure , properties and applications of fullerenes .

富勒烯与分子力教学

Fullerene & The Teaching of Molecular Force

富勒烯碳分子的结构、性质与应用

Fullerenes : Structure , Properties and Application

由于富勒烯碳分子及其纳米管具有一系列特殊性能，可以预期其研究与应用将会得到迅速发展。

Since fullerenes and their nanotubes have a series of special properties , their research and application are expected to advance rapidly .

介绍了富勒烯衍生物分子器件在分子导线，分子开关和分子储存器的研究进展，展望了分子器件发展前景。

The development course of molecular device is described in this paper . The research advancement of fullerene-derivative in molecular wire , molecular switch and molecular memory is summarized , and prospect for progress on molecular device is given too .

ITO导电玻璃支撑的富勒烯修饰双分子层脂膜的光电效应和传感器应用研究

Application Study of Fullerene Modified BLM on ITO Conducting Glass in Photoelectric Effect and Sensor

自从1985年C60被发现以来，人类第一次认识到碳除石墨、金刚石外的第三种物质结构形态，在之后的研究中，越来越多的富勒烯结构碳分子被发现。

Since C_ ( 60 ) fullerene was discovered in 1985 , the first time people recognized the third molecular constitution of carbon besides graphite and diamond . More and more variant fullerenes had been discovered at subsequent researches .

富勒烯修饰双分子层脂膜分子器件光电了与光谱学特性研究

Photoelectronic and Spectroscopic Properties of Bilayer Lipid Membrane ( BLM ) incorporated with Fullerenes : A New Molecular Device

首先优化了几种富勒烯衍生物的分子结构，在优化的基础上计算它们的重组能、晶体结构中的传输积分、能带和紫外可见吸收光谱。

We calculated their molecular structure , reorganization energy , transfer integral , band structure and UV / Vis absorption spectrum .

综述了最近几年来，功能化富勒烯有机小分子、共轭高分子和金属配合物发光材料的国内外研究状况及应用。

The recent progress and application of functional fullerene organic luminescent materials , including low molecules , conjugated polymers and rare metal complexes , are reviewed in this paper .

用激光光解时间分辨瞬态谱研究了N-甲基-2-（4'-N-乙基咔唑基）-富勒烯吡咯烷的分子内电荷转移过程，在近红外区观测到了长寿命电荷分离态C？

Photoinduced intramolecular electron transfer process from C60 moiety to carbazole moiety has been studied by nanosecond laser flash photolysis . The charge-separated state C ?

研究结果表明：①在电场作用下，C60富勒烯发生极化，分子沿电场方向伸长，沿垂直电场的方向缩短，体积膨胀。

The results of this paper show that ① under exterior electric field , C60 molecule is polarized , elongated in the direction of electric field , shortened perpendicular to the direction of electric field , and swollen in volume .

炭化学的新领域富勒烯Ⅲ.富勒烯分子的性质

A new field of carbon chemistry : fullerenes ⅲ . properties of fullerenes molecula

论述了用激光解吸电离质谱法分析富勒烯。因在电离过程中富勒烯分子不发生裂解，因此这种方法可直接用于富勒烯混合物的分析而勿需任何预分离。

A laser desorption ionization mass spectrometric method for the analysis of fullerenes is described here , This method can directly be used to analyze the mixture of fullerenes without any separation because no fragmentation occurs in ionization process .