有机和金属有机非线性光学晶体材料

非线性光学材料是激光技术的重要物质基础之一,是高技术研究的一个组成部分。二十多年来,非线性光学材料的研究经历了无机晶体、有机材料的阶段,现在又开始了金属有机非线性光学材料的探索。本文拟综述有机和金属有机二阶非线性光学晶体材料的研究进展,而不讨论高分子材料以及三阶非线性光学效应。鉴于刊物读者的特     

聚合物非线性光学材料

最近,有机非线性光学材料已引起了人们极大的兴趣。一些可极化有机分子具有很大的分子超极化率,可惜,受晶体对称性的限制仅有少数晶体具有二阶非线性光学效应。极化聚合物可以产生统计非中心对称的环境,使材料的二阶特性显示出来。本文在简单介绍了有机非线性光学和极化的原理后,综述了聚合物二阶非线性光学材料的研究进展。此外,对聚合物的三阶非线性光学效应的研究也作了介绍。     

盐酸氨基脲的二阶非线性光学性质研究

非线性光学(NLO)材料在光学信息处理、远程通讯等光电子学领域有着重要的应用,有效地预测和设计出二阶非线性光学材料所必需的非中心对称晶体,提高材料的综合性能是这一领域的研究热点。标题化合物盐酸氨基脲是以尿素为分子母体的有机离子型化合物,具有将有机和无机材料的优异性能集于一身的结构优势,是综合性能优的材料之一。     

有机共晶非线性光学材料及应用研究进展

随着二次谐波(SHG)和双光子吸收(TPA)的产生,有机非线性光学(NLO)材料近十年来在激光频率转换、生物成像、微纳加工、光限幅以及太赫兹波(THz)等领域发挥越来越重要的应用,引起了广泛兴趣.迄今为止,报道的绝大多数有机非线性光学活性材料为单一组分,它们化学合成繁琐、实验条件苛刻且难以打破单一组分固有属性的限制.而复合材料可通过共混、掺杂、共结晶等简易形式迅速地拓宽新材料种类,通过一种分子以上基于分子间非共价相互作用的有机共晶已在很大程度上朝着调节和修改分子固体的物理化学性质的方向发展.然而,目前国内外并没有关于有机共晶在非线性光学领域中的系统性总结与介绍.本综述首先介绍二阶、三阶非线性光学性能参数及其测试方法;接着,介绍共晶材料在该领域的最新研究进展,包括材料的种类、制备方法、产生光学非线性效应的机理等;其次,讨论共晶非线性光学材料潜在的应用;最后,对该领域的发展提供了一些展望,希望能为有机共晶与非线性光学领域的同行研究者们提供一定的借鉴参考.     

有机非线性光学

由于有机化合物具有非线性光学系数高、响应快等特点,近年来有机非线性光学研究受到了很大的重视。本文从有机非线性光学材料的结构特点出发,综述了典型的四类有机二阶非线性光学晶体方面的研究进展,对三阶材料也作了简要的介绍。     

中红外波段二阶非线性光学晶体材料研究进展

新型无机红外波段二阶非线性光学晶体材料在光电子领域有着重要的应用，对它们的探索是当前非线性光学材料研究领域的难点和前沿方向之一。本文将材料按组成分成三大类（即经典的ABC₂型黄铜矿结构化合物，硫属元素其他化合物和AMX₃型卤化物），分别就新材料探索、已知材料的单晶生长等综述了近10余年来中红外波段二阶非线性光学晶体材料的研究进展。     

10-烃基吖啶酮的非线性光学活性研究

随着激光技术应用的发展,非线性光学材料的研究不断深人［'j,目前倍频效应和短的截止波长的倍频材料是二阶非线性光学有机材料研究的热点之一L'．现有的非线性光学有机材料,如偶氮苯、共轭烯烃与SChiff碱等类化合物,因分子具有较大的共轭长度使其吸收多处于可见光区,不适合于半导体激光等向蓝紫激光倍频"·"．0'（暖酮含有大。共轭结构,分子两端同时连有吸电子基团。X一0）和推电子基团（＞N-R）而发生分子内的电荷转移,使分子具有非线性光学活性"－·这类化合物结构简单,并有很好的光稳定性,且该类化合物最大紫外吸收在385～40…     

大尺寸有机分子晶体的生长及光电应用

有机分子晶体通过非共价相互作用结合在一起,具有三维长程有序、热力学稳定、缺陷密度低等特点,在有机场效应晶体管、X射线成像、非线性光学、光波导、柔性可穿戴器件和激光器等领域有广阔的应用前景。以往的研究主要是基于有机块状晶体或小尺寸的有机微/纳米晶体,对大尺寸的有机分子晶体研究较少,而实际应用场景往往需要大尺寸的有机分子晶体,如晶体管阵列及电路需要英寸级晶体膜,X射线成像和非线性光学变频需要厘米级晶体。然而,获得高质量大尺寸的有机分子晶体极具挑战,国内外尚未有关于大尺寸有机分子晶体生长与光电性能研究的总结和综述。本文首先介绍了分子晶体的生长机理和生长方法,然后介绍了大尺寸有机分子晶体的材料,接着总结了大尺寸有机分子晶体在长余辉发光、非线性光学、X射线成像、快中子探测、场效应晶体管、光电探测器等光电方面的应用,最后讨论了这一领域存在的挑战并对未来发展进行了展望。     

有机非线性光学晶体NPP的AFM研究

有机二阶非线性光学活性晶体的分子设计和晶体工程是复杂而又引人注目的课题．有机非线性光学晶体N一忡硝基苯基）－LWe脯氨醇（NPP）是一个极为成功的自］子山．由于在＊＊P分子中引入了含手性碳原子和可形成分子间氢键的电子给体脯氨醇，使得其分子跃迁偶极矩与单科P21晶体结构的二重轴之间的夹角为586”．接近于理论优化值（54．74”），因此，＊＊P具有很高的宏观二阶非线性光学活性，其粉末二次谐波强度为尿素的150倍．自1984年首次报导以来，对它的晶体生长门和物理性质已进行了广泛深入的研究．原子力显微镜（＊＊M）能够以极高…     

磷脂酰胆碱LB单分子膜诱导下KDP晶体取向生长的研究

有机超薄膜诱导晶体生长是在化学、物理与生物多门学科相互交融的基础上发展起来的新兴学科 ,并逐渐成为仿生合成的重要分支 [1] .目前的研究重点主要集中于以有机化合物 LB膜作为模板剂诱导生物矿化材料上 [2～ 5] .磷脂 LB膜是生物膜的简化模型体系 [6 ] ,用它作模板剂将使该领域的研究进一步接近生物体系 .对晶体而言 ,修饰晶体材料的特征对于改善和测定材料的光学性能至关重要 [2 ] ,但目前有关上述领域的研究几乎均是空白 .KH2 PO4 ( KDP)晶体是性能优良的非线性光学材料 [7] ,本文首次以磷脂分子 LB膜作为模板剂诱导 KDP的晶化…     

Polymer Optical Fibers and Nonlinear Optical Device Principles

Basic principles of the present optoelectronic research activities at Hoechst AG are presented in this contribution. Within the diversified broad band spectrum of optoelectronic materials and applications our interest is focused on new types of polymer optical fibers and nonlinear optical device principles using organic Langmuir–Blodgett films and electrically poled polymers. The basic principles and the limits of the present research and development activities which have a high market potential are outlined.     

二嗪类有机光电功能材料的应用进展

在过去的几十年里,有机电子学作为一个新兴领域迅猛发展,为科学技术的进步作出了巨大的贡献.有机材料被应用在各种电子器件中,并取得了卓越的成效.作为使用在电子器件中最基本的组分,有机光电材料更是备受瞩目.二嗪类化合物具有优异的光电性能,是光电材料领域最活跃的研究方向之一.两个N原子相对位置的不同,可以构成三种异构体,分别为哒嗪(1,2-二嗪)、嘧啶(1,3-二嗪)和吡嗪(1,4-二嗪),从而有效地调控材料的电子结构,且可以影响二嗪化合物不同位置的修饰,从而得到了广泛关注.本文对近年来二嗪类化合物在光伏材料、薄膜半导体材料、液晶材料、传感材料和电致发光材料等领域的研究进展进行了较全面的总结和评述,指出目前基于二嗪类化合物的光电材料所面临的困难以及未来的发展方向,最后展望了二嗪类化合物作为杂环类有机光电功能材料的应用前景.     

Novel organic materials through control of multichromophore interactions

The function of organic semiconducting and light-harvesting materials depends on the organization of the individual molecular components. Our group has tackled the problem of through-space delocalization via the design and synthesis of bichromphoric pairs held in close proximity by the [2.2]paracyclophane core. The linear and nonlinear optical properties of these molecules provide a challenge to theory. They are also useful in delineating the problem of intermolecular contacts in molecular conductivity measurements. Another area of research described here concerns conjugated polyelectrolytes. These macromolecules combine the properties of organic semiconductors and conventional polyelectrolytes. We have used these materials in the development of optically amplified biosensors and have also incorporated them into organic optoelectronic devices. Of particular interest to us is to derive useful structure/property relationships via molecular design that address important basic scientific problems and technological challenges.     

Dibenzothiophene Sulfone-Based Ambipolar-Transporting Blue-Emissive Organic Semiconductors Towards Simple-Structured Organic Light-Emitting Transistors

The development of blue-emissive ambipolar organic semiconductor is an arduous target due to the large energy gap, but is an indispensable part for electroluminescent device, especially for the transformative display technology of simple-structured organic light-emitting transistor (SS-OLET). Herein, we designed and synthesized two new dibenzothiophene sulfone-based high mobility blue-emissive organic semiconductors (DNaDBSOs), which demonstrate superior optical property with solid-state photoluminescent quantum yield of 46–67 % and typical ambipolar-transporting properties in SS-OLETs with symmetric gold electrodes. Comprehensive experimental and theoretical characterizations reveal the natural of ambipolar property for such blue-emissive DNaDBSOs-based materials is ascribed to a synergistic effect on lowering LUMO level and reduced electron injection barrier induced by the interfacial dipoles effect on gold electrodes due to the incorporation of appropriate DBSO unit. Finally, efficient electroluminescence properties with high-quality blue emission (CIE (0.179, 0.119)) and a narrow full-width at half-maximum of 48 nm are achieved for DNaDBSO-based SS-OLET, showing good spatial control of the recombination zone in conducting channel. This work provides a new avenue for designing ambipolar emissive organic semiconductors by incorporating the synergistic effect of energy level regulation and molecular-metal interaction, which would advance the development of superior optoelectronic materials and their high-density integrated optoelectronic devices and circuits.     

静电纺丝制备有机盐类非线性光学材料纳米纤维

采用静电纺丝技术制备的有机非线性光学材料纳米纤维可有效控制非线性光学材料的分子取向,其生色团可实现与有机单晶类似的优化排列结构,表现出了与纯生色团分子相近的宏观二阶非线性光学性质。 本文将有机盐类非线性光学材料掺杂在聚乙烯吡咯烷酮中制备出了具有各向异性结构且表面光滑、排列有序的纳米纤维薄膜,Kurtz非线性测试结果表明,随着薄膜厚度增加,其二次谐波信号强度成正比增大。     

The chemistry of organic nanomaterials

The development of nanotechnology using organic materials is one of the most intellectually and commercially exciting stories of our times. Advances in synthetic chemistry and in methods for the investigation and manipulation of individual molecules and small ensembles of molecules have produced major advances in the field of organic nanomaterials. The new insights into the optical and electronic properties of molecules obtained by means of single-molecule spectroscopy and scanning probe microscopy have spurred chemists to conceive and make novel molecular and supramolecular designs. Methods have also been sought to exploit the properties of these materials in optoelectronic devices, and prototypes and models for new nanoscale devices have been demonstrated. This Review aims to show how the interaction between synthetic chemistry and spectroscopy has driven the field of organic nanomaterials forward towards the ultimate goal of new technology.     

Organometallic chemistry related to applications for microelectronics in Japan

This is meant to be a brief overview of the developments of research activities in Japan on organometallic compounds related to their use in electronic and optoelectronic devices. The importance of organometallic compounds in the deposition of metal and semiconductor films for the fabrication of many electronic and opto-electronic devices cannot be exaggerated. Their scope has now extended to thin-film electronic ceramics and high-temperature oxide superconductors. A variety of organometallic compounds have been used as source materials in many types of processing procedures, such as metal–organic chemical vapor deposition (MOCVD), metalorganic vapor-phase epitaxy (MOVPE), metal–organic molecular-beam epitaxy (MOMBE), etc. Deposited materials include silicon, Group III–V and II–VI compound semiconductors, metals, superconducting oxides and other inorganic materials. Organometallic compounds are utilized as such in many electronic and optoelectronic devices; examples are conducting and semiconducting materials, photovoltaic, photochromic, electrochromic and nonlinear optical materials. This review consists of two parts: (I) research related to the fabrication of semiconductor, metal and inorganic materials; and (II) research related to the direct use of organometallic materials and basic fundamental research.     

酞菁高分子修饰及其光电性质研究进展

酞菁拥有高度离域的二维18π电子共轭体系、易于调变的分子结构、优良的热和化学稳定性和易于处理加工等特点,可以在很宽的范围内剪裁它们的物理、光电和化学参数,其潜在的巨大应用价值已受到科学与企业界的广泛关注和研究。与[60]富勒烯一样,酞菁分子也可以通过共价键合的方式引入到高分子主链或侧链形成不同类型的高分子,亦可得到诸如酞菁网状高分子和树枝状酞菁大分子等高分子材料;与适宜的高分子材料掺杂或共混能形成含酞菁的高分子复合材料。本文详细地介绍了近年来酞菁高分子修饰与光电性质研究进展。     

Synthesis and Non-linear Optical（NLO） Properties of a Series of Alkoxysilane Derivative Chromophores

1 Introduction Nonlinear optical materials(NLO) have drawn a great intrest of some scholars and scientists in the last dacades because of their tremendous     

Insights into the Control of Optoelectronic Properties in Mixed-Stacking Charge-Transfer Complexes

Although cocrystallization has provided a promising platform to develop new organic optoelectronic materials, it is still a big challenge to purposely design and achieve specific optoelectronic properties. Herein, a series of mixed-stacking cocrystals (TMFA, TMCA, and TMTQ) were designed and synthesized, and the regulatory effects of the acceptors on the co-assembly behavior, charge-transfer nature, energy-level structures, and optoelectronic characteristics were systematically investigated. The results demonstrate that it is feasible to achieve effective charge-transport tuning and photoresponse switching by carefully regulating the intermolecular charge transfer and energy orbitals. The inherent mechanisms underlying the change in these optoelectronic behaviors were analyzed in depth and elucidated to provide clear guidelines for future development of new optoelectronic materials. In addition, due to the excellent photoresponsive characteristics of TMCA, TMCA-based phototransistors were investigated with varying light wavelength and optical power, and TMCA shows the best performance among all reported cocrystals under UV illumination.