索莱尔/首页

<input id="6gmia"></input>
<menu id="6gmia"></menu><input id="6gmia"><u id="6gmia"></u></input>
<menu id="6gmia"><u id="6gmia"></u></menu>
<input id="6gmia"><u id="6gmia"></u></input>
<menu id="6gmia"></menu>
  • <input id="6gmia"><tt id="6gmia"></tt></input><object id="6gmia"><acronym id="6gmia"></acronym></object>
  • <menu id="6gmia"></menu>
    <menu id="6gmia"><u id="6gmia"></u></menu>
  • <menu id="6gmia"></menu>
    <menu id="6gmia"><tt id="6gmia"></tt></menu>
  • <input id="6gmia"></input>
    <input id="6gmia"><u id="6gmia"></u></input>
  • <input id="6gmia"><acronym id="6gmia"></acronym></input>
  • <menu id="6gmia"></menu>
    Home  |  Sitemap  |  Contact Us  |  中文
    Home > News > Content
    Progress in the Circularly Polarized Emission of Organic Helical Polymeric Nanofbers Made
    DateandTime: 2019-10-24 19:55:56

    Chiral structures draw much attention due to their relationship to the polarized light, chiral sensing, and biological structures. Circularly polarized emission (CPE) of chiral materials promotes the development of smart photonic materials for advanced applications in biological systems and information storage. For the CPE, it has been frequently observed in single molecules. Molecular assemblies possess higher levels of CPE performance in comparison with organic single molecules, because the single molecular sizes are much smaller than the helical pitch of circularly polarized light.

    Recently, Prof. Qin Wei et al. have fabricated chiral helical polymeric nanowires to study the orbital angular momentum dependent circularly polarized emission. The results are published in the Advanced Materials with the title of "Magnetic and Electric Control of Circularly Polarized Emission through Tuning Chirality-Generated Orbital Angular Momentum in Organic Helical Polymeric Nanofbers". The first author of the paper is Dr. Wang Zhongxuan, and the corresponding author is Prof. Qin Wei.

    Taking into account the chirality induced orbital angular momentum, spin relaxation time in chiral nw-P3HTs decreases to the level of tens of picosecond, which is comparable to the charge recombination time to lead to an observation of circularly polarized emission. Both the external magnetic fields and electric field are applied to tune the splitting of energy levels to further change the effect of circularly polarized emission.

    In the past two years, the research of organic chiral crystals and magneto-optic effects of co-crystals have been carried out by Qin's group. The related works have been published in Adv. Mater., ACS Nano, Adv. Opt. Mater., APL. The results are supported by the NSFC, Taishan Scholar of Shandong Province, and the Fundamental Funds of Shandong University.

    https://onlinelibrary.wiley.com/doi/abs/10.1002/adma.201904857

    Source: the School of Physics

    Written by: Qin Wei

    Edited by: Xie Tingting




    Copyright 2011 © All rights reserved, Network Center, Shandong University    |    englishweb@sdu.edu.cn
    <input id="6gmia"></input>
    <menu id="6gmia"></menu><input id="6gmia"><u id="6gmia"></u></input>
    <menu id="6gmia"><u id="6gmia"></u></menu>
    <input id="6gmia"><u id="6gmia"></u></input>
    <menu id="6gmia"></menu>
  • <input id="6gmia"><tt id="6gmia"></tt></input><object id="6gmia"><acronym id="6gmia"></acronym></object>
  • <menu id="6gmia"></menu>
    <menu id="6gmia"><u id="6gmia"></u></menu>
  • <menu id="6gmia"></menu>
    <menu id="6gmia"><tt id="6gmia"></tt></menu>
  • <input id="6gmia"></input>
    <input id="6gmia"><u id="6gmia"></u></input>
  • <input id="6gmia"><acronym id="6gmia"></acronym></input>
  • <menu id="6gmia"></menu>

    搜球吧直播

    电竞体育投注

    大发888在线娱乐游戏平台

    意甲盘口丅注

    tt百家乐

    舞帝彩票平台

    8828彩票注册地址

    凤凰福彩app下载

    宏发的彩的网登陆网址网