Colloidal quantum dots for mid-infrared detection (Presentation Recording)

P. Guyot-Sionnest
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Abstract

Colloidal quantum dots present an opportunity as infrared and liquid processed materials. Initial results in 2011 showed mid-infrared detection with HgTe colloidal quantum dots in the mi-IR range, 3-5 microns. This has been now extended to the long-wave IR, 8-12 microns. The infrared response from the HgTe colloidal quantum dots arises from the absorption of light across the gap created by the confinement. The large dots absorbing the LWIR are about 20 nm in size and the size dispersion will need improvements. While Interband absorption requires the material to be zero or small-gap semiconductors, intraband transitions have no such limitations. However, this requires doped colloidal quantum dots. Two colloidal quantum dot materials, the small gap (0.6 eV) b-HgS and the zero-gap HgSe turn out to be stably doped with electrons. This has led to the observation of Mid-IR intraband photoconduction in both systems and alternative materials for IR detection. There are several basic challenges, besides fabrication and reliability. The proximity of the surface from the excitation leads to very short excited lifetimes due to nonradiative processes. Controlling the surface will be the avenue to lengthen the lifetime, while plasmonic coupling may lead to shorter radiative lifetime. Since the surface is easily chemically modified, it also leads to strong changes in the Fermi level and this will need to be controlled. In this talk, I will describe my understanding of the potential and limitations of this material approach to infrared detection, while discussing aspects of transport, photoluminescence, doping and photovoltaic responses.
用于中红外探测的胶体量子点(演示记录)
胶体量子点为红外和液体加工材料提供了机会。2011年的初步结果显示,在3-5微米的中红外范围内,HgTe胶体量子点可以进行中红外探测。现在已经扩展到长波IR, 8-12微米。HgTe胶体量子点的红外响应来自于通过限制产生的间隙吸收光。吸收LWIR的大点尺寸约为20 nm,尺寸分散有待改进。而带间吸收要求材料为零隙或小隙半导体,带内跃迁没有这样的限制。然而,这需要掺杂胶体量子点。两种胶体量子点材料,小间隙(0.6 eV)的b-HgS和零间隙的HgSe被证明是稳定掺杂电子的。这导致观察中红外带内光导在系统和替代材料的红外检测。除了制造和可靠性之外,还有几个基本的挑战。由于非辐射过程,表面离激发的接近导致激发寿命非常短。控制表面是延长辐射寿命的途径,而等离子体耦合可能导致辐射寿命缩短。由于表面很容易被化学修饰,它也会导致费米能级的强烈变化,这需要加以控制。在这次演讲中,我将描述我对这种材料方法用于红外探测的潜力和局限性的理解,同时讨论传输,光致发光,掺杂和光伏响应等方面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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