Doping of Semiconductors at Nanoscale with Microwave Heating (Overview)

Microwave Heating - Electromagnetic Fields Causing Thermal and Non-Thermal Effects Pub Date : 2021-01-11 DOI:10.5772/INTECHOPEN.95558

Sandhya K. M., Litty Thomas Manamel, Bikas C. Das

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引用次数: 2

Abstract

Incorporation of dopants efficiently in semiconductors at the nanoscale is an open challenge and is also essential to tune the conductivity. Typically, heating is a necessary step during nanomaterials’ solution growth either as pristine or doped products. Usually, conventional heating induces the diffusion of dopant atoms into host nanocrystals towards the surface at the time of doped sample growth. However, the dielectric heating by microwave irradiation minimizes this dopant diffusion problem and accelerates precursors’ reaction, which certainly improves the doping yield and reduces processing costs. The microwave radiation provides rapid and homogeneous volumetric heating due to its high penetration depth, which is crucial for the uniform distribution of dopants inside nanometer-scale semiconducting materials. This chapter discusses the effective uses of microwave heating for high-quality nanomaterials synthesis in a solution where doping is necessary to tune the electronic and optoelectronic properties for various applications.

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微波加热纳米级掺杂半导体(综述)

在纳米尺度上，将掺杂剂有效地掺入半导体是一个公开的挑战，也是调整导电性的必要条件。通常，加热是纳米材料溶液生长过程中的必要步骤，无论是作为原始产品还是掺杂产品。通常，传统的加热诱导掺杂原子在掺杂样品生长时向表面扩散到宿主纳米晶体中。然而，微波辐射的介质加热使掺杂扩散问题最小化，并加速了前驱体的反应，从而提高了掺杂收率，降低了加工成本。微波辐射由于其高穿透深度而提供快速均匀的体积加热，这对于纳米级半导体材料内掺杂剂的均匀分布至关重要。本章讨论了微波加热在溶液中合成高质量纳米材料的有效用途，在溶液中需要掺杂以调整各种应用的电子和光电子性质。

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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Microwave Heating - Electromagnetic Fields Causing Thermal and Non-Thermal Effects

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