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人工晶体学报 ›› 2026, Vol. 55 ›› Issue (6): 858-866.DOI: 10.16553/j.cnki.issn1000-985x.2026.0022

• 研究论文 • 上一篇    下一篇

Cd掺杂InSb晶体生长及热电性能研究

师千惠1(), 陈浩1, 林思琪1(), 岳晓飞1, 刘学超2, 金敏1,2,3()   

  1. 1.上海电机学院材料学院,上海 201306
    2.中国科学院上海硅酸盐研究所,功能晶体与器件国家重点实验室,上海 200050
    3.乌镇实验室,桐乡 314500
  • 收稿日期:2026-02-10 出版日期:2026-06-20 发布日期:2026-07-07
  • 通信作者: 林思琪,博士,教授。E-mail:linsq@sdju.edu.cn
    金 敏,博士,教授。E-mail:jmaish@aliyun.com
  • 作者简介:师千惠(2000—),女,山西省人,硕士研究生。E-mail:2421380095@qq.com
  • 基金资助:
    国家自然科学基金(52371193);国家自然科学基金(52272006);上海市优秀学术带头人(23XD1421200);上海启明星计划(23QA1403900);上海市东方学者计划(TP2022122);浙江省自然科学基金(LD25E020001);中国科学院上海硅酸盐研究所功能晶体与器件国家重点实验室开放项目(SKLFCD202505SIC)

Growth and Thermoelectric Properties of Cd-Doped InSb Crystals

SHI Qianhui1(), CHEN Hao1, LIN Siqi1(), YUE Xiaofei1, LIU Xuechao2, JIN Min1,2,3()   

  1. 1.College of Materials,Shanghai Dianji University,Shanghai 201306,China
    2.State Key Laboratory of Functional Crystals and Devices,Shanghai Institute of Ceramics,Chinese Academy of Sciences,Shanghai 200050,China
    3.Wuzhen Laboratory,Tongxiang 314500,China
  • Received:2026-02-10 Online:2026-06-20 Published:2026-07-07

摘要: InSb晶体作为一种重要的III-V族窄带隙化合物半导体材料,在红外探测与成像、磁阻传感及高速电子器件等领域具有广泛应用。为进一步探索InSb晶体物理性能的多样性,本文致力于研究该晶体在热电转换领域的应用潜力。本工作采用坩埚下降法分别生长了InSb、In0.99Cd0.01Sb、In0.9Cd0.1Sb三种晶体。拉曼光谱分析表明,随着Cd掺杂浓度的增加,InSb晶体的本征峰发生了红移。Cd掺杂导致晶体导电类型由N型转变为P型,这主要归因于Cd取代In位引入了更多空穴载流子。通过Cd元素掺杂,InSb样品在最高温723 K时的热电功率因子从8.8 μW·cm-1·K-2提升至12.7 μW·cm-1·K-2。此外,由于Cd元素引入缺陷散射,样品热导率随Cd掺杂浓度升高出现显著下降,In0.9Cd0.1Sb晶体的室温热导率降低至8.8 W·m-1·K-1,在723 K时低至3.4 W·m-1·K-1。In0.9Cd0.1Sb晶体在723 K时热电优值zT取得最大值0.19。力学测试表明,Cd掺杂浓度升高会导致晶体最大压痕深度减小,硬度从2.95 GPa提高到3.15 GPa,弹性模量从56.36 GPa提高到73.54 GPa。本工作说明Cd掺杂InSb晶体在中温区具有潜在的热电应用价值。

关键词: InSb晶体; Cd掺杂; 坩埚下降法; 热电性能; 力学性能

Abstract: As an important group III-V narrow bandgap compound semiconductor,InSb crystals have been widely used in infrared detection and imaging,magnetoresistive sensing and high-speed electronic devices owing to their excellent optoelectronic and transport properties. Thermoelectric technology enables direct conversion between heat and electricity based on the Seebeck and Peltier effects. Despite their mature applications in traditional electronic fields,the potential of InSb crystals in thermoelectric energy conversion has not been fully explored. Therefore,optimizing the thermoelectric property of InSb via elemental doping is of great significance. This work systematically investigates the growth,crystal structure,thermoelectric property,and mechanical properties of Cd-doped InSb crystals. Three types of crystals,including InSb,In0.99Cd0.01Sb,and In0.9Cd0.1Sb,were grown by the Bridgman method. X-ray diffraction (XRD) analysis shows that the powder diffraction patterns agree well with the standard data,confirming a cubic zinc-blende structure with a space group of F43m. XRD pattern of the cleaved surface exhibits a single diffraction peak corresponding to the (220) plane,indicating excellent single-crystal characteristics. Scanning electron microscopy combined with energy-dispersive spectroscopy mapping confirms the homogeneous distribution of In,Sb,and doped Cd elements within the crystals. Raman spectroscopy reveals that the characteristic peaks of InSb exhibit a gradual redshift with increasing Cd doping concentration,further confirming the effective incorporation of Cd into the InSb lattice. Cd doping also induces a transition in the conduction type from N-type to P-type,which is mainly attributed to the introduction of hole carriers via Cd substitution at In sites. The pristine InSb crystal exhibits a power factor of 0.43 μW·cm-1·K-2 at room temperature. Upon Cd doping,the room-temperature power factor is significantly enhanced,reaching 5.9 and 5.2 μW·cm-1·K-2 for the In0.99Cd0.01Sb and In0.9Cd0.1Sb crystals,respectively. At 723 K,the thermoelectric power factor of the InSb sample increases from 8.8 μW·cm-1·K-2 to 12.7 μW·cm-1·K-2 by Cd doping. Meanwhile,defect scattering introduced by Cd incorporation enhances phonon scattering,leading to a significant reduction in thermal conductivity with increasing Cd concentration. The intrinsic InSb crystal exhibits a room-temperature thermal conductivity of 16.4 W·m-1·K-1. The thermal conductivity decreases to 8.8 W·m-1·K-1 for the In0.9Cd0.1Sb crystal at room temperature and further decreases to 3.4 W·m-1·K-1 at 723 K. Due to the synergistic optimization of the electrical and thermal transport properties induced by Cd doping,a thermoelectric figure of merit (zT) of 0.19 is achieved at 723 K in the In0.9Cd0.1Sb crystal,representing an enhancement of approximately 46% compared to that of the pristine InSb crystal. Mechanical testing indicates that an increase in Cd doping concentration leads to a reduction in the maximum indentation depth of the crystal,with the hardness increasing from 2.95 GPa to 3.15 GPa and the elastic modulus increasing from 56.36 GPa to 73.54 GPa. This work provides a feasible doping strategy for improving the thermoelectric performance of InSb crystals and demonstrates that Cd-doped InSb exhibits promising potential for thermoelectric applications in the medium-temperature range.

Key words: InSb crystal; Cd doping; Bridgman method; thermoelectric property; mechanical property

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