Enhanced cryogenic thermoelectric cooling of Bi0.5Sb1.5Te3 by carrier optimization

Xuemei Wang , Zhiwei Chen , Shuxian Zhang , Xinyue Zhang , Rui Zhou , Wen Li , Jun Luo , Yanzhong Pei

InfoMat ›› 2025, Vol. 7 ›› Issue (5) : e12663

PDF
InfoMat ›› 2025, Vol. 7 ›› Issue (5) : e12663 DOI: 10.1002/inf2.12663
RESEARCH ARTICLE

Enhanced cryogenic thermoelectric cooling of Bi0.5Sb1.5Te3 by carrier optimization

Author information +
History +
PDF

Abstract

As the best-performing materials for thermoelectric cooling, Bi2Te3-based alloys have long attracted attention to optimizing the room-temperature performance of Bi2Te3 for both power generation and refrigeration applications. This focus leads to less emphasis and fewer reports on the cooling capability below room temperature. Given that the optimal carrier concentration (nopt) for maximizing the cooling power is highly temperature dependent, roughly following the relationship noptT3/2, lowering the carrier concentration is essential to improve the cooling capability at cryogenic temperatures. Taking p-type Bi0.5Sb1.5Te3 as an example, careful control of doping in this work enables a reduction in carrier concentration to 1.7 × 1019 cm–3 from its optimum at 300 K of 3.4 × 1019 cm–3. This work successfully shifts the temperature at which the thermoelectric figure of merit (zT) peaks down to 315 K, with an average zT as high as 0.8 from 180 to 300 K. Further pairing with commercial n-type Bi2Te3-alloys, the cooling device realizes a temperature drop as large as 68 K from 300 K and 24 K from 180 K, demonstrating the extended cooling capability of thermoelectric coolers at cryogenic temperatures.

Keywords

carrier optimization / cryogenic thermoelectric performance / p-type Bi2Te3 / thermoelectric / thermoelectric cooling

Cite this article

Download citation ▾
Xuemei Wang, Zhiwei Chen, Shuxian Zhang, Xinyue Zhang, Rui Zhou, Wen Li, Jun Luo, Yanzhong Pei. Enhanced cryogenic thermoelectric cooling of Bi0.5Sb1.5Te3 by carrier optimization. InfoMat, 2025, 7(5): e12663 DOI:10.1002/inf2.12663

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Ioffe AF, Stil'bans LS, Iordanishvili EK, Stavitskaya TS, Gelbtuch A, Vineyard G. Semiconductor thermoelements and thermoelectric cooling. Phys Today. 1959; 12(5): 42.
[2]

Goldsmid HJ, Douglas RW. The use of semiconductors in thermoelectric refrigeration. Br J Appl Phys. 1954; 5(11): 386-390.
[3]

Bell LE. Cooling, heating, generating power, and recovering waste heat with thermoelectric systems. Science. 2008; 321(5895): 1457-1461.
[4]

Mao J, Chen G, Ren Z. Thermoelectric cooling materials. Nat Mater. 2020; 20(4): 454-461.
[5]

DiSalvo FJ. Thermoelectric cooling and power generation. Science. 1999; 285(5428): 703-706.
[6]

White WC. Some experiments with peltier effect. Electr Eng. 1951; 70(7): 589-591.
[7]

Liu M, Zhang X, Zhang S, Pei Y. Ag2Se as a tougher alternative to n-type Bi2Te3 thermoelectrics. Nat Commun. 2024; 15(1): 6587.
[8]

Liu Z, Gao W, Oshima H, Nagase K, Lee CH, Mori T. Maximizing the performance of n-type Mg3Bi2 based materials for room-temperature power generation and thermoelectric cooling. Nat Commun. 2022; 13(1): 1120.
[9]

Imasato K, Kang SD, Snyder GJ. Exceptional thermoelectric performance in Mg3Sb0.6Bi1.4 for low-grade waste heat recovery. Energy Environ Sci. 2019; 12(3): 965-971.
[10]

Chung D-Y, Hogan T, Brazis P, et al. CsBi4Te6: a high-performance thermoelectric material for low-temperature applications. Science. 2000; 287(5455): 1024-1027.
[11]

Liu Z, Mao J, Sui J, Ren Z. High thermoelectric performance of α-MgAgSb for power generation. Energy Environ Sci. 2018; 11(1): 23-44.
[12]

Qin B, Wang D, Liu X, et al. Power generation and thermoelectric cooling enabled by momentum and energy multiband alignments. Science. 2021; 373(6554): 556-561.
[13]

Yadam S, Singh D, Venkateshwarlu D, Gangrade MK, Samatham SS, Ganesan V. Enhancement in thermoelectric power of Ce(Ni1−xCux)2Al3: an implication of two-band conduction. Phys Status Solidi B. 2014; 252(3): 502-507.
[14]

Huang B-L, Kaviany M. Ab initioand molecular dynamics predictions for electron and phonon transport in bismuth telluride. Phys Rev B. 2008; 77(12): 125209.
[15]

Kim H-S, Heinz NA, Gibbs ZM, Tang Y, Kang SD, Snyder GJ. High thermoelectric performance in (Bi0.25Sb0.75)2Te3 due to band convergence and improved by carrier concentration control. Mater Today. 2017; 20(8): 452-459.
[16]

Yang G, Niu R, Sang L, et al. Ultra-high thermoelectric performance in bulk BiSbTe/amorphous boron composites with nano-defect architectures. Adv Energy Mater. 2020; 10(41): 2000757.
[17]

Hao F, Qiu P, Tang Y, et al. High efficiency Bi2Te3-based materials and devices for thermoelectric power generation between 100 and 300 °C. Energy Environ Sci. 2016; 9(10): 3120-3127.
[18]

El-Makaty FM, Ahmed HK, Youssef KM. Review: the effect of different nanofiller materials on the thermoelectric behavior of bismuth telluride. Mater Des. 2021; 209: 109974.
[19]

Poudel B, Hao Q, Ma Y, et al. High-thermoelectric performance of nanostructured bismuth antimony telluride bulk alloys. Science. 2008; 320(5876): 634-638.
[20]

Sun Y, Wu H, Dong X, et al. High performance BiSbTe alloy for superior thermoelectric cooling. Adv Funct Mater. 2023; 33(28): 2301423.
[21]

Xu Z, Wu H, Zhu T, et al. Attaining high mid-temperature performance in (Bi,Sb)2Te3 thermoelectric materials via synergistic optimization. NPG Asia Mater. 2016; 8(9): e302.
[22]

Kim SI, Lee KH, Mun HA, et al. Dense dislocation arrays embedded in grain boundaries for high-performance bulk thermoelectrics. Science. 2015; 348(6230): 109-114.
[23]

Shi X-L, Zou J, Chen ZG. Advanced thermoelectric design: from materials and structures to devices. Chem Rev. 2020; 120(15): 7399-7515.
[24]

Yim WM, Fitzke EV, Rosi FD. Thermoelectric properties of Bi2Te3-Sb2Te3-Sb2Se3 pseudo-ternary alloys in the temperature range 77 to 300 K. J Mater Sci. 1966; 1(1): 52-65.
[25]

Ivanova LD, Granatkina YV. Thermoelectric properties of Bi2Te3-Sb2Te3 single crystals in the range 100-700 K. Inorg Mater. 2000; 36(7): 672-677.
[26]

Zhu T, Xu Z, He J, et al. Hot deformation induced bulk nanostructuring of unidirectionally grown p-type (Bi,Sb)2Te3 thermoelectric materials. J Mater Chem A. 2013; 1(38): 11589.
[27]

Zhang X, Bu Z, Shi X, et al. Electronic quality factor for thermoelectrics. Sci Adv. 2020; 6(46): eabc0726.
[28]

Witting IT, Chasapis TC, Ricci F. The Thermoelectric Properties of Bismuth Telluride. Adv Electron Mater. 2019; 5(6): 1970030.
[29]

Pei Y, LaLonde AD, Heinz NA, et al. Stabilizing the optimal carrier concentration for high thermoelectric efficiency. Adv Mater. 2011; 23(47): 5674-5678.
[30]

Li H, Feng J, Zhao L, et al. Hierarchical low-temperature n-type Bi2Te3 with high thermoelectric performances. ACS Appl Mater Interfaces. 2024; 16(17): 22147-22154.
[31]

Huang H, Li J, Chen S, et al. Anisotropic thermoelectric transport properties of Bi0.5Sb1.5Te2.96+x zone melted ingots. J Solid State Chem. 2020; 288: 121433.
[32]

Zhai R-S, Wu YH, Zhu TJ, Zhao XB. Thermoelectric performance of p-type zone-melted Se-doped Bi0.5Sb1.5Te3 alloys. Rare Metals. 2018; 37(4): 308-315.
[33]

Fu K, Yu J, Wang B, et al. Recovery and thermoelectric performance optimization of p-type bismuth telluride waste by secondary zone-melting. J Mater Sci Mater Electron. 2024; 35(5): 319.
[34]

Wu G, Zhang Q, Fu Y, et al. High-efficiency thermoelectric module based on high-performance Bi0.42Sb1.58Te3 materials. Adv Funct Mater. 2023; 33(47): 2305686.
[35]

Deng R, Su X, Hao S, et al. High thermoelectric performance in Bi0.46Sb1.54Te3 nanostructured with ZnTe. Energy Environ Sci. 2018; 11(6): 1520.
[36]

Zhuang H-L, Hu H, Pei J, et al. High ZT in p-type thermoelectric (Bi,Sb)2Te3 with built-in nanopores. Energ Environ Sci. 2022; 15(5): 2039-2048.
[37]

Li S, Peng C, Wang C, et al. In situ generation of flower-like and microspherical dendrites to improve thermoelectric properties of p-type Bi0.46Sb1.54Te3. Mater Today Phys. 2022; 23: 100633.
[38]

Bano S, Misra DK, Bharti P, Kumar A, Govind B, Bhardwaj A. Enhanced thermoelectric performance at elevated temperature via suppression of intrinsic excitation in p-type Bi0.5−xSnxSb1.5Te3 thermoelectric material. J Mater Sci Mater Electron. 2022; 33(8): 6018-6030.
[39]

Zhao L, Qiu W, Sun Y, et al. Enhanced thermoelectric performance of Bi0.3Sb1.7Te3 based alloys by dispersing TiC ceramic nanoparticles. J Alloy Compd. 2021; 863: 158376.
[40]

Qin H, Zhang Y, Cai S, et al. Critical role of tellurium self-compensation in enhancing the thermoelectric performance of p-type Bi0.4Sb1.6Te3 alloy. Chem Eng J. 2021; 425: 130670.
[41]

Li YY, Qin XY, Li D, et al. Enhanced thermoelectric performance of Cu2Se/Bi0.4Sb1.6Te3 nanocomposites at elevated temperatures. Appl Phys Lett. 2016; 108(6): 062104.
[42]

Li Y, Wang X, Liu G, Shin B, Shan F. High thermoelectric efficiency of p-type BiSbTe-based composites with CuGaTe2 nanoinclusions. Scripta Mater. 2019; 172: 88-92.
[43]

Liang H, Lou Q, Zhu YK, et al. Highly enhanced thermoelectric and mechanical properties of Bi-Sb-Te compounds by carrier modulation and microstructure adjustment. ACS Appl Mater Interfaces. 2021; 13(38): 45589-45599.
[44]

Jiang Z, Ming H, Qin X, et al. Achieving high thermoelectric performance in p-type BST/PbSe nanocomposites through the scattering engineering strategy. ACS Appl Mater Interfaces. 2020; 12(41): 46181-46189.
[45]

Xiao Y, Chen G, Qin H, et al. Enhanced thermoelectric figure of merit in p-type Bi0.48Sb1.52Te3 alloy with WSe2 addition. J Mater Chem A. 2014; 2(22): 8512.
[46]

Yang G, Sang L, Yun FF, et al. Significant enhancement of thermoelectric figure of merit in BiSbTe-based composites by incorporating carbon microfiber. Adv Funct Mater. 2021; 31(15): 2008851.
[47]

Qin H, Liu Y, Zhang Z, et al. Improved thermoelectric performance of p-type Bi0.5Sb1.5Te3 through Mn doping at elevated temperature. Mater Today Phys. 2018; 6: 31-37.
[48]

Hu L, Meng F, Zhou Y, et al. Leveraging deep levels in narrow bandgap Bi0.5Sb1.5Te3 for record-high zTave near room temperature. Adv Funct Mater. 2020; 30(45): 2005202.
[49]

Xing T, Liu R, Hao F, et al. Suppressed intrinsic excitation and enhanced thermoelectric performance in AgxBi0.5Sb1.5−xTe3. J Mater Chem C. 2017; 5(47): 12619-12628.
[50]

Tan C, Tan X, Yu B, et al. Synergistically optimized thermoelectric performance in Bi0.48Sb1.52Te3 by hot deformation and Cu doping. ACS Appl Energy Mater. 2019; 2(9): 6714-6719.
[51]

Li C, Ma S, Wei P, et al. Magnetism-induced huge enhancement of the room-temperature thermoelectric and cooling performance of p-type BiSbTe alloys. Energy Environ Sci. 2020; 13(2): 535-544.
[52]

Hao F, Xing T, Qiu P, et al. Enhanced thermoelectric performance in n-type Bi2Te3-based alloys via suppressing intrinsic excitation. ACS Appl Mater Interfaces. 2018; 10(25): 21372-21380.
[53]

Mao J, Zhu H, Ding Z, et al. High thermoelectric cooling performance of n-type Mg3Bi2-based materials. Science. 2019; 365(6452): 495-498.
[54]

Ying P, Wilkens L, Reith H, et al. A robust thermoelectric module based on MgAgSb/Mg3(Sb,Bi)2 with a conversion efficiency of 8.5% and a maximum cooling of 72 K. Energy Environ Sci. 2022; 15(6): 2557-2566.
[55]

Yang J, Li G, Zhu H, et al. Next-generation thermoelectric cooling modules based on high-performance Mg3(Bi,Sb)2 material. Joule. 2022; 6(1): 193-204.
[56]

Liang K, Yang H, Zhao P, et al. Characterizing the thermoelectric cooling performance across a broad temperature range. Rev Sci Instrum. 2023; 94(10): 105112.
[57]

Zhou W, Pang K, Zhang Z, et al. Optimized thermoelectric cooler performance by the structure-matching Design of Asymmetrical p/n-type legs. ACS Appl Mater Interfaces. 2023; 15(48): 56064-56071.
[58]

Chen N, Zhu H, Li G, et al. Improved figure of merit (z) at low temperatures for superior thermoelectric cooling in Mg3(Bi,Sb)2. Nat Commun. 2023; 14(1): 4932.
[59]

Zhang Q, Wu G, Guo Z, et al. Enhanced thermoelectric and mechanical performances in sintered Bi0.48Sb1.52Te3-AgSbSe2 composite. ACS Appl Mater Interfaces. 2021; 13(21): 24937-24944.
[60]

Wang X, Wu G, Cai J, et al. Unusually high Seebeck coefficient arising from temperature-dependent carrier concentration in PbSe-AgSbSe2 alloys. J Mater Chem C. 2021; 9(48): 17365-17370.
[61]

Zhou J, Chen Z, Luo J, Li W, Pei Y. Gradient doping enables an extraordinary efficiency in thermoelectric PbTe1−xIx. Adv Mater. 2024; 36(31): 2405299.
[62]

Lin S, Li W, Chen Z, Shen J, Ge B, Pei Y. Tellurium as a high-performance elemental thermoelectric. Nat Commun. 2016; 7(1): 10287.
[63]

Meng Y, Wang X, Zhang S, Chen Z, Pei Y. Single- and two-band transport properties crossover in Bi2Te3 based thermoelectrics. J Inorg Mater. 2024; 39(11): 1283.
[64]

Zhang S, Wang X, Bai Q, et al. Measuring lattice thermal conductivity of Bi1-Sb enabled by external magnetic field. Mater Today Phys. 2024; 45: 101460.

RIGHTS & PERMISSIONS

2025 The Author(s). InfoMat published by UESTC and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF

3

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/