[1] T J ZHU, Y T LIU, C G FU et al. Compromise and synergy in high-efficiency thermoelectric materials. Advanced Materials, 29(2017).

[2] H WANG, A D LALONDE, Y Z PEI et al. The criteria for beneficial disorder in thermoelectric solid solutions. Advanced Functional Materials, 23(2013).

[3] M HONG, Z G CHEN, L YANG et al. Realizing ZT of 2.3 in Ge_1-x-ySb_xIn_yTe via reducing the phase-transition temperature and introducing resonant energy doping. Advanced Materials, 30(2018).

[4] Y M ZHOU, L D ZHAO. Promising thermoelectric bulk materials with 2D structures. Advanced Materials, 29(2017).

[5] H J SU, Z C MIAO, Y PENG et al. SnTe thermoelectric materials with low lattice thermal conductivity synthesized by a self- propagating method under a high-gravity field. Physical Chemistry Chemical Physics, 24(2022).

[6] L D ZHAO, S Q HAO, S H LO et al. High thermoelectric performance via hierarchical compositionally alloyed nanostructures. Journal of American Chemistry Society, 135(2013).

[7] A BANIK, B VISHAL, S PERUMAL et al. The origin of low thermal conductivity in Sn_1-xSb_xTe: phonon scattering via layered intergrowth nanostructures. Energy & Environmental Science, 9, 2011(2016).

[8] X SHI, J YANG, J R SALVADOR et al. Multiple-filled skutterudites: high thermoelectric figure of merit through separately optimizing electrical and thermal transports. Journal of American Chemistry Society, 133(2011).

[9] H L LIU, X SHI, L L ZHANG et al. Copper ion liquid-like thermoelectrics. Nature Materials, 11(2012).

[10] R H LIU, H Y CHEN, K P ZHAO et al. Entropy as a gene-like performance indicator promoting thermoelectric materials. Advanced Materials, 29(2017).

[11] Z W CHEN, Z Z JIAN, W LI et al. Lattice dislocations enhancing thermoelectric PbTe in addition to band convergence. Advanced Materials, 29(2017).

[12] Y Z PEI, Z M GIBBS, A GLOSKOVSKII et al. Optimum carrier concentration in n-type PbTe thermoelectrics. Advanced Energy Materials, 4(2014).

[13] W LI, L L ZHENG, B H GE et al. Promoting SnTe as an eco- friendly solution for p-PbTe thermoelectric via band convergence and interstitial defects. Advanced Materials, 29(2017).

[14] J TANG, Z YAO, Z CHEN et al. Maximization of transporting bands for high-performance SnTe alloy thermoelectrics. Materials Today Physics, 9, 100091(2019).

[15] Q H JIANG, H S HU, J Y YANG et al. High thermoelectric performance in SnTe nanocomposites with all-scale hierarchical structures. ACS Applied Materials & Interfaces, 12(2020).

[16] H J WU, C CHANG, D FENG et al. Synergistically optimized electrical and thermal transport properties of SnTe via alloying high- solubility MnTe. Energy & Environmental Science, 8(2015).

[17] X J TAN, H Z SHAO, J HE et al. Band engineering and improved thermoelectric performance in M-doped SnTe (M = Mg, Mn, Cd, and Hg). Physical Chemistry Chemical Physics, 18(2016).

[18] G J TAN, F Y SHI, J W DOAK et al. Extraordinary role of Hg in enhancing the thermoelectric performance of p-type SnTe. Energy & Environmental Science, 8(2015).

[19] G J TAN, F Y SHI, S Q HAO et al. Codoping in SnTe: enhancement of thermoelectric performance through synergy of resonance levels and band convergence. Journal of American Chemistry Society, 137(2015).

[20] Y Z PEI, L L ZHENG, W LI et al. Interstitial point defect scattering contributing to high thermoelectric performance in SnTe. Advanced Electronic Materials, 2(2016).

[21] L D ZHAO, X ZHANG, H J WU et al. Enhanced thermoelectric properties in the counter-doped SnTe system with strained endotaxial SrTe. Journal of American Chemistry Society, 138(2016).

[22] P X WEI, C E LIAO, H A WU et al. Thermodynamic routes to ultralow thermal conductivity and high thermoelectric performance. Advanced Materials, 32(2020).

[23] S SHAFEIE, S GUO, Q HU et al. High-entropy alloys as high-temperature thermoelectric materials. Journal of Applied Physics, 118(2015).

[24] L HU, Y ZHANG, H WU et al. Entropy engineering of SnTe: multi-principal-element alloying leading to ultralow lattice thermal conductivity and state-of-the-art thermoelectric performance. Advanced Energy Materials, 8, 1802116(2018).

[25] Y Z PEI, A D LALONDE, H WANG et al. Low effective mass leading to high thermoelectric performance. Energy & Environmental Science, 5(2012).

[26] R BLACHNIK, R IGEL. Thermodynamic properties of IV-VI compounds lead chalcogenides. Zeitschrift Fur Naturforschung B, 29(1974).

[27] Q ZHANG, Z GUO, R Y WANG et al. High-performance thermoelectric material and module driven by medium-entropy engineering in SnTe. Advanced Functional Materials, 32(2022).

[28] H J SU, Y M HAN, L C XIE et al. Fast fabrication of SnTe via a non-equilibrium method and enhanced thermoelectric properties by medium-entropy engineering. Journal of Materials Chemistry C, 11(2023).

[29] H S KIM, Z M GIBBS, Y TANG et al. Characterization of Lorenz number with Seebeck coefficient measurement. APL Materials, 3(2015).

[30] Q YANG, P QIU, X SHI et al. Application of entropy engineering in thermoelectrics. Journal of Inorganic Materials, 36(2021).

[31] Y M KIM, K CHUNG, J YOO et al. Effect of fine boron powders prepared with a self-propagating high temperature synthesis on flux pinning properties of the MgB₂/Fe composite wires. Journal of Alloys and Compounds, 485(2009).

[32] L J WANG, S Y CHANG, S Q ZHENG et al. Thermoelectric performance of Se/Cd codoped SnTe via microwave solvothermal method. ACS Applied Materials Interfaces, 9(2017).

[33] S ROYCHOWDHURY, R K BISWAS, M DUTTA. Phonon localization and entropy-driven point defects lead to ultralow thermal conductivity and enhanced thermoelectric performance in (SnTe)_1-2x(SnSe)_x(SnS)_x. ACS Energy Letters, 4(2019).