Inhibition of Lattice Thermal Conductivity of ZrNiSn-based Half-Heusler Thermoelectric Materials by Entropy Adjustment

Pengjiang WANG; Huijun KANG; Xiong YANG; Ying LIU; Cheng CHENG; Tongmin WANG

doi:10.15541/jim20210610

[1] Z Y CHEN, B GAO, J TANG et al. Low lattice thermal conductivity by alloying SnTe with AgSbTe₂ and CaTe/MnTe. Applied Physics Letters(2019).

[2] A S GLEN. New Materials and Performance Limits for Thermoelectric Cooling. CRC Handbook of Thermoelectrics(1995).

[3] G J SNYDER, E S TOBERER. Complex thermoelectric materials. Nature Materials, 105-114(2008).

[4] C CHANG, M H WU, D S HE et al. 3D charge and 2D phonon transports leading to high out-of-plane ZT in n-type SnSe crystals. Science, 778-782(2018).

[5] J LI, Y WANG, X YANG et al. Processing bulk insulating CaTiO₃ into a high-performance thermoelectric material. Chemical Engineering Journal(2022).

[6] Y MA, R HEIJL, A E C PALMQVIST. Composite thermoelectric materials with embedded nanoparticles. Journal of Materials Science, 2767-2778(2013).

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

[8] T FANG, S Q ZHENG, T ZHOU et al. Computational prediction of high thermoelectric performance in p-type half-Heusler compounds with low band effective mass. Physical Chemistry Chemical Physics, 4411-4417(2017).

[9] J P A MAKONGO, D K MISRA, X Y ZHOU et al. Simultaneous large enhancements in thermopower and electrical conductivity of bulk nanostructured half-Heusler alloys. Journal of the American Chemical Society, 18843-18852(2011).

[10] K GALAZKA, W J XIE, S POPULOH et al. Tailoring thermoelectric properties of Zr_0.43Hf_0.57NiSn half-Heusler compound by defect engineering. Rare Metals, 659-670(2020).

[11] J W G BOS, R A DOWNIE. Half-Heusler thermoelectrics: a complex class of materials. Journal of Physics-Condensed Matter(2014).

[12] T J ZHU, C G FU, H H XIE et al. High efficiency half-Heusler thermoelectric materials for energy harvesting. Advanced Energy Materials(2015).

[13] Y F LIU, P SAHOO, J P A MAKONGO et al. Large enhancements of thermopower and carrier mobility in quantum dot engineered bulk semiconductors. Journal of the American Chemical Society, 7486-7495(2013).

[14] H A R ALIABAD, Z NODEHI, B MALEKI et al. Electronical and thermoelectric properties of half-Heusler ZrNiPb under pressure in bulk and nanosheet structures for energy conversion. Rare Metals, 1015-1023(2019).

[15] T GRAF, C FELSER, S S P PARKIN. Simple rules for the understanding of Heusler compounds. Progress in Solid State Chemistry, 1-50(2011).

[16] X YANG, D Q LIU, J B LI et al. Top-down method to fabricate TiNi₁₊_xSn half-Heusler alloy with high thermoelectric performance. Journal of Materials Science & Technology, 39-45(2021).

[17] X YANG, Z JIANG, H J KANG et al. Enhanced thermoelectric performance of Zr_1-_xTa_xNiSn half-Heusler alloys by diagonal-rule doping. ACS Applied Materials Interfaces, 3773-3783(2020).

[18] J L YAN, F S LIU, G H MA et al. Suppression of the lattice thermal conductivity in NbFeSb-based half-Heusler thermoelectric materials through high entropy effects. Scripta Materialia, 129-134(2018).

[19] Q SHEN, L CHEN, T GOTO et al. Effects of partial substitution of Ni by Pd on the thermoelectric properties of ZrNiSn-based half-Heusler compounds. Applied Physics Letters, 4165-4167(2001).

[20] X YANG, Z JIANG, J B LI et al. Identification of the intrinsic atomic disorder in ZrNiSn-based alloys and their effects on thermoelectric properties. Nano Energy(2020).

[21] M SCHWALL, B BALKE. Phase separation as a key to a thermoelectric high efficiency. Physical Chemistry Chemical Physics, 1868-1872(2013).

[22] W J XIE, A WEIDENKAFF, X F TANG et al. Recent advances in nanostructured thermoelectric half-Heusler compounds. Nanomaterials- Basel, 379-412(2012).

[23] Y T LIU, H H XIE, C G FU et al. Demonstration of a phonon-glass electron-crystal strategy in (Hf,Zr)NiSn half-Heusler thermoelectric materials by alloying. Journal of Materials Chemistry A, 22716-22722(2015).

[24] H H XIE, H WANG, Y Z PEI et al. Beneficial contribution of alloy disorder to electron and phonon transport in half-Heusler thermoelectric materials. Advanced Functional Materials, 5123-5130(2013).

[25] O N SENKOV, J D MILLER, D B MIRACLE et al. Accelerated exploration of multi-principal element alloys with solid solution phases. Nature Communications(2015).

[26] Y ZHANG, T T ZUO, Z TANG et al. Microstructures and properties of high-entropy alloys. Progress in Materials Science, 1-93(2014).

[27] J W YEH, S K CHEN, S J LIN et al. Nanostructured high-entropy alloys with multiple principal elements: novel alloy design concepts and outcomes. Advanced Engineering Materials, 299-303(2004).

[28] B CANTOR, I T H CHANG, P KNIGHT et al. Microstructural development in equiatomic multicomponent alloys. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing, 213-218(2004).

[29] P KOZELJ, S VRTNIK, A JELEN et al. Discovery of a superconducting high-entropy alloy. Physical Review Letters(2014).

[30] Y F KAO, S K CHEN, J H SHEU et al. Hydrogen storage properties of multi-principal-component CoFeMnTi_xV_yZr_z alloys. International Journal of Hydrogen Energy, 9046-9059(2010).

[31] D BERARDAN, S FRANGER, A K MEENA et al. Room temperature lithium superionic conductivity in high entropy oxides. Journal of Materials Chemistry A, 9536-9541(2016).

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

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

[34] Q Y YANG, P F QIU, X SHI et al. Application of entropy engineering in thermoelectrics. Journal of Inorganic Materials, 347-354(2021).

[35] K GALAZKA, S POPULOH, W J XIE et al. Improved thermoelectric performance of (Zr_0.3Hf_0.7)NiSn half-Heusler compounds by Ta substitution. Journal of Applied Physics(2014).

[36] W J XIE, Y G YAN, S ZHU et al. Significant ZT enhancement in p-type Ti(Co,Fe)Sb-InSb nanocomposites via a synergistic high-mobility electron injection, energy-filtering and boundary- scattering approach. Acta Materialia, 2087-2094(2013).

[37] J YANG, G P MEISNER, L CHEN. Strain field fluctuation effects on lattice thermal conductivity of ZrNiSn-based thermoelectric compounds. Applied Physics Letters, 1140-1142(2004).

微信扫一扫：分享

微信扫一扫：分享