Effect of Te and In Co-doping on Thermoelectric Properties of Cu2SnSe3 Compounds

PeiAn REN; Cong WANG; Peng ZI; Qirui TAO; Xianli SU; Xinfeng TANG

doi:10.15541/jim20220039

[1] W ZHOU, K YAMAMOTO, A MIURA et al. Seebeck-driven transverse thermoelectric generation. Nature Materials, 463-467(2021).

[2] L O FREIRE, L M NAVARRETE, B P CORRALES et al. Efficiency in thermoelectric generators based on Peltier cells. Energy Reports, 7, 355-361(2021).

[3] L E BELL. Cooling, heating, generating power, and recovering waste heat with thermoelectric systems. Science, 1457-1461(2008).

[4] D W YANG, T T LUO, X X SU et al. Unveiling the intrinsic low thermal conductivity of BiAgSeS through entropy engineering in SHS kinetic process. Journal of Inorganic Materials, 991-998(2021).

[5] B Q CHEN, L D CHEN, Q H ZHANG. Technologies and applications of thermoelectric devices: current status, challenges and prospects. Journal of Inorganic Materials, 279-293(2019).

[6] M H ELSHEIKH, D A SHNAWAH, M F M SABRI et al. A review on thermoelectric renewable energy: principle parameters that affect their performance. Renewable and Sustainable Energy Reviews, 30, 337-355(2014).

[7] J J SHEN, T FANG, T Z FU et al. Lattice thermal conductivity in thermoelectric materials. Journal of Inorganic Materials, 260-268(2019).

[8] W LIU, L YANG, Z CHEN et al. Promising and eco-friendly Cu₂X-based thermoelectric materials: progress and applications. Advanced Materials, 1905703(2020).

[9] X Y ZHOU, Y LIU, C ZHANG et al. Optimization of thermoelectric transport properties of Nb-doped Mo_1-_xW_xSeTe solid solutions. Journal of Inorganic Materials, 1373-7379(2020).

[10] X YANG, X L SU, Y G YAN et al. Structures and thermoelectric properties of (GeTe)_nBi₂Te₃. Journal of Inorganic Materials, 75-80(2021).

[11] J SHUAI, Y SUN, X TAN et al. Manipulating the Ge vacancies and Ge precipitates through Cr doping for realizing the high- performance GeTe thermoelectric material. Small, 1906921(2020).

[12] M HONG, K ZHENG, W LYV et al. Computer-aided design of high-efficiency GeTe-based thermoelectric devices. Energy & Environmental Science, 13, 1856-1864(2020).

[13] X SU, P WEI, H LI et al. Multi-scale microstructural thermoelectric materials: transport behavior, non-equilibrium preparation, and applications. Advanced Materials, 1602013(2017).

[14] L HUANG, J LU, D MA et al. Facile in situ solution synthesis of SnSe/rGo nanocomposites with enhanced thermoelectric performance. Journal of Materials Chemistry A, 1394-1402(2020).

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

[16] X SHI, L XI, J FAN et al. Cu-Se bond network and thermoelectric compounds with complex diamondlike structure. Chemistry of Materials, 6029-6031(2010).

[17] H MING, G ZHU, C ZHU et al. Boosting thermoelectric performance of Cu₂SnSe₃via comprehensive band structure regulation and intensified phonon scattering by multidimensional defects. ACS Nano, 15, 10532-10541(2021).

[18] T DENG, T XING, M K BROD et al. Discovery of high- performance thermoelectric copper chalcogenide using modified diffusion-couple high-throughput synthesis and automated histogram analysis technique. Energy & Environmental Science, 3041-3053(2020).

[19] M SIYAR, J Y CHO, Y YOUN et al. Effect of annealing temperature on the phase transition, band gap and thermoelectric properties of Cu₂SnSe₃. Journal of Materials Chemistry C, 1780-1788(2018).

[20] J FAN, W SCHNELLE, I ANTONYSHYN et al. Structural evolvement and thermoelectric properties of Cu_3-_xSn_xSe₃ compounds with diamond-like crystal structures. Dalton Transactions, 16788-16794(2014).

[21] G DELGADO, A MORA, G MARCANO et al. Crystal structure refinement of the semiconducting compound Cu₂SnSe₃ from X-ray powder diffraction data. Materials Research Bulletin, 1949-1955(2003).

[22] S G CHOI, J KANG, J LI et al. Optical function spectra and bandgap energy of Cu₂SnSe₃. Applied Physics Letters, 043902(2015).

[23] G MARCANO, C RINCÓN, CHALBAUD L DE et al. Crystal growth and structure, electrical, and optical characterization of the semiconductor Cu₂SnSe₃. Journal of Applied Physics, 1847-1853(2001).

[24] L XI, Y ZHANG, X SHI et al. Chemical bonding, conductive network, and thermoelectric performance of the ternary semiconductors Cu₂SnX₃ (X= Se, S) from first principles. Physical Review B, 155201(2012).

[25] X CHENG, D YANG, X SU et al. Synergistically enhanced thermoelectric performance of Cu₂SnSe₃-based composites via Ag doping balance. ACS Applied Materials & Interfaces, 55178-55187(2021).