[1] G KANATZIDIS M, LD ZHAO, G TAN. Rationally designing high-performance bulk thermoelectric materials. Chemical Reviews, 116, 12123-12149(2016).
[2] S NOLAS G, L COHN J, V FESSATIDIS et al. Glass-like heat conduction in high-mobility crystalline semiconductors. Physical Review Letters, 82, 779-782(1999).
[3] X SHI, A LALONDE, Y PEI et al. Convergence of electronic bands for high performance bulk thermoelectrics. Nature, 473, 66-69(2011).
[4] Z SUN, Z LIU, W ZHAO et al. Superparamagnetic enhancement of thermoelectric performance. Nature, 549, 247-251(2017).
[5] Y SHI F, Q HAO S, J TAN G et al. Valence band modification and high thermoelectric performance in SnTe heavily alloyed with MnTe. Journal of the American Chemical Society, 137, 11507-11516(2015).
[6] J HE, D BLUM I, K BISWAS et al. High-performance bulk thermoelectrics with all-scale hierarchical architectures. Nature, 489, 414-418(2012).
[7] W LI, J WU H, Y XIAO et al. Remarkable roles of Cu to synergistically optimize phonon and carrier transport in n-type PbTe-Cu2Te. Journal of the American Chemical Society, 139, 18732-18738(2017).
[8] H SUN F, F WU C, R WEI T et al. Nanoporous PbSe-SiO2 thermoelectric composites. Advanced Science, 4, 1700199-1-7(2017).
[9] X SU, H LI, P WEI et al. Multi-scale microstructural thermoelectric materials: transport behavior, non-equilibrium preparation,applications. Advanced Materials, 29, 1602013-1-13(2017).
[10] SH LO, J HE, LD ZHAO et al. High performance thermoelectrics from earth-abundant materials: enhanced figure of merit in PbS by second phase nanostructures. Journal of the American Chemical Society, 133, 20476-20487(2011).
[11] Y ZHANG, LD ZHAO, SH LO et al. Ultralow thermal conductivity and high thermoelectric figure of merit in SnSe crystals. Nature, 508, 373-377(2014).
[12] Q HAO S, D ZHAO L, J TAN G et al. Ultrahigh power factor and thermoelectric performance in hole-doped single-crystal SnSe. Science, 351, 141-144(2016).
[13] S HE D, H WU M, C CHANG et al. 3D charge and 2D phonon transports leading to high out-of-plane ZT in n-type SnSe crystals. Science, 360, 778-782(2018).
[14] J FAN, X SHI, L XI et al. Cu-Se bond network and thermoelectric compounds with complex diamondlike structure. Chemistry of Materials, 22, 6029-6031(2010).
[15] W CARRILLO-CABRERA, J FAN, L AKSELRUD et al. New monoclinic phase at the composition Cu2SnSe3 and its thermoelectric properties. Inorganic Chemistry, 52, 11067-11074(2013).
[16] S PRASAD K, A RAO, K TYAGI et al. Enhanced thermoelectric performance of Pb doped Cu2SnSe3 synthesized employing spark plasma sintering. Physica B. -Condensed Matter, 512, 39-44(2017).
[17] Y LI, J LI, G LIU et al. High thermoelectric performance of In-doped Cu2SnSe3 prepared by fast combustion synthesis. New Journal of Chemistry, 40, 5394-5400(2016).
[18] T MORELLI D, X LU. Thermoelectric properties of Mn-doped Cu2SnSe3. Journal of Electronic Materials, 41, 1554-1558(2012).
[19] G LIU, T CAO, Y LI et al. Enhanced thermoelectric properties of Cu2SnSe3 by (Ag,In)-Co-doping. Advanced Functional Materials, 26, 6025-6032(2016).
[20] G MARCANO, G DELGADO, A MORA et al. Crystal structure refinement of the semiconducting compound Cu2SnSe3 from X-ray powder diffraction data. Materials Research Bulletin, 38, 1949-1955(2003).
[21] W SCHNELLE, J FAN, I ANTONYSHYN et al. Structural evolvement and thermoelectric properties of Cu3-xSnxSe3 compounds with diamond-like crystal structures. Dalton Transactions, 43, 16788-16794(2014).
[22] X LU, H ZHAN, K PENG et al. Broad temperature plateau for high ZTS in heavily doped p-type SnSe single crystals. Energy & Environmental Science, 9, 454-460(2016).
[23] CW NAN. Physics of inhomogeneous inorganic materials. Progress in Materials Science, 37, 1-116(1993).
[24] B ZHANG, J SUN, E KATZ H et al. Promising thermoelectric properties of commercial PEDOT:PSS materials and their Bi2Te3 powder composites. ACS Applied Materials & Interfaces, 2, 3170-3178(2010).
[25] L PEI Y, J WU H, M ZHOU Y et al. Strategy to optimize the overall thermoelectric properties of SnTe via compositing with its property-counter CuInTe2. Acta Materialia, 125, 542-549(2017).