(i) Pseudocubic approach

A high N_v number, which is normally observed in a crystal structure with high symmetry, is desired for gaining both a large Seebeck coefficient and high electrical conductivity. Snyder et al. successfully implemented the band-convergence scheme in Se-alloyed PbTe for the first time and attained an excellent zT value of ∼1.8.^[7] This scheme has also been successively applied in other highly symmetric semiconductors (e.g., Mg₂Si, SnTe, half–Heusler, and CoSb₃).^[82–85] In 2014, Zhang et al. expanded it to chalcopyrite with low symmetry, and devised a ‘pseudocubic approach’ (Fig. 3), which has a cubic cation framework embedded in a noncubic distorted anion framework, to attain high power factor with high band convergence. They concluded a ‘unity-η rule’ ( ), which reveals that changing η toward unity would lead to band convergence for good thermoelectricity, and it was also experimentally verified that pseudocubic structured CuInTe₂ possesses the significantly enhanced zT value via Ag or Ga doping. As reported by Zeier et al. the pseudocubic approach truly works in attaining an increase of the power factor and zT in stannite Cu₂ZnGeSe₄ via Cu and Fe co-doping.^[86] However, this promising approach is limited to low symmetry material with an ideal band gap and a low κ_L.^[3]

Fig. 3.

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Fig. 3. (color online) Schematic diagrams illustrating the pseudocubic band-convergence, showing (a) crystal structure and schematic electronic bands of cubic zinc blende structure, and (b) crystal structure and schematic electronic bands of ternary chalcopyrites. The c and a are the lattice constants. is a nondegenerate band, and is a doubly degenerate band. is the crystal field-induced energy split at the top of the and bands. The pseudocubic structure has a cubic cation framework with embedded in a noncubic distorted anion framework.[23] Reproduced from Ref. [23] with permission from WILEY-VCH.

(ii) Highly-efficient-doping (HED)

As for TE materials possessing intrinsically high band degeneracy, heavy doping by guest atoms to reach the optimal carrier concentration will more or less cause the degenerate bands to destruct, leading to both the Seebeck coefficient and the power factor decreasing. Thus, selecting highly efficient dopants which can provide optimal carrier concentration at relatively low doping content, should be a feasible attempt to improve the electrical conductivity while maintaining the large Seebeck coefficient with little divergence of degenerate bands.^[60] As illustrated in Fig. 4, the serious separation of the degenerate bands in non-HED can be relieved by HED when the same level of carrier concentration is reached. One could clearly note that the advantage of HED by Al/Ga/In comparing with the non-HED by Ge/Sn in high-band-degeneracy Cu₃SbSe₄ with 0.5% of Al/Ga/In substitution could provide comparable or even higher carrier concentration than that of 1% Ge-doping and its characteristic also has little deviation from the Pisarenko curve due to the nearly non-changed band structure. Meanwhile, the high doping concentration (e.g., 2% Ge, 5% Sn) makes the Seebeck coefficient deteriorate rapidly due to the severe split of the degenerate bands. Ultimately, the zT of the sample with HED possesses a higher value than that of the non-HED at 623 K.^[60]

Fig. 4.

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Fig. 4. (color online) (a) Schematic diagram illustrating the maintenance of highly degenerate electronic bands of the matrix by highly efficient doping (HED), and (b) curve of S versus carrier concentration showing that the nearly non-changed band structure can be obtained via HED (i.e., Al, Ga, In doping)[60] in Cu3SbSe4 with high band degeneracy. Reproduced from Ref. [6] with permission from the American Chemical Society.

It was suggested that the accompanying extra entropy in magnetic ions with degeneracy of electronic spin configuration in real space, such as transition metal ions with unpaired 3d electrons, should play a key role in obtaining large S at high σ in cobalt oxide.^[61,87,88] This striking fact has encouraged many researchers to explore the possibility of substitution using magnetic ions to improve the TE performances of the other materials. Yao et al. firstly investigated the TE properties of magnetic-ion-substituted chalcopyrite in 2011 and observed the simultaneous optimizing of all three TE parameters in Mn-substituted CuInSe₂.^[89] The Mn-doping moved the Fermi level (E_f) downward into the region of the valence band, and the Mn 3d level hybridization with the Se 4p level resulted in the finite DOS in the proximity of the E_f, enabling the considerable enhancing of S and σ for CuInSe₂. The introduced Mn–Se networks could provide an additional conduction pathway for charge carriers. The increased local disorder in the crystal lattice by Mn substitution could reduce κ_L, which was also verified by Raman spectroscopy. However, the contribution of the spin entropy has been neglected in the work of Yao et al. In 2013, Xiao et al. reported that magnetic ions could also decouple the strongly interrelated three TE parameters in Cu₂ZnSnS₄ (Fig. 5(a)).^[61] More importantly, the performed electron paramagnetic resonance (EPR) experiments implied that Ni²⁺ doping truly brought extra spin into Cu₂ZnSnS₄ and therefore the value of S is remarkably enhanced. After the magnetic ions (e.g., Cobalt) are fully substituted into Cu₂ZnSnS₄, the electronic structure and phonon structure will undergo significant change due to the strong hybridization between the 3d states of magnetic ions and S 3p states, and therefore the TE properties are improved (Figs. 5(b)–5(d)). The distinct band structure feature of Cu₂CoSnS₄ with magnetic component shows an extremely high zT of 0.8 achieved in this cheap and eco-friendly sulphide, which is due to the improved electrical properties by enhancing the effective mass and the depressed lattice thermal conductivity by weakening the covalent-bonding.^[67]

Fig. 5.

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Fig. 5. (color online) (a) Schematic diagrams illustrating various electron spin and phonon scatterings in quaternary magnetic nanocrystals and (b) comparison of the zT among Cu2XSnS4 nanocrystals.[61] Reproduced from Ref. [61] with permission from the Royal Society of Chemistry, (c) electronic and (d) phonon band structure for Cu2CoSnS4.[67] Reproduced from Ref. [67] with permission from Elsevier.

Other researches for improving TE performances of Ni-doped Cu₃SbS₄, Mn-doped CuGaTe₂ and cobalt-doped Cu₂SnS₃,^[46,90,91] also proved the effectiveness and good-transplanting of magnetic ion doping strategy in MDLCs. However, most of researches usually focused on explaining the enhancement in S by an additional spin entropy effect or the participation of magnetic-ion-3d states near the E_f in the electronic transport.^{[46,61,89–92]} The above two factors, which may interconnect with each other by magnetic-ion, should be considered together and also clarify the primary cause for enhancing the value of S at different magnetic ion content (e.g., in 2.6% Ni-doped Cu₂ZnSnS₄, Cu₂CoSnS₄, and CuFeS₂.^[36,61,67] Additionally, as the spin-disorder scattering in magnetic ion doping more or less hampers the mobility of carriers,^[93] its influence should also be taken into consideration, especially at low temperature. If the reduction in carrier mobility overweighs the increase in S, no enhancement of power factor may appear. Therefore, the relationship between magnetism and TE property still needs further exploring.

It is known that the introduction of point defects is an effective approach to reducing the value of κ_L by enhancing the phonon scattering due to the mass contrast and strain field fluctuation between the host and guest atoms. According to the Debye–Callaway–Klemens model, the high concentration of defects possessing large mass difference and strain fluctuations can maximize the scattering parameter (Γ) and thus achieve the lowest κ_L.^[75] Pei et al. observed that Ag_Cu substitutional defects reduced the κ_L of CuGaTe₂ more obviously than Zn_Ga/In_Ga defects at the same concentration, which is due to the larger mass contrast.^[94] However, the maximum mass contrast ( ), which can be maximized when the dominant point defects are vacancies, seems unattainable by conventional doping but is possible when the guest or host atom represents a disordered vacancy. Thus, the compounds with inherent vacancy, such as In₂Te₃ (one-third of its cationic sites are vacant) and their analogues, are selected to greatly depress the κ_L of the parent phase by forming a solid solution.^[75] It is found that the value of κ_L of CuGaTe₂ alloyed with the proper amount of In₂Te₃ or Ga₂Te₃ was reduced more remarkably than that of the same quantity of substitutional defects (Fig. 6(a)), which could be attributed to the strong vacancy phonon scattering induced by guesting vacancies.^[95] Additionally, a detailed investigation of the room temperature thermal conductivity on anion substitution series Cu₂ZnGeSe_4−xS_x revealed a reduction of the κ_L of 42% (Fig. 6(b)), and the calculations quantitively revealed that mass contrast (reduction of 34%) has a greater influence than strain contrast (reduction of 8%).^[96]

Fig. 6.

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Fig. 6. (color online) (a) Room temperature cation defect concentration (nCD)-dependent normalized lattice thermal conductivity (κL) for CuGaTe2 solid solutions with (red) and without (black) vacancies.[95] Reproduced from Ref. [95] with permission from the Royal Society of Chemistry. (b) Plots of room-temperature κL and modeled κL against the molar fraction of selenium of the complete solid solution series Cu2ZnGeSe4−xSx with x = 0–4.[96] Reproduced from Ref. [96] with permission from the American Chemical Society.

(I) Nanocomposite

The proposed concept of low-dimensional TE materials (e.g. quantum dots, nanowires and superlattices systems) in the 1990s has revealed that the simultaneous optimization of the power factor and κ_L is possible in nanostructures.^[97,98] After that, many experimental studies on nanostructured bulk materials, such as (Bi,Sb)₂Te₃, PbTe, Si₈₀Ge₂₀,^[99–101] have also proved that the nanocomposite approach (i.e., reducing the grain size to nanometers or using nanoparticles) is indeed effective in increasing zT of 3D bulk material due to the reduction in the κ_L by the selective scattering of phonons or the enhancement in the Seebeck coefficient via preferential scattering of low-energy electrons (i.e., energy filtering).^[12] Consequently, the nanocomposite approach is also widely adopted to achieve the expected high zT in MDLC, although it probably causes the electrical conductivity to decrease by the deterioration of carrier mobility. Liu et al. reported a solution-based scalable synthesis approach to produce several grams of monodisperse Cu₃SbSe₄ nanocrystals (Fig. 7),^[59] and found the nano-crystalline Cu₃SbSe₄ had better TE performance than the micro-crystalline compound with the same constituents because the value of κ_L greatly decreased. Furthermore, an extremely high zT value (i.e., 1.26) was obtained in (Sn, Bi)-dual-doped Cu₃SbSe₄ by this improved approach. Liang et al. found that the CuFeS₂ nanocrystals exhibited a significantly higher S than bulk chalcopyrite material due to quantum confinement and a tremendously low κ_L, due to the increased phonon scattering at the nanocrystal grain boundary, thus zT is enhanced by 77 times.^[36] Chen et al. found that Cu-doped Cu₂ZnSnSe₄ nanocrystals prepared by hot-injection had a zT as high as 0.70 at 450 °C, which is significantly higher than that by the traditional method.^[63] The obtained high TE performance in Cu₂SnSe₃ nanocrystal also shows the effectiveness and good prospects of the nanocomposite approach in obtaining efficient TE materials.^[13] However, the problems of aggregation and growth during nanocrystals densification become challenges to further enhancing the TE performance by this approach.

Fig. 7.

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	Fig. 7. (color online) (a) Representative TEM micrographs of Cu3SbSe4 nanocrystallines, and the corresponding HRTEM images, electron diffraction patterns and EELS analysis results.[59] Reproduced from Ref. [59] with permission from the Royal Society of Chemistry. [(b) and (c)] Temperature-dependent κ and zT values for micro- and nano-crystalline Cu3SbSe4.[56,59]

(II) Nanoinclusion

Nanoinclusion strategies by introducing a nano-sized second phase are effectively utilized to obtain high performance TE materials (e.g., CoSb₃, PbTe, SnTe)^[104–106] due to the depressed κ_L by additional phonon scattering or the increased S through energy filtering. Most of the research of nanoinclusion about MDLCs focuses on the CuGaTe₂/CuInTe₂ type materials currently. In the case of CuGaTe₂, the incorporation of graphite nanosheets could enhance the S and power factor due to the energy filtering effect, and also cause the value of κ_L to decrease below 750 K because of the increased interface scattering. The large zT value increased up to 0.93 at 873 K in CuGaTe₂ composite, which had about 21% improvement on pure CuGaTe₂.^[107] However, the introduction of nanophase Cu₂Se into CuGaTe₂ reduced the value of S due to the increase of carrier concentration.^[32] Benefiting from the greatly reduced value of κ_L, the final zT approached to 1.2 at 834 K for the CuGaTe₂/3vol% Cu₂Se sample. By introducing a proper amount of grapheme into CuInTe₂, Chen et al. also observed that the κ_L successfully decreased and also the value of zT was improved.^[108]