Yu Zhang scite author profile

Thermoelectric (TE) generators enable the direct and reversible conversion between heat and electricity, providing applications in both refrigeration and power generation. In the last decade, several TE materials with relatively high figures of merit (zT) have been reported in the low‐ and high‐temperature regimes. However, there is an urgent demand for high‐performance TE materials working in the mid‐temperature range (400–700 K). Herein, p‐type AgSbTe2 materials stabilized with S and Se co‐doping are demonstrated to exhibit an outstanding maximum figure of merit (zTmax) of 2.3 at 673 K and an average figure of merit (zTave) of 1.59 over the wide temperature range of 300–673 K. This exceptional performance arises from an enhanced carrier density resulting from a higher concentration of silver vacancies, a vastly improved Seebeck coefficient enabled by the flattening of the valence band maximum and the inhibited formation of n‐type Ag2Te, and ahighly improved stability beyond 673 K. The optimized material is used to fabricate a single‐leg device with efficiencies up to 13.3% and a unicouple TE device reaching energy conversion efficiencies up to 12.3% at a temperature difference of 370 K. These results highlight an effective strategy to engineer high‐performance TE material in the mid‐temperature range.

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Tin Diselenide Molecular Precursor for Solution‐Processable Thermoelectric Materials

Zhang

Liu

Lim

et al. 2018

Angewandte Chemie

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In the present work, we detail af ast and simple solution-based method to synthesize hexagonal SnSe 2 nanoplates (NPLs) and their use to produce crystallographically textured SnSe 2 nanomaterials.W ea lso demonstrate that the same strategy can be used to produce orthorhombic SnSe nanostructures and nanomaterials.N PLs are grown through as crew dislocation-driven mechanism. This mechanism typically results in pyramidal structures,b ut we demonstrate here that the growth from multiple dislocations results in flower-like structures.C rystallographically textured SnSe 2 bulk nanomaterials obtained from the hot pressing of these SnSe 2 structures displayhighly anisotropic charge and heat transport properties and thermoelectric (TE) figures of merit limited by relatively low electrical conductivities.T oimprove this parameter,SnSe 2 NPLs are blended here with metal nanoparticles.The electrical conductivities of the blends are significantly improved with respect to bare SnSe 2 NPLs,w hat translates into at hree-fold increase of the TE Figure of merit, reaching unprecedented ZT values up to 0.65.The use of molecular precursors to produce inorganic nanomaterials in the form of nanoparticles,t hin films, supported nanostructures or self-standing porous or dense nanomaterials is potentially advantageous in terms of reducing fabrication costs and improving performances.I nt his direction, the amine-dithiol system has been reported as av ersatile solvent to prepare molecular precursors from the dissolution at ambient conditions of metal chalcogenides, pure metals and metal oxides,a mong others. [1] Tw odimensional (2D) materials have attracted increasing attention in the past decade.T he structure of these materials is formed by atomically thin layers that display strong covalent in-plane bonding and weak layer-to-layer bonding. This type of structure results in extraordinary and at the same time highly anisotropic physical, electronic and optical properties.Inparticular, charge and heat transport properties are especially affected by the strong lattice asymmetry,a nd much higher thermal and electrical conductivities are measured in-plane than cross-plane.O wing to these highly anisotropic properties,t op roduce bulk 2D nanomaterials with aproper crystallographic texture is necessary to optimize their performance in most applications.H owever,t oc ontrol the crystallographic texture of materials produced by bottomup procedures and/or solution-based approaches is not straightforward.Ap articularly interesting 2D material family is that of metal chalcogenides,o wing to their good chemical stability and semiconducting characteristics.2 Dm etal chalcogenides are used in numerous applications in av ariety of fields, including energy conversion and storage, [2] flexible electronics [3] and medical diagnosis. [4] Among them, tin chalcogenides are especially interesting materials for energy conversion. [5] In particular,p -type SnSe single crystals have shown unprecedentedly high thermoelectric (TE) figures of merit:Z T= 2.6 at 92...

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Bismuth telluride–copper telluride nanocomposites from heterostructured building blocks

Zhang¹,

Liu

Calcabrini

et al. 2020

J. Mater. Chem. C

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Half-Heusler alloys as emerging high power density thermoelectric cooling materials

Zhu

Nozariasbmarz

et al. 2023

Nat Commun

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To achieve optimal thermoelectric performance, it is crucial to manipulate the scattering processes within materials to decouple the transport of phonons and electrons. In half-Heusler (hH) compounds, selective defect reduction can significantly improve performance due to the weak electron-acoustic phonon interaction. This study utilized Sb-pressure controlled annealing process to modulate the microstructure and point defects of Nb0.55Ta0.40Ti0.05FeSb compound, resulting in a 100% increase in carrier mobility and a maximum power factor of 78 µW cm−1 K−2, approaching the theoretical prediction for NbFeSb single crystal. This approach yielded the highest average zT of ~0.86 among hH in the temperature range of 300-873 K. The use of this material led to a 210% enhancement in cooling power density compared to Bi2Te3-based devices and a conversion efficiency of 12%. These results demonstrate a promising strategy for optimizing hH materials for near-room-temperature thermoelectric applications.

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PbS–Pb–Cu_xS Composites for Thermoelectric Application

Liu

Zhang

et al. 2021

ACS Appl. Mater. Interfaces

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Composite materials offer numerous advantages in a wide range of applications, including thermoelectrics. Here, semiconductor−metal composites are produced by just blending nanoparticles of a sulfide semiconductor obtained in aqueous solution and at room temperature with a metallic Cu powder. The obtained blend is annealed in a reducing atmosphere and afterward consolidated into dense polycrystalline pellets through spark plasma sintering (SPS). We observe that, during the annealing process, the presence of metallic copper activates a partial reduction of the PbS, resulting in the formation of PbS−Pb− Cu x S composites. The presence of metallic lead during the SPS process habilitates the liquid-phase sintering of the composite. Besides, by comparing the transport properties of PbS, the PbS−Pb−Cu x S composites, and PbS−Cu x S composites obtained by blending PbS and Cu x S nanoparticles, we demonstrate that the presence of metallic lead decisively contributes to a strong increase of the charge carrier concentration through spillover of charge carriers enabled by the low work function of lead. The increase in charge carrier concentration translates into much higher electrical conductivities and moderately lower Seebeck coefficients. These properties translate into power factors up to 2.1 mW m −1 K −2 at ambient temperature, well above those of PbS and PbS + Cu x S. Additionally, the presence of multiple phases in the final composite results in a notable decrease in the lattice thermal conductivity. Overall, the introduction of metallic copper in the initial blend results in a significant improvement of the thermoelectric performance of PbS, reaching a dimensionless thermoelectric figure of merit ZT = 1.1 at 750 K, which represents about a 400% increase over bare PbS. Besides, an average ZT ave = 0.72 in the temperature range 320−773 K is demonstrated.

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Yu Zhang

Defect‐Engineering‐Stabilized AgSbTe₂ with High Thermoelectric Performance

Tin Diselenide Molecular Precursor for Solution‐Processable Thermoelectric Materials

Bismuth telluride–copper telluride nanocomposites from heterostructured building blocks

Half-Heusler alloys as emerging high power density thermoelectric cooling materials

PbS–Pb–Cu_xS Composites for Thermoelectric Application

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Product

Resources

About

Yu Zhang

Defect‐Engineering‐Stabilized AgSbTe2 with High Thermoelectric Performance

Tin Diselenide Molecular Precursor for Solution‐Processable Thermoelectric Materials

Bismuth telluride–copper telluride nanocomposites from heterostructured building blocks

Half-Heusler alloys as emerging high power density thermoelectric cooling materials

PbS–Pb–CuxS Composites for Thermoelectric Application

Contact Info

Product

Resources

About

Defect‐Engineering‐Stabilized AgSbTe₂ with High Thermoelectric Performance

PbS–Pb–Cu_xS Composites for Thermoelectric Application