Rationally Designing High-Performance Bulk Thermoelectric Materials

Tan, Gangjian; Zhao, Li‐Dong; Kanatzidis, Mercouri G.

doi:10.1021/acs.chemrev.6b00255

Cited by 1,726 publications

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“…A good thermoelectric material should simultaneously possess high electrical conductivity (σ) to minimize the internal Joule loss, a high Seebeck coefficient (S) to produce high voltage, and low thermal conductivity (κ) to maintain the temperature gradient. [1] To give a clearer criterion, the dimensionless figure www.advmat.de www.advancedsciencenews.com room temperature TE devices, is discussed for its general opti mization method. Then, two typical kinds of bulk materials with 2D structures developed in our group, stacking with the same slabs or different slabs, are examined to determine the detailed transport properties resulting from their structure.…”

Section: Introductionmentioning

confidence: 99%

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Promising Thermoelectric Bulk Materials with 2D Structures

2017

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Given that more than two thirds of all energy is lost, mostly as waste heat, in utilization processes worldwide, thermoelectric materials, which can directly convert waste heat to electricity, provide an alternative option for optimizing energy utilization processes. After the prediction that superlattices may show high thermoelectric performance, various methods based on quantum effects and superlattice theory have been adopted to analyze bulk materials, leading to the rapid development of thermoelectric materials. Bulk materials with two‐dimensional (2D) structures show outstanding properties, and their high performance originates from both their low thermal conductivity and high Seebeck coefficient due to their strong anisotropic features. Here, the advantages of superlattices for enhancing the thermoelectric performance, the transport mechanism in bulk materials with 2D structures, and optimization methods are discussed. The phenomenological transport mechanism in these materials indicates that thermal conductivities are reduced in 2D materials with intrinsically short mean free paths. Recent progress in the transport mechanisms of Bi2Te3‐, SnSe‐, and BiCuSeO‐based systems is summarized. Finally, possible research directions to enhance the thermoelectric performance of bulk materials with 2D structures are briefly considered.

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Section: Introductionmentioning

confidence: 99%

“…Interested readers are encouraged to refer to other excellent review papers on TE materials. [1,[76][77][78][79] …”

Section: Introductionmentioning

confidence: 99%

Promising Thermoelectric Bulk Materials with 2D Structures

2017

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“…Thermoelectric (TE) materials, which are capable of direct and reversible conversion between heat and electricity, have attracted widespread research interests due to their advantages of no moving parts, no mechanical or chemical processes involved, emission free, high durability, and reliability [1][2][3][4][5]. TE technology shows a great potential in a variety of applications such as spot cooling and power generation using waste heat [6].…”

Section: Introductionmentioning

confidence: 99%

High thermoelectric performance and low thermal conductivity in Cu2−yS1/3Se1/3Te1/3 liquid-like materials with nanoscale mosaic structures

et al. 2017

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Mosaic-crystal microstructure is one of the optimal strategies for decoupling and balancing thermal and electrical transport properties in thermoelectric materials. Herein, we successfully achieve the desired nanoscale mosaic structures in triple-component Cu2-yS1/3Se1/3Te1/3 solid solutions using Cu2S, Cu2Se, and Cu2Te matrix compounds. They are solved in hexagonal structures with space group R3 ̅ m by means of single crystal structural solution and Rietveld refinement. Electron backscatter diffraction measurements show that all the samples are polycrystalline compounds with the grain size in the range of micrometers. However, transmission electron microscopic study reveals that these microscale grains are quasi-single crystals consist of a variety of 10-30 nm mosaic grains. Each mosaic grain is a perfect crystal but titled or rotated with respect to others by a very small angle. In this case, excellent electrical transports are maintained but exceptional low thermal conductivity is achieved throughout the whole temperature range, which is attributed to the combined phonon scatterings by point defects, liquid-like copper ions, and lattice strains or interfaces of mosaic nanograins. Combining all these favorable factors, remarkably high thermoelectric performance is achieved in Cu1.98S1/3Se1/3Te1/3 2 with a maximum zT of 1.9 at 1000 K.

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“…The identification of the phonon-scattering processes that limit heat conduction in a material has led to a panoscopic approach to reduce κ for PC materials. 4,5 Here κ remains above the minimum thermal conductivity (κmin) expected for a PG, where the thermal conductivity is described by a coupled lattice of harmonic oscillators vibrating with the same frequency but with random phases, and κmin can be calculated using Cahill's model (Equation S9, ESI †) from the number density of atoms (N) and D. 6 The phonon MFP of a PG is much smaller than a PC and remains constant as a function of temperature as all vibrations are localised over interatomic distances.…”

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“…23 The nanostructuring approaches used to reduce κ in classical compound semiconductors and intermetallics by increasing grain boundary scattering are inefficient in titanate perovskites as the phonon MFP of SrTiO3 is 2-3 nm, requiring nanometer-sized grains for any noticeable effect on κ. 4,24 Because of this inherently small phonon MFP, the best strategy to reduce κlatt is through the introduction of point defect scattering achieved by substitution. The scattering time for point defects (PD) is added to the other scattering processes according to the Mathiessen rule, 25 and is influenced heavily by the disorder scattering parameter,  = MF + SF, where MF is the mass fluctuation arising from the mass contrast introduced by the defect and SF the strain field induced by ionic radius variance of the defect (Equation S5, ESI †).…”

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Phonon-glass electron-crystal behaviour by A site disorder in n-type thermoelectric oxides

Daniels

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Pitcher

et al. 2017

Energy Environ. Sci.

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a Phonon-glass electron-crystal (PGEC) behaviour is realised in La0.5Na0.5Ti1-xNbxO3 thermoelectric oxides. The vibrational disorder imposed by the presence of both La 3+ and Na + cations on the A site of the ABO3 perovskite oxide La0.5Na0.5TiO3 produces a phonon-glass with a thermal conductivity, κ, 80% lower than that of SrTiO3 at room temperature. Unlike other state-of-the-art thermoelectric oxides, where there is strong coupling of κ to the electronic power factor, the electronic transport of these materials can be optimised independently of the thermal transport through cation substitution at the octahedral B site. The low κ of the phonon-glass parent is retained across the La0.5Na0.5Ti1-xNbxO3 series without disrupting the electronic conductivity, affording PGEC behaviour in oxides.Thermoelectric generators offer enhanced energy efficiency across the industrial and automotive sectors through the conversion of waste heat into electricity. Materials performance is assessed by the dimensionless figure of merit ZT = (S 2 σ/κ)T, combining the thermal conductivity (κ), absolute temperature (T), the Seebeck coefficient (S) and electrical conductivity (σ), which together define the power factor (S 2 σ). One strategy to optimise ZT is the phononglass electron-crystal (PGEC) concept proposed by Slack, 1 which aims to decouple the quantities governed by the Boltzmann transport equation in an "electron-crystal", by maximising S and σ, from the quantity governed by phonon transport processes in a "phonon-glass" (PG) by minimising the lattice contribution to the thermal conductivity (κlatt); essentially, a crystal that transports charge like a semiconductor, whilst hindering the transport of heat by the lattice like a glass. 2 Heat transport in solids consists of lattice and electronic (κelec) contributions through κ = κlatt + κelec, and κlatt=1/3Cv·lph·νs (Equation 1), where Cv is the isochoric heat capacity, lph the average phonon mean free path (MFP), and vs the mean velocity of sound. Different heat-carrying mechanisms lead to a broad distribution of MFPs, ranging from the atomic scale (<1 nm) for point defect scattering, to the mesoscale (>100 nm) for grain boundary scattering. In a "phonon-crystal" (PC), heat is transported by phonons of well-defined wavelength. The phonon scattering rate (ph -1 ), which is inversely proportional to κlatt (Equation S1, ESI †), corresponds to the sum of the inverse relaxation times of several phonon-scattering mechanisms that contribute separately to κ and is described quantitatively by the modified Debye-Callaway model (Equation S3, ESI †). 3 This produces a T -1 temperature dependence of κ above the Debye temperature (D) where heat conduction is by Oxide materials are of current interest as high-temperature energy-harvesting thermoelectrics in the automotive and manufacturing sectors due to their low cost, low toxicity and high chemical robustness. The phonon-glass electron crystal (PGEC) concept which has been successfully used to optimise the thermoelectric figure of merit (Z...

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Rationally Designing High-Performance Bulk Thermoelectric Materials

Cited by 1,726 publications

References 268 publications

Promising Thermoelectric Bulk Materials with 2D Structures

Promising Thermoelectric Bulk Materials with 2D Structures

High thermoelectric performance and low thermal conductivity in Cu2−yS1/3Se1/3Te1/3 liquid-like materials with nanoscale mosaic structures

Phonon-glass electron-crystal behaviour by A site disorder in n-type thermoelectric oxides

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