Advances in Thermoelectric Mg<sub>3</sub>Sb<sub>2</sub> and Its Derivatives

Shi, Xuemin; Wang, Xiao; Li, Wen; Pei, Yanzhong

doi:10.1002/smtd.201800022

Cited by 68 publications

(44 citation statements)

References 88 publications

(232 reference statements)

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“…The advances in n -type Mg 3 Sb 2- x Bi x demonstrate a good paradigm of how a new TE material can be rapidly developed and even transferred into the lab-scale module verification by the current TE community. In the past two years, there have been two timely review articles discussing the recent progress of Mg 3 Sb 2 and its derivatives: one is focusing on the design principle with a combination of theory and experiment [ 99 ] and the other on the manipulation of defects and electronic transport properties [ 100 ]. Readers who are interested in more details may refer to these two reviews.…”

Section: Introductionmentioning

confidence: 99%

High-Performance Mg ₃ Sb _{2-
x} Bi _x Thermoelectrics: Progress and Perspective

Zhao

et al. 2020

Research

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Since the first successful implementation of n-type doping, low-cost Mg3Sb2-xBix alloys have been rapidly developed as excellent thermoelectric materials in recent years. An average figure of merit zT above unity over the temperature range 300–700 K makes this new system become a promising alternative to the commercially used n-type Bi2Te3-xSex alloys for either refrigeration or low-grade heat power generation near room temperature. In this review, with the structure-property-application relationship as the mainline, we first discuss how the crystallographic, electronic, and phononic structures lay the foundation of the high thermoelectric performance. Then, optimization strategies, including the physical aspects of band engineering with Sb/Bi alloying and carrier scattering mechanism with grain boundary modification and the chemical aspects of Mg defects and aliovalent doping, are extensively reviewed. Mainstream directions targeting the improvement of zT near room temperature are outlined. Finally, device applications and related engineering issues are discussed. We hope this review could help to promote the understanding and future developments of low-cost Mg3Sb2-xBix alloys for practical thermoelectric applications.

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Section: Introductionmentioning

confidence: 99%

High-Performance Mg ₃ Sb _{2-
x} Bi _x Thermoelectrics: Progress and Perspective

Zhao

et al. 2020

Research

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“…N-Type Mg 3 Sb 2 -based Zintl compounds are a class of high-performance thermoelectric materials for the midtemperature application, recently discovered. − Compared to the intrinsic p-type Mg 3 Sb 2 , − the high performance of the n-type counterpart is mainly attributed to the excellent electronic conduction transports characterized by larger N V / m * ( N V and m * are the number of valleys and the band effective mass, respectively) . Mg 3.2 Sb 1.5 Bi 0.49 Te 0.01 with a peak zT of 1.51 at 716 K was first reported by Tamaki et al, and multiple groups have reported similar results. − The role of excess Mg is to lift the Fermi level up toward the conduction band, and the Fermi level is further improved by Te doping, thus leading to a high n-type carrier concentration of ∼10 19 cm –3 and excellent thermoelectric transports. , …”

Section: Introductionmentioning

confidence: 99%

Defect Chemistry for N-Type Doping of Mg₃Sb₂-Based Thermoelectric Materials

Zhang

Zheng

et al. 2019

J. Phys. Chem. C

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N-Type Mg3Sb2-based Zintl compounds have recently been discovered to be a promising class of thermoelectric materials. Effective n-type dopants are crucial for realizing high thermoelectric performance. Here, using first-principles defect calculations, we investigate that Tm and Ce are effective n-type dopants in Mg3Sb2 and explain why n-type conduction can be successfully achieved by a simple doping without extra Mg. Under Mg-rich conditions, the maximal achievable free carrier concentrations for Tm and Ce substitution on Mg sites at 750 K exceed 1020 cm–3, approaching the optimal carriers of ∼1020 cm–3. Under Mg-poor conditions, the miraculous n-type conduction achieved by a simple extrinsic n-type doping can be explained by the sufficiently low defect formation energy for the substitutional donor defect.

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“…The low-temperature (<550 K) materials contain group-V alloys, [7] V 2 VI 3 , [8][9][10][11][12] CsBi 4 Te 6 , [13] and α-MgAgSb, [14] etc., in general exhibiting zT values below 1.5. The class of medium-temperature (550-950 K) materials contains many compounds, including IV-VI alloys, such as PbTe, [15,16] SnTe, [17] GeTe, [18] and SnSe, [19] I-V-VI 2 compounds, [20,21] Zintl compounds, [22] filled Skutterudites, [23] Clathrates, [24] Cu 2 Se, [25] and BiCuSeO, [26] to name a few. They normally embrace maximum zT values above 1.5.…”

mentioning

confidence: 99%

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Cagnoni

Cojocaru‐Mirédin

et al. 2019

Adv Funct Materials

165

201

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Thermoelectric materials have attracted significant research interest in recent decades due to their promising application potential in interconverting heat and electricity. Unfortunately, the strong coupling between the material parameters that determine thermoelectric efficiency, i.e., the Seebeck coefficient, electrical conductivity, and thermal conductivity, complicates the optimization of thermoelectric energy converters. Main‐group chalcogenides provide a rich playground to alleviate the interdependence of these parameters. Interestingly, only a subgroup of octahedrally coordinated chalcogenides possesses good thermoelectric properties. This subgroup is also characterized by other outstanding characteristics suggestive of an exceptional bonding mechanism, which has been coined metavalent bonding. This conclusion is further supported by a map that separates different bonding mechanisms. In this map, all octahedrally coordinated chalcogenides with good performance as thermoelectrics are located in a well‐defined region, implying that the map can be utilized to identify novel thermoelectrics. To unravel the correlation between chemical bonding mechanism and good thermoelectric properties, the consequences of this unusual bonding mechanism on the band structure are analyzed. It is shown that features such as band degeneracy and band anisotropy are typical for this bonding mechanism, as is the low lattice thermal conductivity. This fundamental understanding, in turn, guides the rational materials design for improved thermoelectric performance by tailoring the chemical bonding mechanism.

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Advances in Thermoelectric Mg₃Sb₂ and Its Derivatives

Cited by 68 publications

References 88 publications

High-Performance Mg ₃ Sb _{2-
x} Bi _x Thermoelectrics: Progress and Perspective

High-Performance Mg ₃ Sb _{2-
x} Bi _x Thermoelectrics: Progress and Perspective

Defect Chemistry for N-Type Doping of Mg₃Sb₂-Based Thermoelectric Materials

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

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Advances in Thermoelectric Mg3Sb2 and Its Derivatives

Cited by 68 publications

References 88 publications

High-Performance Mg 3 Sb 2- x Bi x Thermoelectrics: Progress and Perspective

High-Performance Mg 3 Sb 2- x Bi x Thermoelectrics: Progress and Perspective

Defect Chemistry for N-Type Doping of Mg3Sb2-Based Thermoelectric Materials

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Contact Info

Product

Resources

About

Advances in Thermoelectric Mg₃Sb₂ and Its Derivatives

High-Performance Mg ₃ Sb _{2-
x} Bi _x Thermoelectrics: Progress and Perspective

High-Performance Mg ₃ Sb _{2-
x} Bi _x Thermoelectrics: Progress and Perspective

Defect Chemistry for N-Type Doping of Mg₃Sb₂-Based Thermoelectric Materials