Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe<sub>2</sub>–SnSe Thermoelectrics

Jang, Hanhwi; Toriyama, Michael Y.; Abbey, Stanley; Frimpong, Brakowaa; Male, James P.; Snyder, G. Jeffrey; Jung, Yeon Sik

doi:10.1002/adma.202204132

Cited by 20 publications

(6 citation statements)

References 92 publications

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“…The minimum value of the lattice thermal conductivity, observed at 623 K, followed by a conspicuous increase ( Figure 5 ) can be explained, based on the effect of the atomic ordering happening at that temperature. It has been reported that this atomic ordering effect can be inferred from the unconventional temperature dependence of the transport properties [ 30 ], such as in the lattice thermal conductivity, as well as in the resistivity, the Seebeck coefficient and the weighted mobility.…”

Section: Resultsmentioning

confidence: 99%

“…Therefore, the precise determination of the Ag/Sb occupancy in this telluride has a significant relevance in terms of transport properties. This cation disordering is often found in other ternary cubic chalcogenide compounds, with the associated point defects usually leading to a poor reproducibility of the properties of these materials [ 30 ]. Recently, Roychowdhury et al have proven that the atomic ordering can be achieved in AgSbTe 2 with cadmium (Cd) doping [ 31 ].…”

Section: Introductionmentioning

confidence: 99%

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Reduced Thermal Conductivity in Nanostructured AgSbTe2 Thermoelectric Material, Obtained by Arc-Melting

et al. 2022

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AgSbTe2 intermetallic compound is a promising thermoelectric material. It has also been described as necessary to obtain LAST and TAGS alloys, some of the best performing thermoelectrics of the last decades. Due to the random location of Ag and Sb atoms in the crystal structure, the electronic structure is highly influenced by the atomic ordering of these atoms and makes the accurate determination of the Ag/Sb occupancy of paramount importance. We report on the synthesis of polycrystalline AgSbTe2 by arc-melting, yielding nanostructured dense pellets. SEM images show a conspicuous layered nanostructuration, with a layer thickness of 25–30 nm. Neutron powder diffraction data show that AgSbTe2 crystalizes in the cubic Pm-3m space group, with a slight deficiency of Te, probably due to volatilization during the arc-melting process. The transport properties show some anomalies at ~600 K, which can be related to the onset temperature for atomic ordering. The average thermoelectric figure of merit remains around ~0.6 from ~550 up to ~680 K.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Reduced Thermal Conductivity in Nanostructured AgSbTe2 Thermoelectric Material, Obtained by Arc-Melting

et al. 2022

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“…In parallel, considering the positive role of Sn, Ag, and Bi in reducing the lattice thermal conductivity value of Cu 2 Se, as well as the potential advantages of stepwise alloying engineering, (SnSe) 1– x (AgBiSe 2 ) x was selected as the dopant for alloying. Furthermore, the stable existence of high-pressure cubic rock salt phase SnSe can be promoted by adjusting the x content in (SnSe) 1– x (AgBiSe 2 ) x . , The large degenerate number caused by the highly symmetric structure in cubic (SnSe) 0.75 (AgBiSe 2 ) 0.25 is beneficial to the improvement of Seebeck coefficient. Inherently low thermal conductivity (SnSe) 0.75 (AgBiSe 2 ) 0.25 was used as an additive to combine these effects to optimize the thermoelectric properties of Cu 1.9 Se.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, the stable existence of high-pressure cubic rock salt phase SnSe can be promoted by adjusting the x content in (SnSe) 1−x (AgBiSe 2 ) x . 23,24 The large degenerate number caused by the highly symmetric structure in cubic (SnSe) 0.75 (AgBiSe 2 ) 0.25 is beneficial to the improvement of Seebeck coefficient. Inherently low thermal conductivity (SnSe) 0.75 (AgBiSe 2 ) 0.25 was used as an additive to combine these effects to optimize the thermoelectric properties of Cu 1.9 Se.…”

Section: ■ Introductionmentioning

confidence: 99%

Stepwise Alloying in Liquid-like Solid Solutions to Achieve Crystallographic Distortion for Regulating Thermoelectric Transport Behavior

Bo,

Wang,

Zhu

et al. 2023

ACS Appl. Mater. Interfaces

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With the surge of energy consumption, environmental-protection Cu2–x Se thermoelectric materials are increasingly attracting attention. In this work, multilayered structures are constructed in Cu2–x Se solid solutions by alloying (SnSe)0.75(AgBiSe2)0.25, which strongly scatters full-wavelength phonons by carefully regulating the crystallographic distortion. By using the stepwise alloying strategies, crystallographic distortion and the resultant strain fields presented in microstructure were strengthened markedly, which enhanced the phonon scattering. Meanwhile, by adjusting the coalloying content of Ag, Bi, and Sn elements, the carrier and phonon transports were well decoupled in p-type Cu2–x Se, and the thermoelectric performance was significantly enhanced. By optimized power factor as well as depressed heat transport originating from the moderate coalloying, the maximum zT of 1.23 at 750 K was achieved in Cu1.9Se - 1 wt % (SnSe)0.75(AgBiSe2)0.25. This study indicated that the stepwise alloying strategy was a suitable method for optimizing zT of Cu2–x Se.

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“…Native defects often regulate electron-hole recombination mechanisms in, e.g., photovoltaics, [1][2][3][4][5] whereas electrical and thermal transport properties can be tuned by controlling point defects and the resulting carrier concentrations in, e.g., thermoelectrics. [6][7][8][9][10][11][12][13][14] The phase stability, defect formation energies, and carrier concentrations are interconnected properties of a semiconductor that are influenced by the thermodynamic environment. 15,16 In particular, a thermodynamic state is defined by a fixed set of elemental chemical potentials that are determined by the impurity phases with which a material is in equilibrium.…”

Section: Introductionmentioning

confidence: 99%

VTAnDeM: A Python Toolkit for Simultaneously Visualizing Phase Stability, Defect Energetics, and Carrier Concentrations of Materials

Toriyama¹,

Gomes

et al. 2022

Preprint

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Phase stability, defect formation energies, and carrier concentrations are closely interrelated features of semiconductors. Due to their joint dependence on the multidimensional chemical potential space, it is challenging to quantitatively establish patterns between these quantities in a given semiconductor, especially when the semiconductor is comprised of multiple elements. To enable synchronous visualization and analysis of these complementary material properties and their interdependence, we developed the Visualization Toolkit for Analyzing Defects in Materials (VTAnDeM). This python-based toolkit allows users to interactively explore how defect formation energies and carrier concentrations vary across the composition and chemical potential spaces of multicomponent semiconductors. Here, we illustrate the computational workflow that employs VTAnDeM as a post-processing tool for first-principles calculations and describe the data organization and theory underlying the visualization scheme. We believe that this software will serve as a useful tool for simultaneously visualizing the often complex and non-intuitive chemical potential - defect - carrier concentration phase space of semiconductors.

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Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe₂–SnSe Thermoelectrics

Cited by 20 publications

References 92 publications

Reduced Thermal Conductivity in Nanostructured AgSbTe2 Thermoelectric Material, Obtained by Arc-Melting

Reduced Thermal Conductivity in Nanostructured AgSbTe2 Thermoelectric Material, Obtained by Arc-Melting

Stepwise Alloying in Liquid-like Solid Solutions to Achieve Crystallographic Distortion for Regulating Thermoelectric Transport Behavior

VTAnDeM: A Python Toolkit for Simultaneously Visualizing Phase Stability, Defect Energetics, and Carrier Concentrations of Materials

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Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe2–SnSe Thermoelectrics

Cited by 20 publications

References 92 publications

Reduced Thermal Conductivity in Nanostructured AgSbTe2 Thermoelectric Material, Obtained by Arc-Melting

Reduced Thermal Conductivity in Nanostructured AgSbTe2 Thermoelectric Material, Obtained by Arc-Melting

Stepwise Alloying in Liquid-like Solid Solutions to Achieve Crystallographic Distortion for Regulating Thermoelectric Transport Behavior

VTAnDeM: A Python Toolkit for Simultaneously Visualizing Phase Stability, Defect Energetics, and Carrier Concentrations of Materials

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Product

Resources

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Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe₂–SnSe Thermoelectrics