Thermoelectric properties in the series Ti1-xTaxS2

Beaumale, M.; Barbier, Tristan; Bréard, Yohann; Hébert, S.; Kinemuchi, Yoshiaki; Guilmeau, Emmanuel

doi:10.1063/1.4863141

Cited by 40 publications

(46 citation statements)

References 38 publications

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“…In the case of TiS 2 -based layered sulfides, a single crystal can be grown using the chemical-vapor-transport method with I 2 as the transport agent [38,39,40,41]. Polycrystalline TiS 2 -based layered sulfides have been commonly prepared by melting stoichiometric amounts of the constituent elements in evacuated and sealed quartz tubes at 905–1273 K, followed by pressurized sintering at 873–1173 K [30,42,43,44,45,46,47]. However, these methods are difficult to apply because of the large difference in vapor pressure between metals and sulfur; consequently, there is less motivation for researchers in the thermoelectric community to investigate thermoelectric sulfides further.…”

Section: Cs2 Sulfurization and Pressurized Sinteringmentioning

confidence: 99%

“…Because TiS 2 -based layered sulfides are primarily composed of earth-abundant, low-toxicity, and light elements, they will pave the way for environment-friendly, cost-effective, and lightweight thermoelectric devices [29,30,39,40,41,42,43,44,45,46,47,56,57,58,59,60,61,62,63,64,65,66]. The two-dimensional crystal structure of these systems is a great example in which the thermoelectric performance can be improved through nanoblock integration and hierarchical architecturing.…”

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

“…Temperature dependence of the thermoelectric figure of merit ( ZT ) in the in-plane ( ab -plane) direction for single-crystal TiS 2 [40] and polycrystalline Ti 1.008 S 2 [29], Ti 1.025 S 2 [30], Cu 0.1 TiS 2 [44], TiS 1.5 Se 0.5 [45], Ti 0.95 Ta 0.05 S 2 [46], [BiS] 1.2 [TiS 2 ] 2 [42], [PbS] 1.18 [TiS 2 ] 2 [42], [SnS] 1.2 [TiS 2 ] 2 [43], and [BiS] 1.2 [Ti 0.95 Cr 0.05 S 2 ] 2 [66]. …”

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

“…For example, Cu intercalation reduces κ lat from ~2.0 W·K −1 ·m −1 for TiS 2 to ~1.7 W·K −1 ·m −1 for Cu 0.1 TiS 2 , and SnS intercalation dramatically reduces κ lat to ~1.0 W·K −1 ·m −1 for [SnS] 1.2 [TiS 2 ] 2 at 300 K (Figure 7a). Substitution is another way to reduce κ lat [45,46,47]; for example, the substitution of Ti by Ta slightly reduces κ lat to ~1.8 W·K −1 ·m −1 for Ti 0.95 Ta 0.05 S 2 at 300 K (Figure 7b).…”

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

“…Temperature dependence of the lattice thermal conductivity (κ lat ) in the in-plane ( ab -plane) direction for Ti 1.008 S 2 [29]: ( a ) intercalated systems [BiS] 1.2 [TiS 2 ] 2 [42], [PbS] 1.18 [TiS 2 ] 2 [42], [SnS] 1.2 [TiS 2 ] 2 [43], and Cu 0.1 TiS 2 [44]; ( b ) substituted systems TiS 1.5 Se 0.5 [45] and Ti 0.95 Ta 0.05 S 2 [46]. …”

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

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Hierarchical Architecturing for Layered Thermoelectric Sulfides and Chalcogenides

Jood

Ohta

2015

Materials

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Sulfides are promising candidates for environment-friendly and cost-effective thermoelectric materials. In this article, we review the recent progress in all-length-scale hierarchical architecturing for sulfides and chalcogenides, highlighting the key strategies used to enhance their thermoelectric performance. We primarily focus on TiS2-based layered sulfides, misfit layered sulfides, homologous chalcogenides, accordion-like layered Sn chalcogenides, and thermoelectric minerals. CS2 sulfurization is an appropriate method for preparing sulfide thermoelectric materials. At the atomic scale, the intercalation of guest atoms/layers into host crystal layers, crystal-structural evolution enabled by the homologous series, and low-energy atomic vibration effectively scatter phonons, resulting in a reduced lattice thermal conductivity. At the nanoscale, stacking faults further reduce the lattice thermal conductivity. At the microscale, the highly oriented microtexture allows high carrier mobility in the in-plane direction, leading to a high thermoelectric power factor.

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Section: Cs2 Sulfurization and Pressurized Sinteringmentioning

confidence: 99%

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

Section: Tis2-based Layered Sulfidesmentioning

confidence: 99%

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Hierarchical Architecturing for Layered Thermoelectric Sulfides and Chalcogenides

Jood

Ohta

2015

Materials

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Refractory‐Metal‐Based Chalcogenides for Energy

Özel

Arkan

Coskun

et al. 2022

Adv Funct Materials

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When it is asked, “where can refractory metals be used?,” the possible shortest answer is, “where cannot they be used?” The uses of refractory‐metal‐based compounds in research and industry are too many to be enumerated; nevertheless, some outstanding examples are briefly mentioned here. Essentially, chalcogenide forms of refractory metals are preferred in the fabrication of high‐performance structures. Therefore, expanding the current studies that usually focus on tungsten‐ and molybdenum‐based structures to other materials may open new opportunities. Moreover, research on ternary and quaternary structures can also be a keystone in creating high‐performance products. The rationale of the present review is to give a brief overview of the recent history of refractory‐metal‐based chalcogenides (RMCs). Initially, the framework is confined to the general design and approaches for the synthesis of refractory metal chalcogenides. The assay is continued by extending with characteristic features of materials from crystalline properties to thermoelectric attributes and examining device fabrication processes. Taken together, the device fabrication part where RMCs are mainly used is extensively focused upon. Finally, outlook and future perspectives are given on the design and construction of RMCs to enable future inspiration and innovation.

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Environmentally Friendly Thermoelectric Materials: High Performance from Inorganic Components with Low Toxicity and Abundance in the Earth

Caballero‐Calero

Ares

Martín‐González

2021

Advanced Sustainable Systems

119

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energy would improve the efficiency of all these processes. In this context, thermoelectric devices provide a unique opportunity with significant advantages relative to other types of conversion, such as durability (no moving parts or fluids inside the generator), noise-free, low maintenance, modulability, and their applicability at different scales (from microdevices to large spaces to produce kilowatts), etc. [2] The implementation of thermoelectric generators has been limited for many years because of their low efficiency and high cost. There are examples of these limited applications like in space missions such as the Voyager, Apollo, Curiosity, etc. [3] when reliability is mandatory. Other niche applications with products that are being sold are, for instance, the powering of smartwatches with wasted

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Thermoelectric properties in the series Ti1-xTaxS2

Cited by 40 publications

References 38 publications

Hierarchical Architecturing for Layered Thermoelectric Sulfides and Chalcogenides

Hierarchical Architecturing for Layered Thermoelectric Sulfides and Chalcogenides

Refractory‐Metal‐Based Chalcogenides for Energy

Environmentally Friendly Thermoelectric Materials: High Performance from Inorganic Components with Low Toxicity and Abundance in the Earth

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