Electrical and Thermal Transport of Layered Bismuth-Sulfide EuBiS<sub>2</sub>F at Temperatures between 300 and 623 K

Goto, Yosuke; Kajitani, Joe; Mizuguchi, Yoshikazu; Kamihara, Yoichi; Matoba, Masanori

doi:10.7566/jpsj.84.085003

Cited by 15 publications

(12 citation statements)

References 21 publications

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“…The power factor increased with increasing concentration of Se, i.e., Se substitution led to an enhanced electrical conductivity, without suppression of the Seebeck coefficient. Hall measurements indicated that the low electrical resistivity resulted from increases in the carrier mobility, and the decrease in carrier concentration led to large absolute values of the Seebeck coefficient of the system.LaOBiCh2 (Ch: S, Se) and related Bi-Ch layered compounds have attracted significant attention as new thermoelectric materials [1][2][3][4]. The crystal structure of LaOBiCh2 consists of alternating stacks of an electrically conducting BiCh2 bilayer and an insulating La2O2 layer.…”

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confidence: 99%

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS₂₋_xSe_x

et al. 2016

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We examined the electrical transport properties of densified LaOBiS2-xSex, which constitutes a new family of thermoelectric materials. The power factor increased with increasing concentration of Se, i.e., Se substitution led to an enhanced electrical conductivity, without suppression of the Seebeck coefficient. Hall measurements indicated that the low electrical resistivity resulted from increases in the carrier mobility, and the decrease in carrier concentration led to large absolute values of the Seebeck coefficient of the system. (at ~650 K) for LaOBiSSe [5]. In contrast to the typically observed trend, the electrical resistivity of LaOBiS2-xSex was suppressed and the absolute value of the Seebeck coefficient was increased by Se substitution [2]. We therefore sought to clarify the electronic origins of the Se-substitution-induced enhancement of the power factor (PF = S 2 /) of LaOBiS2-xSex; this was done by determining the electrical resistivity (), Seebeck coefficient (S), carrier concentration (n), and mobility () of the system. Polycrystalline samples of LaOBiS2-xSex (x = 0, 0.4, 0.6, 0.8, and 1) were prepared using the solid-state-reaction method described in Ref. 2. The samples were densified by hot-pressing (HP) under a uniaxial pressure of 50 MPa. The resulting LaOBiS2-xSex powders were sealed in a 15-mm-diameter graphite capsule during HP annealing. The powders were annealed for 1 h at 700 ºC and 800 ºC for x = 0.4-1 and x = 0, respectively. This annealing

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Electronic Origins of Large Thermoelectric Power Factor of LaOBiS₂₋_xSe_x

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“…This material shows metallic conductivity and shows a superconducting transition at 0.4 K [32]. Goto et al measured thermoelectric properties of EuFBiS2 at high temperatures [53]. Figures 6(a,b) show the temperature dependences of  and S for EuFBiS2.…”

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Thermoelectric properties of new Bi-chalcogenide layered compounds

et al. 2016

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The layered Bi-chalcogenide compounds have been drawing much attention as a new layered superconductor family since 2012. Due to the rich variation of crystal structure and constituent elements, the development of new physics and chemistry of the layered Bi-chalcogenide family and its applications as functional materials have been expected. Recently, it was revealed that the layered Bi chalcogenides can show a relatively high thermoelectric performance (ZT = 0.36 in LaOBiSSe at ~650 K). Here, we show the crystal structure variation of the Bi-chalcogenide family and their thermoelectric properties. Finally, the possible strategies for enhancing the thermoelectric performance are discussed on the basis of the experimental and the theoretical facts reviewed here.

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“…The highest ZT was 0.36 at ∼650 K, and the ZT is expected to increase at higher temperatures. Studies on the thermoelectric properties of BiCh 2 ‐related compounds have just started in several groups with various compounds . The LaOM 2 S 3 (M = Bi, Pb) structure (Figure e) with four‐layer‐type M 4 S 6 conduction layers is also a candidate for new thermoelectric materials, because of the M 4 Ch 6 ‐type conduction layer similar to that of CsBi 4 Te 6 , which is a high‐performance thermoelectric material and a superconductor .…”

Section: Bich2‐based Compounds As Thermoelectric Materials or Other Fmentioning

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Recent Advances in Layered Metal Chalcogenides as Superconductors and Thermoelectric Materials: Fe-Based and Bi-Based Chalcogenides

Mizuguchi

2016

The Chemical Record

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Recent advances in layered (Fe-based and Bi-based) chalcogenides as superconductors or functional materials are reviewed. The Fe-chalcogenide (FeCh) family are the simplest Fe-based high-Tc superconductors. The superconductivity in the FeCh family is sensitive to external or chemical pressure, and high Tc is attained when the local structure (anion height) is optimized. The Bi-chalcogenide (BiCh2) family are a new group of layered superconductors with a wide variety of stacking structures. Their physical properties are also sensitive to external or chemical pressure. Recently, we revealed that the emergence of superconductivity and the Tc in this family correlate with the in-plane chemical pressure. Since the flexibility of crystal structure and electronic states are an advantage of the BiCh2 family for designing functionalities, I briefly review recent developments in this family as not only superconductors but also other functional materials.

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Electrical and Thermal Transport of Layered Bismuth-Sulfide EuBiS₂F at Temperatures between 300 and 623 K

Cited by 15 publications

References 21 publications

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS₂₋_xSe_x

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS₂₋_xSe_x

Thermoelectric properties of new Bi-chalcogenide layered compounds

Recent Advances in Layered Metal Chalcogenides as Superconductors and Thermoelectric Materials: Fe-Based and Bi-Based Chalcogenides

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Electrical and Thermal Transport of Layered Bismuth-Sulfide EuBiS2F at Temperatures between 300 and 623 K

Cited by 15 publications

References 21 publications

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS2−xSex

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS2−xSex

Thermoelectric properties of new Bi-chalcogenide layered compounds

Recent Advances in Layered Metal Chalcogenides as Superconductors and Thermoelectric Materials: Fe-Based and Bi-Based Chalcogenides

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Electrical and Thermal Transport of Layered Bismuth-Sulfide EuBiS₂F at Temperatures between 300 and 623 K

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS₂₋_xSe_x

Electronic Origins of Large Thermoelectric Power Factor of LaOBiS₂₋_xSe_x