Properties of pulse plated SnSe films

Ananthi, K; Thilakavathy, K.; Muthukumarasamy, N.; Dhanapandian, S.; Murali, K. R.

doi:10.1007/s10854-011-0595-3

Cited by 9 publications

(8 citation statements)

References 12 publications

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“…The average particle size is 9.3 ± 1.7 nm [ Figure S14 Figure S14(c)]. [72] Characterizations of Ag2Se nanoparticles are presented in Figure S15, which shows that the morphology of Ag2Se is bigger and non-uniform in comparison with those of the other metal chalcogenide nanostructures; the binding energies of Ag 3d and Se 3d are consistent with those of reported Ag2Se. [73] The dried nanopowders were consolidated into pellets by the SPS technique, and the sintering parameters and relative density are listed in Table S7.…”

Section: Resultssupporting

confidence: 60%

Robust scalable synthesis of surfactant-free thermoelectric metal chalcogenide nanostructures

Han

et al. 2015

Nano Energy

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, S. Xue. (2015). Robust scalable synthesis of surfactant-free thermoelectric metal chalcogenide nanostructures. Nano Energy, Robust scalable synthesis of surfactant-free thermoelectric metal chalcogenide nanostructures AbstractA robust low-cost ambient aqueous method for the scalable synthesis of surfactant-free nanostructured metal chalcogenides (MaXb, M=Cu, Ag, Sn, Pb, and Bi; X=S, Se, and Te; a=1 or 2; and b=1 or 3) is developed in this work. The effects of reaction parameters, such as precursor concentration, ratio of precursors, and amount of reducing agent, on the composition, size, and shape of the resultant nanostructures have been comprehensively investigated. This environmentally friendly approach is capable of producing metal chalcogenide nanostructures in a one-pot reaction on a large scale, which were investigated for their thermoelectric properties towards conversion of waste heat into electricity. The results demonstrate that the thermoelectric properties of these metal chalcogenide nanostructures are strongly dependent on the types of metal chalcogenides, and their figure of merits are comparable with previously reported figures for their bulk or nanostructured counterparts.

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Section: Resultssupporting

confidence: 60%

Robust scalable synthesis of surfactant-free thermoelectric metal chalcogenide nanostructures

Han

et al. 2015

Nano Energy

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“…This electrochemical synthesis process is scalable, simple, rapid, and cost-effective and it gives great control of the thickness, crystallinity, composition, and morphology. Electrodeposition has been extensively applied to fabricate various metal chalcogenide thermoelectric materials (Figure 7), such as Bi 2 Te 3 films [59,72,73,[82][83][84][85][86][87][88][89], Bi 2 Te 3 nanowire arrays [90][91][92][93], Bi 2 Te 3 nanotube arrays [94], Cu 2 Te films [95,96], Cu 2 Te nanowires [97], SnSe films [98][99][100][101], and so on.…”

Section: Electrodeposition Methodsmentioning

confidence: 99%

“…2019, 9, x FOR PEER REVIEW 9 of 19 composition, and morphology. Electrodeposition has been extensively applied to fabricate various metal chalcogenide thermoelectric materials (Figure 7), such as Bi2Te3 films [59,72,73,[82][83][84][85][86][87][88][89], Bi2Te3 nanowire arrays [90][91][92][93], Bi2Te3 nanotube arrays [94], Cu2Te films [95,96], Cu2Te nanowires [97], SnSe films [98][99][100][101], and so on. (h) cross-sectional views of the electrodeposited SnSe films.…”

Section: Electrodeposition Methodsmentioning

confidence: 99%

Solution-Based Synthesis and Processing of Metal Chalcogenides for Thermoelectric Applications

et al. 2019

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Metal chalcogenide materials are current mainstream thermoelectric materials with high conversion efficiency. This review provides an overview of the scalable solution-based methods for controllable synthesis of various nanostructured and thin-film metal chalcogenides, as well as their properties for thermoelectric applications. Furthermore, the state-of-art ink-based processing method for fabrication of thermoelectric generators based on metal chalcogenides is briefly introduced. Finally, the perspective on this field with regard to material production and device development is also commented upon.

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“…The average crystallite size of the as-synthesized SnSe was determined to be ~42 nm using Williamson-Hall method[90]. Apart from XRD, XPS can also be used to analyze the phase of SnSe[81,[264][265][266].Figure 25(b)shows a partial high resolution XPS spectrum of SnSe synthesized via solvothermal route[81], indicating the existence of one valence state for Sn and Se. The peaks of Sn 3d 3/2 and Sn 3d 5/2 were singlet and no accessorial binding energy peaks can be found, indicating the divalent characteristic of Sn ions, and a binding energy peak of Se 3d was also observed at 53.7 eV, suggesting Se 2+[81].To determine the compositional ratio of Sn and Se in the materials, EDS[267][268][269] and high-resolution electron probe micro-analysis (EPMA)[81,91,128,257] are commonly used.Figure 25(c)shows a typical EDS spot analysis of SnSe synthesized by microwave-assisted solvothermal route, the atomic ratio of Sn and Se was roughly 1:1.…”

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confidence: 99%

High-performance SnSe thermoelectric materials: Progress and future challenge

Chen

Zhao

Zou

2018

Progress in Materials Science

457

410

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Thermoelectric materials offer an alternative opportunity to tackle the energy crisis and environmental problems by enabling the direct solid-state energy conversion. As a promising candidate with full potentials for the next generation thermoelectrics, tin selenide (SnSe) and its associated thermoelectric materials have been attracted extensive attentions due to their ultralow thermal conductivity and high electrical transport performance (power factor). To provide a thorough overview of recent advances in SnSe-based thermoelectric materials that have been revealed as promising thermoelectric materials since 2014, here, we first focus on the inherent relationship between the structural characteristics and the supreme thermoelectric performance of SnSe, including the thermodynamics, crystal structures, and electronic structures. The effects of phonon scattering, pressure or strain, and oxidation behavior on the thermoelectric performance of SnSe are discussed in detail. Besides, we summarize the current theoretical calculations to predict and understand the thermoelectric performance of SnSe, and provide a comprehensive summary on the current synthesis, characterization, and thermoelectric performance of both SnSe crystals and polycrystals, and their associated materials. In the end, we point out the controversies, challenges and strategies toward future enhancements of the SnSe thermoelectric materials.

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Properties of pulse plated SnSe films

Cited by 9 publications

References 12 publications

Robust scalable synthesis of surfactant-free thermoelectric metal chalcogenide nanostructures

Robust scalable synthesis of surfactant-free thermoelectric metal chalcogenide nanostructures

Solution-Based Synthesis and Processing of Metal Chalcogenides for Thermoelectric Applications

High-performance SnSe thermoelectric materials: Progress and future challenge

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