Thermoelectric Properties of Ultralong Silver Telluride Hollow Nanofibers

Zhang, Miluo; Park, Hosik; Kim, Jiwon; Park, Hyounmyung; Wu, Tingjun; Kim, Seil; Park, Su-Dong; Choa, Yong‐Ho; Myung, Nosang V.

doi:10.1021/acs.chemmater.5b00960

Cited by 36 publications

(32 citation statements)

References 42 publications

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“…However, normally there is no clear operation temperature boundary for each type of TE materials, for instance, rare earth chalcogenides, group III–V compounds, oxide perovskites materials, borides and metal oxides can be applied in a vast range of temperature depending on specific compounds [10,17,36,38,39,40]. The inorganic materials are the most well-studied TE materials [3,7,10,11,12,36,41]. We have studied the thermoelectric properties of PbTe films [20] and silver telluride nanofibers [41].…”

Section: Introductionmentioning

confidence: 99%

“…The inorganic materials are the most well-studied TE materials [3,7,10,11,12,36,41]. We have studied the thermoelectric properties of PbTe films [20] and silver telluride nanofibers [41]. Additionally, Te nanostructures including nanowire [42], nanotree [42], and nanorice [43] were synthesized, which can be used to be embedded into other TE materials as nanocomposite [44,45,46] or converted to metal tellurides through cation exchange reaction [47,48].…”

Section: Introductionmentioning

confidence: 99%

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Development of Perovskite-Type Materials for Thermoelectric Application

Gao

2018

Materials

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115

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Oxide perovskite materials have a long history of being investigated for thermoelectric applications. Compared to the state-of-the-art tin and lead chalcogenides, these perovskite compounds have advantages of low toxicity, eco-friendliness, and high elemental abundance. However, because of low electrical conductivity and high thermal conductivity, the total thermoelectric performance of oxide perovskites is relatively poor. Variety of methods were used to enhance the TE properties of oxide perovskite materials, such as doping, inducing oxygen vacancy, embedding crystal imperfection, and so on. Recently, hybrid perovskite materials started to draw attention for thermoelectric application. Due to the low thermal conductivity and high Seebeck coefficient feature of hybrid perovskites materials, they can be promising thermoelectric materials and hold the potential for the application of wearable energy generators and cooling devices. This mini-review will build a bridge between oxide perovskites and burgeoning hybrid halide perovskites in the research of thermoelectric properties with an aim to further enhance the relevant performance of perovskite-type materials.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of Perovskite-Type Materials for Thermoelectric Application

Gao

2018

Materials

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115

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“…Similarly the various metal telluride such as ZnTe, PbTe, Ag 2 Te,, Bi 2 Te 3 , Bi 0.4 Sb 1.6 Te 3 (BiSbTe), nanoparticles with exceptional enhanced thermoelectrical properties has been synthesized for the use in thermoelectric device applications. Copper telluride nanowires/polyvinylidene fluoride were used as a building block to synthesize flexible thin films which exhibit room temperature electrical conductivity and Seebeck coefficient of 2490 S/cm and 9.6 μv/K respectively, ensuing in a power factor of 23 μW/(mK 2 ) at room temperature.…”

Section: Properties Of Metal Telluride Nanomaterialsmentioning

confidence: 99%

Metal Telluride Nanomaterials: Facile Synthesis, Properties and Applications for Third Generation Devices.

Jamwal

Mehta

2019

ChemistrySelect

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From the material science community, metal telluride semiconductor nanostructures have lately attracted a significant quantity of attention. On account of physics associated in quantum confinement, remarkable surface chemistry metal telluride became the most explored group of semiconductor nanomaterials. The intensive concern in this area originates from their exceptional optical, chemical and electronic properties which give rise to their potential use in the field of solar energy conversion, nonlinear optics, catalysis, thermoelectric and magnetic, as well as other areas. In the current review, shape and size‐controlled synthesis strategies, substantial properties and some selected applications for metal telluride nanostructures are highlighted, for the synthesis of nanoparticles each method is favourably analyzed.

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“…Therefore, synthesis of a few millimeter chalcogenide nanofibers has been realized by combining electrospinning with an additional process called the galvanic displacement reaction (Xiao et al, 2007b ; Chang et al, 2010a , b , 2014 ; Hangarter et al, 2010 ; Jung et al, 2010 , 2012 ; Park et al, 2010 , 2013 ; Rheem et al, 2010 ; Suh et al, 2012 , 2013 ; Elazem et al, 2013 ; Jeong et al, 2013 ; Liu et al, 2013 ; Wu et al, 2014 , 2015 ; Zhang et al, 2014 ), by which the electrospun nanofibers can be converted to desired hollow metal chalcogenides spontaneously. Several hollow nanofibers of chalcogens and metal chalcogenides [e.g., Te (Lee et al, 2011 ; Jeong et al, 2013 ), Ag 2 Te (Park et al, 2015 ; Zhang et al, 2015 ), and Pb x Se y Ni z (Zhang et al, 2014 )] have been successfully synthesized by this method in our group.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Thermoelectric Characterization of Lead Telluride Hollow Nanofibers

et al. 2018

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Lead telluride (PbTe) nanofibers were fabricated by galvanic displacement of electrospun cobalt nanofibers where their composition and morphology were altered by adjusting the electrolyte composition and diameter of sacrificial cobalt nanofibers. By employing Co instead of Ni as the sacrificial material, residue-free PbTe nanofibers were synthesized. The Pb content of the PbTe nanofibers was slightly affected by the Pb2+ concentration in the electrolyte, while the average outer diameter increased with Pb2+ concentration. The surface morphology of PbTe nanofibers was strongly dependent on the diameter of sacrificial nanofibers where it altered from smooth to rough surface as the Pb2+ concentration increased. Some of thermoelectric properties [i.e., thermopower (S) and electrical conductivity(σ)] were systematically measured as a function of temperature. Energy barrier height (Eb) was found to be one of the key factors affecting the thermoelectric properties–that is, higher energy barrier heights increased the Seebeck coefficient, but lowered the electrical conductivity.

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Thermoelectric Properties of Ultralong Silver Telluride Hollow Nanofibers

Cited by 36 publications

References 42 publications

Development of Perovskite-Type Materials for Thermoelectric Application

Development of Perovskite-Type Materials for Thermoelectric Application

Metal Telluride Nanomaterials: Facile Synthesis, Properties and Applications for Third Generation Devices.

Synthesis and Thermoelectric Characterization of Lead Telluride Hollow Nanofibers

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