Revisiting Metal Sulfide Semiconductors: A Solution‐Based General Protocol for Thin Film Formation, Hall Effect Measurement, and Application Prospects

Shinde, Dipak V.; Patil, Supriya A.; Cho, Keumnam; Ahn, Do Young; Shrestha, Nabeen K.; Mane, Rajaram S.; Lee, Joong Kee; Han, Sung‐Hwan

doi:10.1002/adfm.201500964

Cited by 70 publications

(45 citation statements)

References 65 publications

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“…Herein, we report for the first time, to the best of our knowledge, a method for fabricating various amounts of nano‐CuS in/on a 3D MOF, which gives rise to nano‐CuS( x wt %)@Cu‐BTC ( x =1.4, 5.3, 8.8, 28, and 56) and nano‐CuS(99 wt %) (Scheme ). The series of composites were prepared by a simple solution infiltration method, using Cu‐BTC as a sacrificial template and a EtOH solution of thioacetamide as the sulfide source with the control of the reaction time and temperature. There have been some reports of the synthesis of metal oxides using MOFs as sacrificial templates, but none of metal sulfide.…”

Section: Methodsmentioning

confidence: 99%

Copper–Organic Framework Fabricated with CuS Nanoparticles: Synthesis, Electrical Conductivity, and Electrocatalytic Activities for Oxygen Reduction Reaction

2016

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To apply electrically nonconductive metal-organic frameworks (MOFs) in an electrocatalytic oxygen reduction reaction (ORR), we have developed an ew method for fabricating various amounts of CuS nanoparticles (nano-CuS) in/on a3 DC u-MOF,[ Cu 3 (BTC) 2 ·(H 2 O) 3 ]( BTC = 1,3,5-benzenetricarboxylate). As the amount of nano-CuS increases in the composite,the electrical conductivity increases exponentially by up to circa 10 9 -fold, while porosity decreases, compared with that of the pristine Cu-MOF.T he composites, nano-CuS(x wt %)@Cu-BTC,exhibit significantly higher electrocatalytic ORR activities than Cu-BTC or nano-CuS in an alkaline solution. The onset potential, electron transfer number,and kinetic current density increase when the electrical conductivity of the material increases but decrease when the material has apoor porosity,which shows that the two factors should be finely tuned by the amount of nano-CuS for ORR application. Of these materials,C uS(28 wt %)@Cu-BTC exhibits the best activity,s howing the onset potential of 0.91 Vv s. RHE, quasi-four-electron transfer pathway,a nd ak inetic current density of 11.3 mA cm À2 at 0.55 Vv s. RHE.Scheme 1. Synthesis of nano-CuS(x wt %)@Cu-BTCand nano-CuS-(99 wt %).Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: http://dx.

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Section: Methodsmentioning

confidence: 99%

Copper–Organic Framework Fabricated with CuS Nanoparticles: Synthesis, Electrical Conductivity, and Electrocatalytic Activities for Oxygen Reduction Reaction

2016

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“…26). 515 The flexible DSSC with the NiS CE exhibited a high PCE of 9.50% (vs. 8.97% for the device with Pt CE). The Wu group deposited CoS and NiS on FTO by a simple electrodeposition method and the morphology of the films was tuned by adding different amounts of ammonia (shown in Fig.…”

Section: Chalcogenidesmentioning

confidence: 96%

Counter electrodes in dye-sensitized solar cells

et al. 2017

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Dye-sensitized solar cells (DSSCs) are regarded as prospective solar cells for the next generation of photovoltaic technologies and have become research hotspots in the PV field. The counter electrode, as a crucial component of DSSCs, collects electrons from the external circuit and catalyzes the redox reduction in the electrolyte, which has a significant influence on the photovoltaic performance, long-term stability and cost of the devices. Solar cells, dye-sensitized solar cells, as well as the structure, principle, preparation and characterization of counter electrodes are mentioned in the introduction section. The next six sections discuss the counter electrodes based on transparency and flexibility, metals and alloys, carbon materials, conductive polymers, transition metal compounds, and hybrids, respectively. The special features and performance, advantages and disadvantages, preparation, characterization, mechanisms, important events and development histories of various counter electrodes are presented. In the eighth section, the development of counter electrodes is summarized with an outlook. This article panoramically reviews the counter electrodes in DSSCs, which is of great significance for enhancing the development levels of DSSCs and other photoelectrochemical devices.

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“…Herein, we report for the first time,t ot he best of our knowledge,amethod for fabricating various amounts of nano-CuS in/on a3 DM OF,w hich gives rise to nano-CuS(x wt %)@Cu-BTC (x = 1.4, 5.3, 8.8, 28, and 56) and nano-CuS(99 wt %) (Scheme 1). Thes eries of composites were prepared by as imple solution infiltration method, using Cu-BTC as as acrificial template and aE tOH solution of thioacetamide as the sulfide source [35] with the control of the reaction time and temperature.T here have been some reports of the synthesis of metal oxides using MOFs as sacrificial templates, [36][37][38] but none of metal sulfide.Inmost of those cases,t emplate MOFs were completely consumed during the formation of the NPs,a nd only NPs and/or carbon was left. Thep resent solution infiltration method enables the amount of CuS formed in/on the MOF to be easily controllable.B yi ncreasing the amount of nano-CuS in the material, electrical conductivity increases by up to 10 9 -fold, while porosity decreases,c ompared to those of the pristine Cu-BTC.InORR, the catalytic performance of the composite materials significantly increases,asshown by increases in the onset voltage,e lectron transfer number,a nd kinetic current density,c ompared with those of the pristine MOF and nano-CuS.T his is due to the synergistic effect of two different materials,w hich provide the porosity and the electrical conductivity,respectively.Inthe present composite materials, nano-CuS(28 wt %)@Cu-BTC shows the best ORR activity.…”

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confidence: 99%

Copper–Organic Framework Fabricated with CuS Nanoparticles: Synthesis, Electrical Conductivity, and Electrocatalytic Activities for Oxygen Reduction Reaction

2016

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To apply electrically nonconductive metal-organic frameworks (MOFs) in an electrocatalytic oxygen reduction reaction (ORR), we have developed a new method for fabricating various amounts of CuS nanoparticles (nano-CuS) in/on a 3D Cu-MOF, [Cu (BTC) ⋅(H O) ] (BTC=1,3,5-benzenetricarboxylate). As the amount of nano-CuS increases in the composite, the electrical conductivity increases exponentially by up to circa 10 -fold, while porosity decreases, compared with that of the pristine Cu-MOF. The composites, nano-CuS(x wt %)@Cu-BTC, exhibit significantly higher electrocatalytic ORR activities than Cu-BTC or nano-CuS in an alkaline solution. The onset potential, electron transfer number, and kinetic current density increase when the electrical conductivity of the material increases but decrease when the material has a poor porosity, which shows that the two factors should be finely tuned by the amount of nano-CuS for ORR application. Of these materials, CuS(28 wt %)@Cu-BTC exhibits the best activity, showing the onset potential of 0.91 V vs. RHE, quasi-four-electron transfer pathway, and a kinetic current density of 11.3 mA cm at 0.55 V vs. RHE.

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Revisiting Metal Sulfide Semiconductors: A Solution‐Based General Protocol for Thin Film Formation, Hall Effect Measurement, and Application Prospects

Cited by 70 publications

References 65 publications

Copper–Organic Framework Fabricated with CuS Nanoparticles: Synthesis, Electrical Conductivity, and Electrocatalytic Activities for Oxygen Reduction Reaction

Copper–Organic Framework Fabricated with CuS Nanoparticles: Synthesis, Electrical Conductivity, and Electrocatalytic Activities for Oxygen Reduction Reaction

Counter electrodes in dye-sensitized solar cells

Copper–Organic Framework Fabricated with CuS Nanoparticles: Synthesis, Electrical Conductivity, and Electrocatalytic Activities for Oxygen Reduction Reaction

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