Ferromagnetic behavior of non-stoichiometric ZnS microspheres with a nanoplate-netted surface

Dong, Jing; Zeng, Xianghua; Xia, Weiwei; Zhang, Xiuyun; Zhou, Min; Wang, Caixia

doi:10.1039/c7ra02521a

Cited by 35 publications

(15 citation statements)

References 26 publications

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“…Moreover, the XPS spectra of the S 2p core level can be resolved into triple peaks, which were labeled as I, II and III (Figure d). The peaks of I and III were ascribed to S 2p1/2 and S 2p3/2, respectively, while the peak of II can be ascribed to the sulfur vacancies . The larger integrated intensity of II in NiFeS 1‐x UNM confirmed the existence of a larger number of sulfur vacancies.…”

Section: Figurementioning

confidence: 72%

“…The electrochemical capacitance measurements (Figure S6) showed that the electrochemical active surface areas (ECSA) of NiFeS 1‐x UNM (4.2 mF cm −2 ) were much larger than those of NiFeS NS (2.8 mF cm −2 ) as displayed in Figure e. This result proved that more active sites existed in NiFeS 1‐x UNM due to their ultrathin nanomesh structure . Notably, NiFeS 1‐x UNM still showed better performance than NiFeS NS after normalization to ECSA (Figure f and Figure S7), demonstrating that NiFeS 1‐x UNM owned higher intrinsic activity.…”

Section: Figurementioning

confidence: 99%

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Ultrathin NiFeS Nanomeshes with Sulfur Vacancy for Electrocatalytic Hydrogen Evolution

Wang

et al. 2020

ChemElectroChem

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The development of novel transition metal‐based electrocatalysts with high hydrogen evolution reaction (HER) activity is significant. NiFeS shows promising potential for HER because of its suitable electronic configuration. However, the low ratio of accessible active sites hinders its HER performance. Processing NiFeS into ultrathin nanosheets with abundant pores and vacancies can increase the number of active sites and enhance the intrinsic activity of active sites, but, the synthesis is still challenging. Here, we developed a facile two‐step conversion strategy to prepare ultrathin NiFeS nanomeshes with sulfur vacancies (NiFeS1‐x UNM). The overpotential of NiFeS1‐x UNM for 10 mA cm−2 was only 81 mV in acid electrolyte, much lower than the counterpart of NiFeS nanosheets (NiFeS NS) without sulfur vacancies (118 mV). Combining the electrochemical characterizations and Density Functional Theory (DFT) calculations, we revealed that the superior performance of NiFeS1‐x UNM originated from the increased active sites, accelerated electron/mass transfer and improved intrinsic activity.

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Section: Figurementioning

confidence: 72%

Section: Figurementioning

confidence: 99%

Ultrathin NiFeS Nanomeshes with Sulfur Vacancy for Electrocatalytic Hydrogen Evolution

Wang

et al. 2020

ChemElectroChem

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“…Since at 300 K both the paramagnetic and diamagnetic components are linear with magnetic field, the low field increase of magnetization suggests an additional component contributing to the measured magnetization. We suppose that in addition to the paramagnetic and diamagnetic components discussed earlier, there is also an extra component in the pre-kesterite nanopowder that has originated from ferro/ferrimagnetic impurities linked to the precursor system or formed during the high energy ball milling (e.g., some likely left-over zinc sulfide ZnS reported to show d 0 ferromagnetism [20,21]). We note that such a situation has been widely encountered, for instance, in a series of gallium nitride-and antimonide-based magnetic semiconductors synthesized with magnetic transition metal concentrations close to the solubility limits [38][39][40].…”

Section: Magnetic Studymentioning

confidence: 95%

“…Given the above observations and since one of the potential metal centers in kesterite is d-orbital magnetic, i.e., Cu 2+ with the formal 3d 9 configuration while the expected copper sites are nominally Cu 1+ with diamagnetic configuration 3d 10 , kesterites's magnetic properties may come to play a significant role in defining its fundamentals-under certain stoichiometry and synthesis conditions these two types of copper centers can coexist in the kesterite's lattice. In addition, the high propensity of kesterite to accommodate variable element stoichiometries, extended site occupancy/disorder features, and various defects makes its nanocrystalline forms the firm candidates for the so-called d 0 magnetism observed in many disordered/defected nanomaterials including formally diamagnetic zinc sulfide ZnS [20][21][22]. Therefore, the combination of nuclear magnetic resonance measurements sensitive to close range ordering and local field peculiarities with measurements of overall magnetism reflecting averaged magnetic fields may yield a comprehensive insight into the characteristics of kesterite.…”

Section: Introductionmentioning

confidence: 99%

Magnetism of Kesterite Cu2ZnSnS4 Semiconductor Nanopowders Prepared by Mechanochemically Assisted Synthesis Method

et al. 2020

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High energy ball milling is used to make first the quaternary sulfide Cu2ZnSnS4 raw nanopowders from two different precursor systems. The mechanochemical reactions in this step afford cubic pre-kesterite with defunct semiconducting properties and showing no solid-state 65Cu and 119Sn MAS NMR spectra. In the second step, each of the milled raw materials is annealed at 500 and 550 °C under argon to result in tetragonal kesterite nanopowders with the anticipated UV-Vis-determined energy band gap and qualitatively correct NMR characteristics. The magnetic properties of all materials are measured with SQUID magnetometer and confirm the pre-kesterite samples to show typical paramagnetism with a weak ferromagnetic component whereas all the kesterite samples to exhibit only paramagnetism of relatively decreased magnitude. Upon conditioning in ambient air for 3 months, a pronounced increase of paramagnetism is observed in all materials. Correlations between the magnetic and spectroscopic properties of the nanopowders including impact of oxidation are discussed. The magnetic measurements coupled with NMR spectroscopy appear to be indispensable for comprehensive kesterite evaluation.

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“…The peak at low binding energy (162.00 eV) corresponds to the Cu-S bond, and the peak at the high binding energy (165.28 eV) corresponds to the Ga-S bond [40]. Furthermore, the intermediate peak observed near 163.74 eV corresponds to sulfur vacancy, which is attributed to sulfur defects formed at the CuGaS2 or heterojunction interface [41]. These XPS results demonstrate the presence of structural defects on the heterojunction 0.5CuS@1.5CuGaS2 catalyst surface and predict that the site can act as a reactive site.…”

Section: Characteristics Of Cus Cugas 2 and Cus@cugas 2 Nanoparticlesmentioning

confidence: 99%

Enhancement of Hydrogen Productions by Accelerating Electron-Transfers of Sulfur Defects in the CuS@CuGaS2 Heterojunction Photocatalysts

et al. 2019

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CuS and CuGaS 2 heterojunction catalysts were used to improve hydrogen production performance by photo splitting of methanol aqueous solution in the visible region in this study. CuGaS 2 , which is a chalcogenide structure, can form structural defects to promote separation of electrons and holes and improve visible light absorbing ability. The optimum catalytic activity of CuGaS 2 was investigated by varying the heterojunction ratio of CuGaS 2 with CuS. Physicochemical properties of CuS, CuGaS 2 and CuS@CuGaS 2 nanoparticles were confirmed by X-ray diffraction, ultraviolet visible spectroscopy, high-resolution transmission electron microscopy, scanning electron microscopy and energy dispersive X-ray spectroscopy. Compared with pure CuS, the hydrogen production performance of CuGaS 2 doped with Ga dopant was improved by methanol photolysis, and the photoactivity of the heterogeneous CuS@CuGaS 2 catalyst was increased remarkably. Moreover, the 0.5CuS@1.5CuGaS 2 catalyst produced 3250 µmol of hydrogen through photolysis of aqueous methanol solution under 10 h UV light irradiation. According to the intensity modulated photovoltage spectroscopy (IMVS) results, the high photoactivity of the CuS@CuGaS 2 catalyst is attributed to the inhibition of recombination between electron-hole pairs, accelerating electron-transfer by acting as a trap site at the interface between CuGaS 2 structural defects and the heterojunction.

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Ferromagnetic behavior of non-stoichiometric ZnS microspheres with a nanoplate-netted surface

Cited by 35 publications

References 26 publications

Ultrathin NiFeS Nanomeshes with Sulfur Vacancy for Electrocatalytic Hydrogen Evolution

Ultrathin NiFeS Nanomeshes with Sulfur Vacancy for Electrocatalytic Hydrogen Evolution

Magnetism of Kesterite Cu2ZnSnS4 Semiconductor Nanopowders Prepared by Mechanochemically Assisted Synthesis Method

Enhancement of Hydrogen Productions by Accelerating Electron-Transfers of Sulfur Defects in the CuS@CuGaS2 Heterojunction Photocatalysts

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