A Water-Stable Luminescent W/S/Cu Heterothiometallic Cluster for Detection of TNP

Zhu, Yuan; Xia, Hongchen; Zhang, Jinfang; Zhang, Chi

doi:10.1007/s10876-019-01749-8

Cited by 7 publications

(2 citation statements)

References 48 publications

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“…Among them, many scholars have done a lot of work in thermal management, but there is still insufficient research on the surface properties and there are few studies on achieving higher interfacial evaporation rates using other types of energy. [6][7][8][9][10] In terms of energy utilization, the direct use of sunlight is very cost effective, but the evaporation rate that can be achieved is limited due to the relative low energy density of solar illumination. [11] Therefore, devices solely powered by solar energy are not suitable for practical and industrial applications that require high-speed evaporations such as distillations, purification, sterilization, and so on.…”

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confidence: 99%

Graphene–Carbon Composites for Solar and Low‐Voltage Powered Efficient Interfacial Evaporation

Liu

Wang

Bradley

et al. 2020

Advanced Sustainable Systems

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Nanocarbon materials have great potential for sustainable energy harvest and energy utilizations, such as solar thermal stream generation, and interfacial evaporation. However, the evaporation rate is far too low for practical applications. The technologies are not ready yet for industries requiring rapid, energy‐efficient, and low‐cost evaporation processes such as distillation and sterilization. A flexible ultrathin graphene–carbon cloth (CC)‐based carbon–carbon composites is prepared by in situ electrochemical reduction of graphene oxide. The carbon–carbon composite materials demonstrate high performance in photothermal evaporation; more importantly, all carbon‐based devices can also be operated as low‐voltage Joule heating elements in wide temperature range up to 389 °C. Even when a very low voltage of 3 V is applied, the graphene–CC heater can reach a very high heating speed up to 112 °C s–1, and a steady‐state temperature up to 292 °C within 10 s only. The low‐voltage heater promises to be the most effective solution for high‐speed interfacial evaporation since its evaporation rate can reach up to 45.87 kg m−2 h−1, enhanced by one order of magnitude compared to the best solar power photothermal seawater desalination devices ever reported.

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confidence: 99%

Graphene–Carbon Composites for Solar and Low‐Voltage Powered Efficient Interfacial Evaporation

Liu

Wang

Bradley

et al. 2020

Advanced Sustainable Systems

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“…Polynuclear metal coordination polymers are more stable than monometallic-centered complexes and thus have a promising future [8]. In the past few decades, mononuclear metal sul de composite precursors [MS 4 ] 2and [MOS 3 ] 2-(M = Mo, W) anions have been widely used in the preparation of Mo(W)/S/Cu(Ag) clusters, mainly because of their relevance to sensing properties [9,10], optical properties [11,12] and the catalytic decomposition of hydrogen sul de [13]. At present, the chemical study of sul de-bridging dinuclear clusters composed of [M 2 S 4 ] core (M= Mo, W) prepared from the above-mentioned mononuclear precursors and various transition metals has attracted extensive attention [14][15][16].…”

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confidence: 99%

Construction of Symmetric Mo/S/Ag Cluster Complexes from a Dinuclear Molybdnum Precursor [nPr4N]2[(edt)2Mo2O2(µ-S)2] (edt = -SCH2CH2S-)

Chen,

Liang,

Pan

et al. 2024

Preprint

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In this paper, we have demonstrated that symmetric complexes [(edt)2Mo2O2(µ-S)2Ag2(dppm)2] (2, edt = 1,2-ethanedithiolate dianion, dppm = bis(diphenylphosphino)methane) and [(µ-Cl)2Ag4(µ3-Cl)2(dppm)2]·4DMF (3, DMF = N,N-dimethylformamide), were generated by combining a dinuclear molybdnum precursor [nPr4N]2[(edt)2Mo2O2(µ-S)2] (1) with two equimolar AgNO3 and dppm in DMF and CH2Cl2 mixed solutions. Treatment of complex 1 with AgBr in acetonitrile followed by addition of (NH4)2S produced a dodecanuclear Mo–Ag–S cage cluster [nPr4N]2[{Mo2Ag2S2O2(edt)2}3(µ6-S)]·1.5CH3CN (4). Complexes 2−4 have been characterized by were characterized by infrared, 1H NMR, UV-vis, and fluorescence spectroscopies. Moreover, molecular structures of complexes 2−4 have been established by single-crystal X-ray crystallography.

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Construction of Mo/S/Ag Cluster Complexes from Dinuclear Molybdenum Precursors [R₄N]₂[(edt)₂Mo₂S₂(μ‐S)₂] (R = Et, ⁿPr; edt = ⁻SCH₂CH₂S⁻)

Chen,

Liang,

Pan

et al. 2024

ChemistrySelect

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We have demonstrated that complexes [(edt)2Mo2O2(μ‐S)2Ag2(dppm)2]·4CH3OH·DMF (2, edt = 1,2‐ethanedithiolate dianion, dppm = bis(diphenylphosphino)methane, DMF = N,N‐dimethylformamide) and [(μ‐Cl)2Ag4(μ3‐Cl)2(dppm)2]·4DMF (3), were generated by combining a dinuclear molybdenum precursor [Et4N]2[(edt)2Mo2S2(μ‐S)2] (1a) with two equimolar AgCl and dppm in a CH3OH‐DMF mixed solution. Treatment of complex 1a with one equimolar AgCl and DPEPhos in CH3OH and DMF mixed solutions, producing complex [Et4N][(edt)2Mo2S2(μ‐S)2Ag(DPEPhos)]·CH3OH (4, DPEPhos = bis(2‐diphenylphosphinophenyl)ether). Treatment of complex [nPr4N]2[(edt)2Mo2S2(μ‐S)2] (1b) with AgBr in acetonitrile followed by addition of (NH4)2S produced a dodecanuclear Mo–Ag–S cage cluster [nPr4N]2[{Mo2Ag2S2O2(edt)2}3(μ6‐S)]·1.5CH3CN (5). Complexes 2−5 have been characterized by infrared(IR), 1H NMR, UV‐vis, and fluorescence spectroscopies. Moreover, molecular structures of complexes 2−5 have been established by single‐crystal X‐ray crystallography.

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A Water-Stable Luminescent W/S/Cu Heterothiometallic Cluster for Detection of TNP

Cited by 7 publications

References 48 publications

Graphene–Carbon Composites for Solar and Low‐Voltage Powered Efficient Interfacial Evaporation

Graphene–Carbon Composites for Solar and Low‐Voltage Powered Efficient Interfacial Evaporation

Construction of Symmetric Mo/S/Ag Cluster Complexes from a Dinuclear Molybdnum Precursor [nPr4N]2[(edt)2Mo2O2(µ-S)2] (edt = -SCH2CH2S-)

Construction of Mo/S/Ag Cluster Complexes from Dinuclear Molybdenum Precursors [R₄N]₂[(edt)₂Mo₂S₂(μ‐S)₂] (R = Et, ⁿPr; edt = ⁻SCH₂CH₂S⁻)

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A Water-Stable Luminescent W/S/Cu Heterothiometallic Cluster for Detection of TNP

Cited by 7 publications

References 48 publications

Graphene–Carbon Composites for Solar and Low‐Voltage Powered Efficient Interfacial Evaporation

Graphene–Carbon Composites for Solar and Low‐Voltage Powered Efficient Interfacial Evaporation

Construction of Symmetric Mo/S/Ag Cluster Complexes from a Dinuclear Molybdnum Precursor [nPr4N]2[(edt)2Mo2O2(µ-S)2] (edt = -SCH2CH2S-)

Construction of Mo/S/Ag Cluster Complexes from Dinuclear Molybdenum Precursors [R4N]2[(edt)2Mo2S2(μ‐S)2] (R = Et, nPr; edt = −SCH2CH2S−)

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Construction of Mo/S/Ag Cluster Complexes from Dinuclear Molybdenum Precursors [R₄N]₂[(edt)₂Mo₂S₂(μ‐S)₂] (R = Et, ⁿPr; edt = ⁻SCH₂CH₂S⁻)