Systematic Assessment of Precious Metal Recovery to Improve Environmental and Resource Protection

Chen, Yao; Shang, Hengjun; Ren, Yuqing; Yue, Yinghong; Li, Hexing

doi:10.1021/acsestengg.1c00453

Cited by 27 publications

(19 citation statements)

References 80 publications

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“…DOS originated from the Mo 4d states and S 3p states are observed to pass through the Fermi level as shown in Figure c, which verifies previous report that PMs would be reduced by oxidation of Mo 4+ and S 2– of MoS 2 to MoO 4 2– and SO 4 2– . Unexpectedly, the pyridine of Py-MoS 2 also contributes to the DOS, confirming that the pyridine group can act as electron donation, which not only increases the selectivity toward PM ions but also increases the interfacial electron transport efficiency. , Theoretically, Py-MoS 2 could reduce PM ions into metallic with higher redox potentials (Figure d), including Au 3+ , Pd 4+ , Ag + , and Pt 4+ . In the practical recovery process, Au 3+ , Pd 4+ , and Ag + were indeed reduced into metallic, while platinum was atomically dispersed over Py-MoS 2 in the form of Pt 2+ .…”

Section: Resultsmentioning

confidence: 99%

“…51,52 Theoretically, Py-MoS 2 could reduce PM ions into metallic with higher redox potentials (Figure 4d), including Au 3+ , Pd 4+ , Ag + , and Pt 4+ . 53 In the practical recovery process, Au 3+ , Pd 4+ , and Ag + were indeed reduced into metallic, while platinum was atomically dispersed over Py-MoS 2 in the form of Pt 2+ . The different morphologies and surface statuses lead to distinct removal efficiency for PMs.…”

Section: Precious Metal Recovery With Py-mosmentioning

confidence: 99%

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Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS₂

Wang

Luo

Zheng

et al. 2023

ACS Appl. Mater. Interfaces

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Rational design of functional material interfaces with welldefined physico-chemical-driven forces is crucial for achieving highly efficient interfacial chemical reaction dynamics for resource recovery. Herein, via an interfacial structure engineering strategy, precious metal (PM) coordination-active pyridine groups have been successfully covalently integrated into ultrathin 1T-MoS 2 (Py-MoS 2 ). The constructed Py-MoS 2 shows highly selective interfacial coordination bonding-assisted redox (ICBAR) functionality toward PM recycling. Py-MoS 2 shows state-of-theart high recovery selectivity toward Au 3+ and Pd 4+ within 13 metal cation mixture solutions. The related recycling capacity reaches up to 3343.00 and 2330.74 mg/g for Au 3+ and Pd 4+ , respectively. More importantly, above 90% recovery efficiencies have been achieved in representative PMs containing electronic solid waste leachate, such as computer processing units (CPU) and spent catalysts. The ICBAR mechanism developed here paves the way for interface engineering of the welldocumented functional materials toward highly efficient PM recovery.

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Section: Resultsmentioning

confidence: 99%

Section: Precious Metal Recovery With Py-mosmentioning

confidence: 99%

Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS₂

Wang

Luo

Zheng

et al. 2023

ACS Appl. Mater. Interfaces

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“…Hence, we further evaluated oxidation and reduction processes occurring at ambient temperature under photocatalytic conditions. Photocatalytic oxidation is one of the key technologies for diminishing environmental pollutants and preventing poisoning deactivation. − …”

Section: Resultsmentioning

confidence: 99%

Operando Spectroscopic Observation of CO Oxidation on a Pt/TiO₂ Catalyst in NO–CO Mixtures under Dark and UV Illumination

Park

Hwang²,

Eom³

et al. 2022

Energy Fuels

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The importance of catalytic CO oxidation for exhaust gas processing has inspired the development of efficient and durable catalysts that can be operated at low temperatures, as exemplified by supported noble metals. However, most of the related studies have neglected the potential effects of co-present exhaust gas components, such as NO. Herein, we compared the performances of platinized and bare TiO2 for the ambient-temperature (photo)catalytic oxidation of CO by O2 in the co-presence of NO and used in situ Fourier transform infrared spectroscopy to elucidate the effects of platinization on the efficiency and mechanism of this oxidation. Catalytic CO oxidation was accompanied by competitive NO oxidation both in the dark and under ultraviolet (UV) illumination. In the dark, Pt/TiO2 achieved a higher CO removal efficiency than bare TiO2, which was ascribed to the enhanced adsorption of O2 and CO and the inhibition of NO overoxidation (mainly the oxidation of the monodentate nitrito form to the bidentate nitrate form). Under UV illumination, Pt/TiO2 efficiently promoted CO oxidation at photocatalytically active sites (Pt0–CO) by suppressing NO overoxidation and increasing the reduction of NO to N2O. Hence, the enhanced CO oxidation performance of Pt/TiO2 was due to its ability to control NO oxidation and reduction at ambient temperature, which presents a new strategy for the design of low-temperature CO oxidation catalysts.

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“…The changes occurring in solvent composition after photocatalytic dissolution of Au and Pt were analyzed by high-resolution nuclear magnetic resonance (NMR) spectroscopy. First, a background experiment was performed with deuterated chloroform (7.26 ppm in 1 H NMR and 77.16 ppm in 13 C NMR) as the test solvent, and the peak at 0 ppm was derived from the internal standard tetramethylsilane (TMS). For the MeCN system, an obvious peak at 1.97 ppm in the 1 H NMR spectrum was assigned to the hydrogens (H) on the methyl group (À CH 3 ) pf MeCN (Figures S4a and S5a).…”

Section: Resultsmentioning

confidence: 99%

Photocatalytic Dissolution of Precious Metals by TiO₂ through Photogenerated Free Radicals

Chen

Guan

et al. 2022

Angewandte Chemie

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Exploring the pathways for photocatalytic dissolution of precious metals (PMs) is crucial for optimizing recovery. In this work, we systematically investigated the selectivity and solvation effects observed for dissolution by focusing on photocatalysis, precious metals and solvents. By combining transient characterization, reaction kinetics, and density functional theory, we determined that the radicals generated in photocatalysis were the key active species in the entire reaction. The cyano functional group in the solvent was the driving factor for dissolution of gold, and the importance of chlorine radicals for dissolution of platinum group precious metals was further confirmed. In addition, the catalytic properties of different precious metals can promote different transformations of functional groups, leading to selective dissolution. The structures of photocatalytic precious metal leaches also precisely explains the special coordination forms of precious metals and functional group ligands.

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Systematic Assessment of Precious Metal Recovery to Improve Environmental and Resource Protection

Cited by 27 publications

References 80 publications

Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS₂

Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS₂

Operando Spectroscopic Observation of CO Oxidation on a Pt/TiO₂ Catalyst in NO–CO Mixtures under Dark and UV Illumination

Photocatalytic Dissolution of Precious Metals by TiO₂ through Photogenerated Free Radicals

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Systematic Assessment of Precious Metal Recovery to Improve Environmental and Resource Protection

Cited by 27 publications

References 80 publications

Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS2

Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS2

Operando Spectroscopic Observation of CO Oxidation on a Pt/TiO2 Catalyst in NO–CO Mixtures under Dark and UV Illumination

Photocatalytic Dissolution of Precious Metals by TiO2 through Photogenerated Free Radicals

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Product

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Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS₂

Interfacial Coordination Bonding-Assisted Redox Mechanism-Driven Highly Selective Precious Metal Recovery on Covalent-Functionalized Ultrathin 1T-MoS₂

Operando Spectroscopic Observation of CO Oxidation on a Pt/TiO₂ Catalyst in NO–CO Mixtures under Dark and UV Illumination

Photocatalytic Dissolution of Precious Metals by TiO₂ through Photogenerated Free Radicals