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Synthesis of CuNiSn LDHs as highly efficient Fenton catalysts for degradation of phenol
Abstract A series of CuNiSn ternary layered double hydroxides (LDH) were synthesized as catalysts for degradation of phenol via Fenton reaction. At Cu/Ni ratios above 0.2, copper chloride hydroxide co-exists with LDH. Multivalent Cu+/Cu2+, Ni2+/Ni3+ and Sn2+/Sn4+ ions are present in LDH due to the electron transfer between metals in brucite-like sheets. The catalytic activity varies directly with the Cu+ percentage, and the maximum activity is achieved at Cu/Ni/Sn ratio of 1/2/0.75. This catalyst (Cu1Ni2Sn0.75) can mineralize 97.8% phenol under mild conditions and shows good stability. Multivalent Cu, Ni and Sn cations in LDH could construct a closed electron cycle. This allows the rapid regeneration of Cu+ active species through electron transfer within LDH rather than through slow Fenton-like reaction, as what usually happens in conventional Fenton catalysts. In addition, a positive synergistic effect between copper chloride hydroxide and LDH is observed in Cu1Ni2Sn0.75, favoring the formation of Cu+.
Graphical abstract Display Omitted
Highlights Multivalent Cu, Ni and Sn ions construct a closed electron cycle within LDH. Active Cu+ can be rapid regenerated without via Fenton-like reaction. Copper chloride hydroxide co-exists with LDH at Cu/Ni ratio above 0.2. Positive synergistic effect between two phases occurs at Cu/Ni ratio of 0.5.
Synthesis of CuNiSn LDHs as highly efficient Fenton catalysts for degradation of phenol
Abstract A series of CuNiSn ternary layered double hydroxides (LDH) were synthesized as catalysts for degradation of phenol via Fenton reaction. At Cu/Ni ratios above 0.2, copper chloride hydroxide co-exists with LDH. Multivalent Cu+/Cu2+, Ni2+/Ni3+ and Sn2+/Sn4+ ions are present in LDH due to the electron transfer between metals in brucite-like sheets. The catalytic activity varies directly with the Cu+ percentage, and the maximum activity is achieved at Cu/Ni/Sn ratio of 1/2/0.75. This catalyst (Cu1Ni2Sn0.75) can mineralize 97.8% phenol under mild conditions and shows good stability. Multivalent Cu, Ni and Sn cations in LDH could construct a closed electron cycle. This allows the rapid regeneration of Cu+ active species through electron transfer within LDH rather than through slow Fenton-like reaction, as what usually happens in conventional Fenton catalysts. In addition, a positive synergistic effect between copper chloride hydroxide and LDH is observed in Cu1Ni2Sn0.75, favoring the formation of Cu+.
Graphical abstract Display Omitted
Highlights Multivalent Cu, Ni and Sn ions construct a closed electron cycle within LDH. Active Cu+ can be rapid regenerated without via Fenton-like reaction. Copper chloride hydroxide co-exists with LDH at Cu/Ni ratio above 0.2. Positive synergistic effect between two phases occurs at Cu/Ni ratio of 0.5.
Synthesis of CuNiSn LDHs as highly efficient Fenton catalysts for degradation of phenol
Wang, Hao (author) / Zhang, Zeng (author) / Jing, Mengmeng (author) / Tang, Song (author) / Wu, Yan (author) / Liu, Wenshi (author)
Applied Clay Science ; 186
2019-12-31
Article (Journal)
Electronic Resource
English
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