This work highlights the benefit of designing mixed-metal (Cr/Fe) MOFs for enhanced chemical stability and catalytic activity. A robust and stable mixed-metal MIL-101(Cr/Fe) was prepared through a HF-free direct hydrothermal route with Fe3+ content up to 21 wt%. The incorporation of Fe3+ cations in the crystal structure was confirmed by 57Fe Mössbauer spectrometry. The catalytic performance of the mixed metal MIL-101(Cr/Fe) was evaluated in the Prins reaction. MIL-101(Cr/Fe) exhibited a higher catalytic activity compared to MIL-101(Cr), improved chemical stability compared to MIL-101(Fe) and a higher catalytic activity for bulky substrates compared to MIL-100(Fe). In situ infra-red spectroscopy study suggests that the incorporation of Fe3+ ions in MIL-101 structure leads to an increase in Lewis acid sites. It was thus concluded that the predominant role of Cr3+ ions was to maintain the crystal structure, while Fe3+ ions enhanced the catalytic activity

Abednatanzi

Abeykoon

Barzetti

Castillo-Blas

Chughtai

Corma

Delolo

Dhakshinamoorthy

Ferey

Furukawa

Férey

Gascon

Giménez-Marqués

Gómez-Paricio

Hong

Horcajada

Jing

Leclerc

Llewellyn

Masoomi

Nouar

Opanasenko

Rallapalli

Rogge

Santiago-Portillo

Serre

Skobelev

Stavitski

Surblé

Tanasaro

Vimont

Volkringer

Wang

Wickenheisser

Yang

Yoon

English

Vallés-García, Cristina

Gkaniatsou, Effrosyni

Santiago-Portillo, Andrea

Giménez Marqués, Mónica

Álvaro, Mercedes

Greneche, Jean-Marc

Steunou, Nathalie

Sicard, Clémence

Navalón, Sergio

Serre, Christian

García, Hermenegildo

Repositori d'Objectes Digitals per a l'Ensenyament la Recerca i la Cultura

Design of stable mixed-metal MIL-101(Cr/Fe) materials with enhanced catalytic activity for the Prins reaction

This work highlights the benefit of designing mixed-metal (Cr/Fe) MOFs for enhanced chemical stability and catalytic activity. A robust and stable mixed-metal MIL-101(Cr/Fe) was prepared through a HF-free direct hydrothermal route with Fe3+ content up to 21 wt%. The incorporation of Fe3+ cations in the crystal structure was confirmed by 57Fe Mössbauer spectrometry. The catalytic performance of the mixed metal MIL-101(Cr/Fe) was evaluated in the Prins reaction. MIL-101(Cr/Fe) exhibited a higher catalytic activity compared to MIL-101(Cr), improved chemical stability compared to MIL-101(Fe) and a higher catalytic activity for bulky substrates compared to MIL-100(Fe). In situ infra-red spectroscopy study suggests that the incorporation of Fe3+ ions in MIL-101 structure leads to an increase in Lewis acid sites. It was thus concluded that the predominant role of Cr3+ ions was to maintain the crystal structure, while Fe3+ ions enhanced the catalytic activity.Financial support by the Spanish Ministry of Economy and Competitiveness (Severo Ochoa, CTQ2018-890237-CO2-R1 and Maria de Maeztu, CEX2019-000919-M), is gratefully acknowledged. Generalidad Valenciana is also thanked for funding (Prometeo 2017/083). S. N. thanks financial support by the Ministerio de Ciencia, Innovación y Universidades (RTI 2018-099482-A-I00 project), Fundación Ramón Areces (XVIII Concurso Nacional para la Adjudicación de Ayudas a la Investigación en Ciencias de la Vida y de la Materia, 2016), and Generalitat Valenciana grupos de investigación consolidables 2019 (ref: AICO/2019/214) project. E. G. thanks the ANR-11-LABEX-0039 (LabEx CHARM3AT) for financial support. M. G.-M thanks support from “la Caixa” Foundation (LCF/BQ/PI19/11690022) and Generalitat Valenciana (SEJI/2020/036)

Vallés, Cristina

Gkaniatsou, E.

Santiago-Portillo, A

Giménez-Marqués, Mónica

Álvaro Rodríguez, Mercedes

Grenèche, Jean Marc

Steunou, N.

Sicard, Clemence

García Gómez, Hermenegildo

Digital.CSIC

           El texto completo de este trabajo no se encuentra disponible por no haber sido facilitado aún por su autor, por restricciones de copyright, o por no existir una versión digital      The full text of this item is not available because it has not been provided by its author yet; because there are copyright restrictions; or because a digital version does not exist  

[EN] This work highlights the benefit of designing mixed-metal (Cr/Fe) MOFs for enhanced chemical stability and catalytic activity. A robust and stable mixed-metal MIL-101(Cr/Fe) was prepared through a HF-free direct hydrothermal route with Fe(3+)content up to 21 wt%. The incorporation of Fe(3+)cations in the crystal structure was confirmed by(57)Fe Mossbauer spectrometry. The catalytic performance of the mixed metal MIL-101(Cr/Fe) was evaluated in the Prins reaction. MIL-101(Cr/Fe) exhibited a higher catalytic activity compared to MIL-101(Cr), improved chemical stability compared to MIL-101(Fe) and a higher catalytic activity for bulky substrates compared to MIL-100(Fe).In situinfra-red spectroscopy study suggests that the incorporation of Fe(3+)ions in MIL-101 structure leads to an increase in Lewis acid sites. It was thus concluded that the predominant role of Cr(3+)ions was to maintain the crystal structure, while Fe(3+)ions enhanced the catalytic activity.Financial support by the Spanish Ministry of Economy and Competitiveness (Severo Ochoa, CTQ2018-890237-CO2-R1 and Maria de Maeztu, CEX2019-000919-M), is gratefully acknowledged. Generalidad Valenciana is also thanked for funding (Prometeo 2017/083). S. N. thanks financial support by the Ministerio de Ciencia, Innovacion y Universidades (RTI 2018-099482-A-I00 project), Fundacion Ramon Areces (XVIII Concurso Nacional para la Adjudicacion de Ayudas a la Investigacion en Ciencias de la Vida y de la Materia, 2016), and Generalitat Valenciana grupos de investigacion consolidables 2019 (ref: AICO/2019/214) project. E. G. thanks the ANR-11-LABEX-0039 (LabEx CHARM3AT) for financial support. M. 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Alvaro Rodríguez, Maria Mercedes

Navalón Oltra, Sergio

RiuNet

International audienceThis work highlights the benefit of designing mixed-metal (Cr/Fe) MOFs for enhanced chemical stability and catalytic activity. A robust and stable mixed-metal MIL-101(Cr/Fe) was prepared through a HF-free direct hydrothermal route with Fe3+ content up to 21 wt%. The incorporation of Fe3+ cations in the crystal structure was confirmed by 57Fe Mössbauer spectrometry. The catalytic performance of the mixed metal MIL-101(Cr/Fe) was evaluated in the Prins reaction. MIL-101(Cr/Fe) exhibited a higher catalytic activity compared to MIL-101(Cr), improved chemical stability compared to MIL-101(Fe) and a higher catalytic activity for bulky substrates compared to MIL-100(Fe). In situ infra-red spectroscopy study suggests that the incorporation of Fe3+ ions in MIL-101 structure leads to an increase in Lewis acid sites. It was thus concluded that the predominant role of Cr3+ ions was to maintain the crystal structure, while Fe3+ ions enhanced the catalytic activity

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Design of stable mixed-metal MIL-101(Cr/Fe) materials with enhanced catalytic activity for the Prins reaction

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Repositori d'Objectes Digitals per a l'Ensenyament la Recerca i la Cultura

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