Sol-gel entrapped Au0- and Ag0-nanoparticles catalyze reductive de-halogenation of halo-organic compounds by BH4−

Jaydeep Adhikary; Dan Meyerstein; Vered Marks; Michael Meistelman; Gregory Gershinsky; Ariela Burg; Dror Shamir; Haya Kornweitz; Yael Albo

doi:10.1016/j.apcatb.2018.08.040

Sol-gel entrapped Au⁰- and Ag⁰-nanoparticles catalyze reductive de-halogenation of halo-organic compounds by BH₄⁻

Jaydeep Adhikary, Dan Meyerstein, Vered Marks, Michael Meistelman, Gregory Gershinsky, Ariela Burg, Dror Shamir, Haya Kornweitz, Yael Albo

Department of Chemistry

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

This study investigated the reductive de-halogenations of toxic Br₃CCO₂⁻, Br₂CHCO₂⁻, BrCH₂CO₂⁻, CH₃CHBrCO₂⁻, CH₂BrCH₂CO₂⁻, CH₂BrCHBrCO₂⁻, Cl₃CCO₂⁻, Cl₂CHCO₂- and ClCH₂CO₂⁻ by sodium borohydride catalyzed by sol-gel silica entrapped Au⁰ and Ag⁰ nanoparticles. The results indicate that the mechanism of reduction of Br₃CCO₂⁻ differs from that of Cl₃CCO₂⁻. Calculated by DFT, the source of this difference lies in the larger bond strength of C–Cl compared to that of C–Br and the weaker M⁰–C bond strength in Au⁰-CBr₂CO₂⁻ compared to those of Au⁰-CCl₂CO₂⁻ and Au⁰-CH₂CO₂⁻. Furthermore, the de-halogenation mechanisms catalyzed by Ag⁰-NPs differ from those catalyzed by Au⁰-NPs. The latter observation is attributed to the different Ag–C and Au–C bond strengths and to the different over-potentials for H₂ release of these M⁰-NPs. In addition, product composition depends on the rate of BH₄⁻ addition. Proton labeling experiments prove that nearly all the hydrogen atoms in the products originated from the water solvent and not from the BH₄⁻. The detailed mechanistic conclusions that can be drawn from these results differ considerably from those commonly accepted for de-halogenation processes.

Original language	English
Pages (from-to)	450-462
Number of pages	13
Journal	Applied Catalysis B: Environmental
Volume	239
DOIs	https://doi.org/10.1016/j.apcatb.2018.08.040
State	Published - 30 Dec 2018

Keywords

Dehalogenation
Gold and silver nanoparticles
Mechanistic study
Silica matrix
Sol-gel

ASJC Scopus subject areas

Catalysis
Environmental Science (all)
Process Chemistry and Technology

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10.1016/j.apcatb.2018.08.040

Cite this

@article{88a5223ac9cd42eaa91ffc36125e9252,

title = "Sol-gel entrapped Au0- and Ag0-nanoparticles catalyze reductive de-halogenation of halo-organic compounds by BH4−",

abstract = "This study investigated the reductive de-halogenations of toxic Br3CCO2−, Br2CHCO2−, BrCH2CO2−, CH3CHBrCO2−, CH2BrCH2CO2−, CH2BrCHBrCO2−, Cl3CCO2−, Cl2CHCO2- and ClCH2CO2− by sodium borohydride catalyzed by sol-gel silica entrapped Au0 and Ag0 nanoparticles. The results indicate that the mechanism of reduction of Br3CCO2− differs from that of Cl3CCO2−. Calculated by DFT, the source of this difference lies in the larger bond strength of C–Cl compared to that of C–Br and the weaker M0–C bond strength in Au0-CBr2CO2− compared to those of Au0-CCl2CO2− and Au0-CH2CO2−. Furthermore, the de-halogenation mechanisms catalyzed by Ag0-NPs differ from those catalyzed by Au0-NPs. The latter observation is attributed to the different Ag–C and Au–C bond strengths and to the different over-potentials for H2 release of these M0-NPs. In addition, product composition depends on the rate of BH4− addition. Proton labeling experiments prove that nearly all the hydrogen atoms in the products originated from the water solvent and not from the BH4−. The detailed mechanistic conclusions that can be drawn from these results differ considerably from those commonly accepted for de-halogenation processes.",

keywords = "Dehalogenation, Gold and silver nanoparticles, Mechanistic study, Silica matrix, Sol-gel",

author = "Jaydeep Adhikary and Dan Meyerstein and Vered Marks and Michael Meistelman and Gregory Gershinsky and Ariela Burg and Dror Shamir and Haya Kornweitz and Yael Albo",

note = "Funding Information: We are indebted to the PAZY Foundation for the grant that enabled this study. V. M. would like to offer her special thanks to the Ministry of Aliyah and Integration for its generous sponsorship. Publisher Copyright: {\textcopyright} 2018",

year = "2018",

month = dec,

day = "30",

doi = "10.1016/j.apcatb.2018.08.040",

language = "English",

volume = "239",

pages = "450--462",

journal = "Applied Catalysis B: Environmental",

issn = "0926-3373",

publisher = "Elsevier",

}

TY - JOUR

T1 - Sol-gel entrapped Au0- and Ag0-nanoparticles catalyze reductive de-halogenation of halo-organic compounds by BH4−

AU - Adhikary, Jaydeep

AU - Meyerstein, Dan

AU - Marks, Vered

AU - Meistelman, Michael

AU - Gershinsky, Gregory

AU - Burg, Ariela

AU - Shamir, Dror

AU - Kornweitz, Haya

AU - Albo, Yael

N1 - Funding Information: We are indebted to the PAZY Foundation for the grant that enabled this study. V. M. would like to offer her special thanks to the Ministry of Aliyah and Integration for its generous sponsorship. Publisher Copyright: © 2018

PY - 2018/12/30

Y1 - 2018/12/30

N2 - This study investigated the reductive de-halogenations of toxic Br3CCO2−, Br2CHCO2−, BrCH2CO2−, CH3CHBrCO2−, CH2BrCH2CO2−, CH2BrCHBrCO2−, Cl3CCO2−, Cl2CHCO2- and ClCH2CO2− by sodium borohydride catalyzed by sol-gel silica entrapped Au0 and Ag0 nanoparticles. The results indicate that the mechanism of reduction of Br3CCO2− differs from that of Cl3CCO2−. Calculated by DFT, the source of this difference lies in the larger bond strength of C–Cl compared to that of C–Br and the weaker M0–C bond strength in Au0-CBr2CO2− compared to those of Au0-CCl2CO2− and Au0-CH2CO2−. Furthermore, the de-halogenation mechanisms catalyzed by Ag0-NPs differ from those catalyzed by Au0-NPs. The latter observation is attributed to the different Ag–C and Au–C bond strengths and to the different over-potentials for H2 release of these M0-NPs. In addition, product composition depends on the rate of BH4− addition. Proton labeling experiments prove that nearly all the hydrogen atoms in the products originated from the water solvent and not from the BH4−. The detailed mechanistic conclusions that can be drawn from these results differ considerably from those commonly accepted for de-halogenation processes.

AB - This study investigated the reductive de-halogenations of toxic Br3CCO2−, Br2CHCO2−, BrCH2CO2−, CH3CHBrCO2−, CH2BrCH2CO2−, CH2BrCHBrCO2−, Cl3CCO2−, Cl2CHCO2- and ClCH2CO2− by sodium borohydride catalyzed by sol-gel silica entrapped Au0 and Ag0 nanoparticles. The results indicate that the mechanism of reduction of Br3CCO2− differs from that of Cl3CCO2−. Calculated by DFT, the source of this difference lies in the larger bond strength of C–Cl compared to that of C–Br and the weaker M0–C bond strength in Au0-CBr2CO2− compared to those of Au0-CCl2CO2− and Au0-CH2CO2−. Furthermore, the de-halogenation mechanisms catalyzed by Ag0-NPs differ from those catalyzed by Au0-NPs. The latter observation is attributed to the different Ag–C and Au–C bond strengths and to the different over-potentials for H2 release of these M0-NPs. In addition, product composition depends on the rate of BH4− addition. Proton labeling experiments prove that nearly all the hydrogen atoms in the products originated from the water solvent and not from the BH4−. The detailed mechanistic conclusions that can be drawn from these results differ considerably from those commonly accepted for de-halogenation processes.

KW - Dehalogenation

KW - Gold and silver nanoparticles

KW - Mechanistic study

KW - Silica matrix

KW - Sol-gel

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U2 - 10.1016/j.apcatb.2018.08.040

DO - 10.1016/j.apcatb.2018.08.040

M3 - Article

AN - SCOPUS:85051968936

SN - 0926-3373

VL - 239

SP - 450

EP - 462

JO - Applied Catalysis B: Environmental

JF - Applied Catalysis B: Environmental

ER -