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Ni-Mg/Al Mixed Oxides Prepared from Layered Double Hydroxides as Catalysts for the Conversion of Furfural to Tetrahydrofurfuryl Alcohol

  • Identification data

    Identifier: imarina:9295172
    Authors:
    Aldureid, AMontané, DLlorca, JMedina, F
    Abstract:
    Ni-Mg/Al mixed oxide catalysts (Ni2Al, Ni2Mg1Al, and Ni1Mg1Al) obtained from layered double hydroxides (LDHs) were tested on the one-pot production of tetrahydrofurfuryl alcohol (TFA) from furfural (FF). Upon calcination at 400 °C and reduction at 500 °C, the LDHs gave catalysts containing small nickel crystallites (<4 nm) dispersed on mixtures of metal oxides and spinel structures. Complete conversion of FF (>99.5%) was achieved on all the catalysts after 4 h at 190 °C and 5.0 MPa of H2 using 5 wt.% FF in ethanol and a furfural-to-catalyst mass ratio of 7.44 g/g. TFA evolved from the sequential hydrogenation of FF to furfuryl alcohol (FA) to TFA. Competing reaction routes involved decarbonylation of FF to furan (FUR) followed by hydrogenation to tetrahydrofuran (THF) or hydrogenolysis to n-butane (BU) and the hydrogenation of the carbonyl group in FF to form 2-methyl furan (mFUR) and its hydrogenation to 2-methyltetrahydrofuran (mTHF). A third competing route consisted of the nucleophilic addition of FF with ethanol and with FA to form acetals (such as 2-(diethoxymethyl)furan, FDA), which were later converted to difurfuryl ether (DFE) and tetrahydrofurfuryl ethyl ether (TFEE) as final products. Hydrogen pressure favored the production of TFA and diminished the formation of acetals, while temperature reduced the capacity of the catalyst to hydrogenate the furan ring, thus reducing TFA and increasing FA and FUR. An 80% yield to TFA was achieved with the Ni2Mg1Al catalysts after 6 h at 190 °C and 50 bar H2, but a variety of coproducts were present at low concentration. Testing of the catalysts in gas-phase hydrogenation conditions at atmospheric pressure revealed a poorer performance, with FA as the main product.
  • Others:

    Author, as appears in the article.: Aldureid, A; Montané, D; Llorca, J; Medina, F
    Department: Enginyeria Química
    URV's Author/s: Aldureid Kadi Amin, Abdulaziz / Medina Cabello, Francisco / Montané Calaf, Daniel
    Keywords: Selective hydrogenation Mesoporous materials as solid catalysts Layered double hydroxide Hydrogenation Heterogeneous catalysis Biomass valorization response factors prediction platform performance mesoporous materials as solid catalysts layered double hydroxide hydrotalcite hydrogenation heterogeneous catalysts gas-chromatography design biomass valorization anionic clays
    Abstract: Ni-Mg/Al mixed oxide catalysts (Ni2Al, Ni2Mg1Al, and Ni1Mg1Al) obtained from layered double hydroxides (LDHs) were tested on the one-pot production of tetrahydrofurfuryl alcohol (TFA) from furfural (FF). Upon calcination at 400 °C and reduction at 500 °C, the LDHs gave catalysts containing small nickel crystallites (<4 nm) dispersed on mixtures of metal oxides and spinel structures. Complete conversion of FF (>99.5%) was achieved on all the catalysts after 4 h at 190 °C and 5.0 MPa of H2 using 5 wt.% FF in ethanol and a furfural-to-catalyst mass ratio of 7.44 g/g. TFA evolved from the sequential hydrogenation of FF to furfuryl alcohol (FA) to TFA. Competing reaction routes involved decarbonylation of FF to furan (FUR) followed by hydrogenation to tetrahydrofuran (THF) or hydrogenolysis to n-butane (BU) and the hydrogenation of the carbonyl group in FF to form 2-methyl furan (mFUR) and its hydrogenation to 2-methyltetrahydrofuran (mTHF). A third competing route consisted of the nucleophilic addition of FF with ethanol and with FA to form acetals (such as 2-(diethoxymethyl)furan, FDA), which were later converted to difurfuryl ether (DFE) and tetrahydrofurfuryl ethyl ether (TFEE) as final products. Hydrogen pressure favored the production of TFA and diminished the formation of acetals, while temperature reduced the capacity of the catalyst to hydrogenate the furan ring, thus reducing TFA and increasing FA and FUR. An 80% yield to TFA was achieved with the Ni2Mg1Al catalysts after 6 h at 190 °C and 50 bar H2, but a variety of coproducts were present at low concentration. Testing of the catalysts in gas-phase hydrogenation conditions at atmospheric pressure revealed a poorer performance, with FA as the main product.
    Thematic Areas: Organic chemistry Inorganic chemistry Electrochemistry Chemistry, multidisciplinary Chemistry (miscellaneous)
    licence for use: https://creativecommons.org/licenses/by/3.0/es/
    Author's mail: abdulaziz.aldureid@estudiants.urv.cat abdulaziz.aldureid@estudiants.urv.cat daniel.montane@urv.cat francesc.medina@urv.cat
    Author identifier: 0000-0002-5273-8870 0000-0002-3111-1542
    Record's date: 2024-08-03
    Papper version: info:eu-repo/semantics/publishedVersion
    Link to the original source: https://www.mdpi.com/2624-8549/5/1/41
    Licence document URL: https://repositori.urv.cat/ca/proteccio-de-dades/
    Papper original source: Chemistry-Switzerland. 5 (1): 571-588
    APA: Aldureid, A; Montané, D; Llorca, J; Medina, F (2023). Ni-Mg/Al Mixed Oxides Prepared from Layered Double Hydroxides as Catalysts for the Conversion of Furfural to Tetrahydrofurfuryl Alcohol. Chemistry-Switzerland, 5(1), 571-588. DOI: 10.3390/chemistry5010041
    Article's DOI: 10.3390/chemistry5010041
    Entity: Universitat Rovira i Virgili
    Journal publication year: 2023
    Publication Type: Journal Publications
  • Keywords:

    Chemistry (Miscellaneous),Chemistry, Multidisciplinary,Electrochemistry,Inorganic Chemistry,Organic Chemistry
    Selective hydrogenation
    Mesoporous materials as solid catalysts
    Layered double hydroxide
    Hydrogenation
    Heterogeneous catalysis
    Biomass valorization
    response factors
    prediction
    platform
    performance
    mesoporous materials as solid catalysts
    layered double hydroxide
    hydrotalcite
    hydrogenation
    heterogeneous catalysts
    gas-chromatography
    design
    biomass valorization
    anionic clays
    Organic chemistry
    Inorganic chemistry
    Electrochemistry
    Chemistry, multidisciplinary
    Chemistry (miscellaneous)
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