Palladium Supported on Porous Chitosan-Graphene Oxide Aerogels as Highly Efficient Catalysts for Hydrogen Generation from Formate

[EN] Adsorption of Pd(NH3)(4)(2+) in preformed chitosan-graphene oxide (CS-GO) beads and their subsequent reduction with NaBH4 afford well-dispersed, high dispersion (similar to 21%) of uniformly sized Pd nanoparticles (similar to 1.7 nm). The resulting Pd/CS-GO exhibits interesting catalytic activity for hydrogen generation by ammonium formate decomposition. The optimal GO proportion of 7 wt% allows reaching, at 60 degrees C, a turnover frequency above 2200 h(-1)-being outstanding among the highest values reported for this process to date. Interestingly, no formation of CO or CH4 was detected. The catalyst did not leach, although it underwent gradual deactivation, probably caused by the increase in the Pd average size that became over 3 nm after three uses. Our results are relevant in the context of efficient on-board hydrogen generation from liquid organic hydrogen carriers in transportation.This research was funded by the Spanish Ministry of Science, Innovation and Universities (Grant RTI2018-098237-B-C21 and Severo Ochoa). A.P. also thanks the Spanish Ministry of Science and Education a research associate Ramon y Cajal contract. A.A. thanks UEMF for scholarship.Anouar, A.; Katir, N.; El Kadib, A.; Primo Arnau, AM.; García Gómez, H. (2019). Palladium Supported on Porous Chitosan-Graphene Oxide Aerogels as Highly Efficient Catalysts for Hydrogen Generation from Formate. Molecules. 24(18):1-13. https://doi.org/10.3390/molecules24183290S113241

Pd embedded in chitosan microspheres as tunable soft-materials for Sonogashira cross-coupling in water-ethanol mixture

Easy shaping of chitosan (CS) as porous self-standing nanofibrillar microspheres allows their use as a palladium carrier. Amino-groups on CS enable the modulation of Pd coordination, giving rise to three different support-catalyst interactions: weakly-coordinated Pd-CS in native CS, incarcerated Pd-CS-Glu in cross-linked CS and strongly-ligated Pd-CS-SH, obtained by the introduction of thiol arms in CS. These catalysts efficiently promote Sonogashira cross-coupling of a large library of functional substrates under mild and sustainable conditions (water-ethanol as solvent at 65 degrees C) and stand as recyclable, metal-scavenging catalytic systems.Frindy, S.; Primo Arnau, AM.; Lahcini, M.; Bousmina, M.; García Gómez, H.; El Kadib, A. (2015). Pd embedded in chitosan microspheres as tunable soft-materials for Sonogashira cross-coupling in water-ethanol mixture. Green Chemistry. 17(3):1893-1898. doi:10.1039/c4gc02175dS18931898173Johansson Seechurn, C. C. C., Kitching, M. O., Colacot, T. J., & Snieckus, V. (2012). Palladium-Catalyzed Cross-Coupling: A Historical Contextual Perspective to the 2010 Nobel Prize. Angewandte Chemie International Edition, 51(21), 5062-5085. doi:10.1002/anie.201107017Sehnal, P., Taylor, R. J. K., & Fairlamb, I. J. S. (2010). Emergence of Palladium(IV) Chemistry in Synthesis and Catalysis. Chemical Reviews, 110(2), 824-889. doi:10.1021/cr9003242Torborg, C., & Beller, M. (2009). Recent Applications of Palladium-Catalyzed Coupling Reactions in the Pharmaceutical, Agrochemical, and Fine Chemical Industries. Advanced Synthesis & Catalysis, 351(18), 3027-3043. doi:10.1002/adsc.200900587Hartwig, J. F. (2008). Carbon–heteroatom bond formation catalysed by organometallic complexes. Nature, 455(7211), 314-322. doi:10.1038/nature07369Loska, R., Volla, C. M. R., & Vogel, P. (2008). Iron-Catalyzed Mizoroki-Heck Cross-Coupling Reaction with Styrenes. Advanced Synthesis & Catalysis, 350(18), 2859-2864. doi:10.1002/adsc.200800662Sun, C.-L., Li, B.-J., & Shi, Z.-J. (2011). Direct C−H Transformation via Iron Catalysis. Chemical Reviews, 111(3), 1293-1314. doi:10.1021/cr100198wCzaplik, W. M., Mayer, M., Cvengroš, J., & von Wangelin, A. J. (2009). Coming of Age: Sustainable Iron-Catalyzed Cross-Coupling Reactions. ChemSusChem, 2(5), 396-417. doi:10.1002/cssc.200900055Fürstner, A., Leitner, A., Méndez, M., & Krause, H. (2002). Iron-Catalyzed Cross-Coupling Reactions. Journal of the American Chemical Society, 124(46), 13856-13863. doi:10.1021/ja027190tBarluenga, J., & Valdés, C. (2011). Tosylhydrazones: New Uses for Classic Reagents in Palladium-Catalyzed Cross-Coupling and Metal-Free Reactions. Angewandte Chemie International Edition, 50(33), 7486-7500. doi:10.1002/anie.201007961Yin, & Liebscher, J. (2007). Carbon−Carbon Coupling Reactions Catalyzed by Heterogeneous Palladium Catalysts. Chemical Reviews, 107(1), 133-173. doi:10.1021/cr0505674Phan, N. T. S., Van Der Sluys, M., & Jones, C. W. (2006). On the Nature of the Active Species in Palladium Catalyzed Mizoroki–Heck and Suzuki–Miyaura Couplings – Homogeneous or Heterogeneous Catalysis, A Critical Review. Advanced Synthesis & Catalysis, 348(6), 609-679. doi:10.1002/adsc.200505473Weck, M., & Jones, C. W. (2007). Mizoroki−Heck Coupling Using Immobilized Molecular Precatalysts:  Leaching Active Species from Pd Pincers, Entrapped Pd Salts, and Pd NHC Complexes. Inorganic Chemistry, 46(6), 1865-1875. doi:10.1021/ic061898hWEBB, J., MACQUARRIE, S., MCELENEY, K., & CRUDDEN, C. (2007). Mesoporous silica-supported Pd catalysts: An investigation into structure, activity, leaching and heterogeneity. Journal of Catalysis, 252(1), 97-109. doi:10.1016/j.jcat.2007.09.007Garrett, C. E., & Prasad, K. (2004). The Art of Meeting Palladium Specifications in Active Pharmaceutical Ingredients Produced by Pd-Catalyzed Reactions. Advanced Synthesis & Catalysis, 346(8), 889-900. doi:10.1002/adsc.200404071Glasspoole, B. W., Webb, J. D., & Crudden, C. M. (2009). Catalysis with chemically modified mesoporous silicas: Stability of the mesostructure under Suzuki–Miyaura reaction conditions. Journal of Catalysis, 265(2), 148-154. doi:10.1016/j.jcat.2009.04.020Modak, A., Mondal, J., & Bhaumik, A. (2012). Pd-grafted periodic mesoporous organosilica: an efficient heterogeneous catalyst for Hiyama and Sonogashira couplings, and cyanation reactions. Green Chemistry, 14(10), 2840. doi:10.1039/c2gc35820dMacquarrie, D. J., & Hardy, J. J. E. (2005). Applications of Functionalized Chitosan in Catalysis†. Industrial & Engineering Chemistry Research, 44(23), 8499-8520. doi:10.1021/ie050007vA. El Kadib , ChemSusChem20158217244El Kadib, A., Primo, A., Molvinger, K., Bousmina, M., & Brunel, D. (2011). Nanosized Vanadium, Tungsten and Molybdenum Oxide Clusters Grown in Porous Chitosan Microspheres as Promising Hybrid Materials for Selective Alcohol Oxidation. Chemistry – A European Journal, 17(28), 7940-7946. doi:10.1002/chem.201003740El Kadib, A., & Bousmina, M. (2012). Chitosan Bio-Based Organic-Inorganic Hybrid Aerogel Microspheres. Chemistry - A European Journal, 18(27), 8264-8277. doi:10.1002/chem.201104006Kadib, A. E., Bousmina, M., & Brunel, D. (2014). Recent Progress in Chitosan Bio-Based Soft Nanomaterials. Journal of Nanoscience and Nanotechnology, 14(1), 308-331. doi:10.1166/jnn.2014.9012Primo, A., & Quignard, F. (2010). Chitosan as efficient porous support for dispersion of highly active gold nanoparticles: design of hybrid catalyst for carbon–carbon bond formation. Chemical Communications, 46(30), 5593. doi:10.1039/c0cc01137aValentin, R., Molvinger, K., Quignard, F., & Brunel, D. (2003). Supercritical CO2 dried chitosan: an efficient intrinsic heterogeneous catalyst in fine chemistry. New Journal of Chemistry, 27(12), 1690. doi:10.1039/b310109fPrimo, A., Atienzar, P., Sanchez, E., Delgado, J. M., & García, H. (2012). From biomass wastes to large-area, high-quality, N-doped graphene: catalyst-free carbonization of chitosan coatings on arbitrary substrates. Chemical Communications, 48(74), 9254. doi:10.1039/c2cc34978gNgah, W. S. W., Ab Ghani, S., & Kamari, A. (2005). Adsorption behaviour of Fe(II) and Fe(III) ions in aqueous solution on chitosan and cross-linked chitosan beads. Bioresource Technology, 96(4), 443-450. doi:10.1016/j.biortech.2004.05.022El Hankari, S., El Kadib, A., Finiels, A., Bouhaouss, A., Moreau, J. J. E., Crudden, C. M., … Hesemann, P. (2011). SBA-15-Type Organosilica with 4-Mercapto-N,N-bis-(3-Si-propyl)butanamide for Palladium Scavenging and Cross-Coupling Catalysis. Chemistry - A European Journal, 17(32), 8984-8994. doi:10.1002/chem.201002190Crudden, C. M., Sateesh, M., & Lewis, R. (2005). Mercaptopropyl-Modified Mesoporous Silica:  A Remarkable Support for the Preparation of a Reusable, Heterogeneous Palladium Catalyst for Coupling Reactions. Journal of the American Chemical Society, 127(28), 10045-10050. doi:10.1021/ja0430954McEleney, K., Crudden, C. M., & Horton, J. H. (2009). X-ray Photoelectron Spectroscopy and the Auger Parameter As Tools for Characterization of Silica-Supported Pd Catalysts for the Suzuki−Miyaura Reaction. The Journal of Physical Chemistry C, 113(5), 1901-1907. doi:10.1021/jp808837kRoy, A. S., Mondal, J., Banerjee, B., Mondal, P., Bhaumik, A., & Islam, S. M. (2014). Pd-grafted porous metal–organic framework material as an efficient and reusable heterogeneous catalyst for C–C coupling reactions in water. Applied Catalysis A: General, 469, 320-327. doi:10.1016/j.apcata.2013.10.017Kadib, A. E., Molvinger, K., Cacciaguerra, T., Bousmina, M., & Brunel, D. (2011). Chitosan templated synthesis of porous metal oxide microspheres with filamentary nanostructures. Microporous and Mesoporous Materials, 142(1), 301-307. doi:10.1016/j.micromeso.2010.12.012Kühbeck, D., Saidulu, G., Reddy, K. R., & Díaz, D. D. (2012). Critical assessment of the efficiency of chitosan biohydrogel beads as recyclable and heterogeneous organocatalyst for C–C bond formation. Green Chem., 14(2), 378-392. doi:10.1039/c1gc15925aKhalafi-Nezhad, A., & Mohammadi, S. (2014). Chitosan supported ionic liquid: a recyclable wet and dry catalyst for the direct conversion of aldehydes into nitriles and amides under mild conditions. RSC Advances, 4(27), 13782. doi:10.1039/c3ra43440kEl Kadib, A., McEleney, K., Seki, T., Wood, T. K., & Crudden, C. M. (2011). Cross-Coupling in the Preparation of Pharmaceutically Relevant Substrates using Palladium Supported on Functionalized Mesoporous Silicas. ChemCatChem, 3(8), 1281-1285. doi:10.1002/cctc.20110002

Insightful understanding of the role of clay topology on the stability of biomimetic hybrid chitosan-clay thin films and CO2-dried porous aerogel microspheres

[EN] Three natural clay-based microstructures, namely layered montmorillonite (MMT), nanotubular halloysite (HNT) and micro-fibrillar sepiolite (SP) were used for the synthesis of hybrid chitosan-clay thin films and porous aerogel microspheres. At a first glance, a decrease in the viscosity of the three gel forming solutions was noticed as a result of breaking the mutual polymeric chains interaction by the clay microstructure. Upon casting, chitosan-clay films displayed enhanced hydrophilicity in the order CS < CS-MMT < CS-HNT < CS-SP. Irrespective to the clay microstructure, an improvement in the mechanical properties of the chitosan-clay films has been substantiated with CS-SP reaching the highest value at 5% clay loading. While clay addition provides a way to resist the shrinkage occurring for native chitosan, the enhanced hydrophilicity associated to the water content affects the efficacy of the CO2 super-critical drying as the most hydrophilic CS-SP microspheres face the highest shrinkage, resulting in a lowest specific surface area compared to CS-HNT and CS-MMT. Chitosan-clay exhibits enhanced thermal properties with the degradation delayed in the order CS < CS-MMT < CS-HNT < CS-SP. Under acidic environment, a longevity has been substantiated for chitosan-clay compared to native chitosan, evidencing the beneficial protective effect of the clay particulates for the biopolymer. However, under hydrothermal treatment, the presence of clay was found to be detrimental to the material stability as a significant shrinkage occurs in hybrid CS-clay microspheres, which is attributed again to their increased hydrophilicity compared to the native polymeric microspheres. In this framework, a peculiar behavior was observed for CS-MMT, with the microspheres standing both against contraction during CO2 gel drying and under hydrothermal conditions. The knowledge gained from this rational design will constitute a guideline toward the preparation of ultra-stable, practically-optimized food-packaging films and commercially scalable porous bio-based adsorbents.S. F thanks MAScIR foundation, CNRST and Erasmus Mundus-Maghreb & Egypt- EMMAG.Frindy, S.; Primo Arnau, AM.; Qaiss, AEK.; Bouhfid, R.; Lahcini, M.; García Gómez, H.; Bousmina, M.... (2016). Insightful understanding of the role of clay topology on the stability of biomimetic hybrid chitosan-clay thin films and CO2-dried porous aerogel microspheres. Carbohydrate Polymers. 146:353-361. doi:10.1016/j.cabpel.2016.03.022S35336114

Remarkable Activity of 002 Facet of Ruthenium Nanoparticles Grown on Graphene Films on the Photocatalytic CO2 Methanation

[EN] In the context of diminishing atmospheric CO2 emissions, there is an urgent need to develop processes that can be carried out at a scale commensurate with appropriate CO2 volumes. One possible reaction is the transformation of CO2 to methane (Sabatier reaction). Due to its chemical stability, catalytic CO2 hydrogenation to methane is carried out at temperatures of 450 degrees C or higher and pressures above 5 bars, thus, requiring a significant energy input. One alternative possibility to conventional thermal catalysis is the use of solar light as the primary energy, performing the photocatalytic CO2 hydrogenation. In this broad context, the present study shows the photocatalytic activity of nanometric films of oriented Ru nanoparticles (NPs) strongly grafted on defective graphene. These graphene films (thinner than 20 nm) containing Ru NPs nanoplatelets (less than 2 nanomol(Ru)/cm(2)) are among the most active photocatalysts ever prepared for CO2 hydrogenation and operate through photoinduced charge separationSupport by the Ministerio de Ciencia e Innovacion (Severo Ochoa and RTI2018-098237-B-C21) and Generalitat Valenciana (Prometeo 2017/083) was acknowledged. Thanks are due to Galicia Supercomputing Center. A.A. thanks UEMF (Euromed Unniversity Fes) and UPV for an Erasmus+ 2019-1-ES01-KA107-062073 Scholarship. A.P. thanks the Spanish Ministry for a Ramon y Cajal research associate contract.Anouar, A.; García-Aboal, R.; Atienzar Corvillo, PE.; Franconetti, A.; Katir, N.; El Kadib, A.; Primo Arnau, AM.... (2022). Remarkable Activity of 002 Facet of Ruthenium Nanoparticles Grown on Graphene Films on the Photocatalytic CO2 Methanation. Advanced Sustainable Systems. 6(5):1-10. https://doi.org/10.1002/adsu.2021004871106

Organophosphonate bridged anatase mesocrystals: low temperature crystallization, thermal growth and hydrogen photo-evolution

The sol-gel co-condensation of organo-phosphonates to titanium alkoxides enables access to novel organic-inorganic hybrids based on phosphonate-bridged titanium dioxide. In this contribution, we bring new perspectives to the long established sol-gel mineralization of titanium alkoxide species, by harnessing the virtues of the well-designed phosphonate-terminated phosphorus dendrimers as reactive amphiphilic nanoreactor, confined medium and cross-linked template to generate discrete crystalline anatase nanoparticles at low temperature (T = 60 degrees C). An accurate investigation on several parameters (dendrimer generation, dendrimer-to-titanium alkoxide ratio, precursor reactivity, temperature, solvent nature, salt effect) allows a correlation between the network condensation, the opening porous framework and the crystalline phase formation. The evolution of the dendrimer skeleton upon heat treatment has been deeply monitored by means of P-31 NMR, XPS and Raman spectroscopy. Increasing the heteroatom content within a titania network provides the driving force for enhancing their photocatalytic water splitting ability for hydrogen production.Brahmi, Y.; Katir, N.; Macia Agullo, JA.; Primo Arnau, AM.; Bousmina, M.; Majoral, J.; García Gómez, H.... (2015). Organophosphonate bridged anatase mesocrystals: low temperature crystallization, thermal growth and hydrogen photo-evolution. Dalton Transactions. 44(35):15544-15556. doi:10.1039/c5dt02367jS1554415556443

Métallation (Si, Ge) des esters méthyliques d'acides gras

Ce travail décrit la métallation (Si, Ge) des esters méthyliques d'acides gras (EMAG) et de l'huile brute. Dans un premier temps, l'hydrométallation des EMAG a été développée. La séquence d'initiation radicalaire conduit à des produits métallés avec une meilleure sélectivité. La silylation des EMAG en a de la fonction ester a été réalisée par des silyltriflates ou à partir d'énolates d'EMAG. L'optimisation des conditions opératoires a conduit à l'obtention exclusive des produits C-silylés. Le quatrième chapitre a porté sur l'obtention de biosilicones par polycondensation des silylEMAG. La modélisation moléculaire a révélé "le masquage" parfait des siloxanes par des EMAG montrant l'intérêt que peuvent présenter de tels polymères en particulier concernant l'accroissement de leur biocompatibilité. Dans le dernier chapitre a été développé une application intéressante des précurseurs silylés : le pouvoir d'auto-organisation de ces unités moléculaires a permis d'accéder à des nanomatériaux de silice.TOULOUSE3-BU Sciences (315552104) / SudocSudocFranceF

Recent Progress in Chitosan Bio-Based Soft Nanomaterials

International audienc

Self-templating amphiphilic polysiloxanes to design nanostructured silica-based architectures

International audienc

Improving Catalytic Activity by Synergic Effect between Base and Acid pairs in Hierarchically Porous Chitosan@Titania Nanoreactors

International audienc

Decoration of Chitosan Microspheres with Inorganic Oxide Clusters : Rational Design of Hierarchically Porous, Stable and Cooperative Acid-Base Nanoreactors

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