107,948 research outputs found
Francesco Piccolo e il mito di Atteone
The paper examines, through the available classic sources, the use of Actaeon's Greek myth made by Francesco Piccolo in his novel Il desiderio di essere come tutti (Einaudi 2013, Premio Strega 2014). The peculiar aspects of this myth have been adapted to adhere to the narrator' s autobiography in its various moments and experiences
La Famiglia Meneghina e la nascita del Piccolo Teatro di Milano
L'attività della Famiglia Meneghina al Piccolo Teatro di Milano.The activity of the Meneghina Family at the Piccolo Teatro in Milan
Environment and dynamical effects in nanocatalysis
SSCI-VIDE+ECI2D+LPIInternational audienceRecent progress in nanomaterials preparation, characterization and theoretical modeling opens the way to tailoring catalysts and understanding their operating mode at the atomic level. Many strategies are possible for improving the performances of metal-based catalysts, e.g., as done in our laboratory, through the use of alloy phases (noble metal nanoalloys[1] and non-noble intermetallics[2]) and/or reducible oxide supports (e.g. TiO2[3] and CeO2[4]). It will be shown that the targeted catalytic processes (selective hydrogenations and preferential CO oxidation) all benefit from metal-metal and/or metal-oxide synergies.However, as these reactions involve hydrogen-rich environments, hydrogen absorption in the metal lattice can have a drastic influence on the catalytic properties.[5–7] Moreover, advanced microscopy and spectroscopy techniques reveal additional major effects of the gaseous atmosphere and the support on the catalyst phase, such as changes in nanoparticle morphology, chemical arrangement and oxidation state.[8–10] Finally, as will be shown from operando techniques in the prototypical case of CO oxidation over Pt/-Al2O3, the influence of the thermochemical environment is even more dramatic for the stability of recently emerging “singe-atom catalysts”. Confronting experimental observations with computer simulations enables us to identify the key structural drivers and elucidate the reaction mechanisms.References1- L. Piccolo, in Nanoalloys: Synthesis, Structure and Properties, edited by D. Alloyeau, C. Mottet, and C. Ricolleau (Springer London, 2012), pp. 369–404.2- L. Piccolo and L. Kibis, J. Catal. 332, 112 (2015).3- T.-S. Nguyen, D. Laurenti, P. Afanasiev, Z. Konuspayeva, and L. Piccolo, J. Catal. 344, 136 (2016).4- F. Morfin, T.-S. Nguyen, J.-L. Rousset, and L. Piccolo, Appl. Catal. B 197, 2 (2016).5- C. Zlotea, F. Morfin, T.-S. Nguyen, N.-T. Nguyen, J. Nelayah, C. Ricolleau, M. Latroche, and L. Piccolo, Nanoscale 6, 9955 (2014).6- C. Goyhenex and L. Piccolo, Phys. Chem. Chem. Phys. 19, 32451 (2017).7- C. Zlotea, Y. Oumellal, K. Provost, F. Morfin, and L. Piccolo, Appl. Catal. B 237, 1059 (2018).8- A. Kaftan, F. Kollhoff, T.-S. Nguyen, L. Piccolo, M. Laurin, and J. Libuda, Catal. Sci. Technol. 6, 818 (2016).9- L. Piccolo, Z. Y. Li, I. Demiroglu, F. Moyon, Z. Konuspayeva, G. Berhault, P. Afanasiev, W. Lefebvre, J. Yuan, and R. L. Johnston, Sci. Rep. 6, 35226 (2016).10- I. Demiroglu, T. Fan, Z. Li, J. Yuan, T. Liu, L. Piccolo, and R. L. Johnston, Faraday Discuss. 208, 53 (2018)
On the interplay between structure, reaction medium and performance in heterogeneous catalysis
SSCI-VIDE+ECI2D+LPIInternational audienceRecent progress in nanomaterials preparation, characterization and theoretical modeling opens the way to tailoring catalysts and understanding their operating mode at the atomic level. Many strategies are possible for improving the performances of metal-based catalysts, e.g., as done in our laboratory, through the use of alloy phases (noble metal nanoalloys [1] and non-noble intermetallics [2]) and/or reducible oxide supports (e.g. TiO2 [3] and CeO2 [4]). It will be shown that the targeted catalytic processes (selective hydrogenations and preferential CO oxidation) all benefit from metal-metal and/or metal-oxide synergies. However, as these reactions involve hydrogen-rich environments, hydrogen absorption in the metal lattice can have a drastic influence on the catalytic properties [5–7]. Moreover, advanced microscopy and spectroscopy techniques reveal additional major effects of the gaseous atmosphere and the support on the catalyst phase, such as changes in nanoparticle morphology, chemical arrangement and oxidation state (Fig. 1) [8–10]. Finally, as will be shown from operando techniques in the prototypical case of CO oxidation over Pt/-Al2O3, the influence of the thermochemical environment is even more dramatic for the stability of recently emerging “singe-atom catalysts”. Confronting experimental observations with computer simulations enables us to identify the key structural drivers and elucidate the reaction mechanisms. [1]L. Piccolo, in Nanoalloys: Synthesis, Structure and Properties, edited by D. Alloyeau, C. Mottet, and C. Ricolleau (Springer London, 2012), pp. 369–404.[2]L. Piccolo and L. Kibis, J. Catal. 332, 112 (2015).[3]T.-S. Nguyen, D. Laurenti, P. Afanasiev, Z. Konuspayeva, and L. Piccolo, J. Catal. 344, 136 (2016).[4]F. Morfin, T.-S. Nguyen, J.-L. Rousset, and L. Piccolo, Appl. Catal. B 197, 2 (2016).[5]C. Zlotea, F. Morfin, T.-S. Nguyen, N.-T. Nguyen, J. Nelayah, C. Ricolleau, M. Latroche, and L. Piccolo, Nanoscale 6, 9955 (2014).[6]C. Goyhenex and L. Piccolo, Phys. Chem. Chem. Phys. 19, 32451 (2017).[7]C. Zlotea, Y. Oumellal, K. Provost, F. Morfin, and L. Piccolo, Appl. Catal. B 237, 1059 (2018).[8]A. Kaftan, F. Kollhoff, T.-S. Nguyen, L. Piccolo, M. Laurin, and J. Libuda, Catal. Sci. Technol. 6, 818 (2016).[9]L. Piccolo, Z. Y. Li, I. Demiroglu, F. Moyon, Z. Konuspayeva, G. Berhault, P. Afanasiev, W. Lefebvre, J. Yuan, and R. L. Johnston, Sci. Rep. 6, 35226 (2016).[10]I. Demiroglu, T. Fan, Z. Li, J. Yuan, T. Liu, L. Piccolo, and R. L. Johnston, Faraday Discuss. 208, 53 (2018)
Nanocatalysis for energy applications
SSCI-VIDE+ECI2D+LPIInternational audienceHeterogeneous catalysis, which is currently used in most industrial chemical processes, has an even stronger role to play in the energy transition, owing to its intrinsic ability to decrease the activation energy of thermodynamically feasible reactions.1 Present and future applications of catalysis for energy -including photo- and electrocatalysis- comprise petroleum refining, fuel cells, batteries, hydrogen production and storage, and biomass conversion.2 Heterogeneous catalysts often consist of transition metal nanoparticles and, more recently, single atoms supported on high-surface-area solids. This presentation will illustrate several fundamental aspects of nanocatalysis for energy-related reactions such as preferential oxidation of CO,3–5 methane reforming,6 and hydrodeoxygenation of biosourced compounds.7 It will be shown that the careful design of nanocatalysts, through the choice of suitable metals and supports, and the tuning of nanoparticle size and composition,1 allow improving catalytic performances. These investigations benefit from the use of advanced microscopy and spectroscopy techniques as well as computational methods,8–10 revealing the interplay between catalyst structure, reaction medium, and catalytic properties. (1) Piccolo, L. Surface Studies of Catalysis by Metals: Nanosize and Alloying Effects. In Nanoalloys: Synthesis, Structure and Properties; Alloyeau, D., Mottet, C., Ricolleau, C., Eds.; Engineering Materials; Springer London, 2012; pp 369–404.(2) New and Future Developments in Catalysis, S.L. Suib.; Elsevier: Amsterdam, 2013.(3) Zlotea, C.; Morfin, F.; Nguyen, T.-S.; Nguyen, N.-T.; Nelayah, J.; Ricolleau, C.; Latroche, M.; Piccolo, L. Nanoscale 2014, 6, 9955–9959.(4) Morfin, F.; Nguyen, T.-S.; Rousset, J.-L.; Piccolo, L. Appl. Catal. B 2016, 197, 2–13.(5) Zlotea, C.; Oumellal, Y.; Provost, K.; Morfin, F.; Piccolo, L. Appl. Catal. B 2018, 237, 1059–1065.(6) Nguyen, T. S.; Postole, G.; Loridant, S.; Bosselet, F.; Burel, L.; Aouine, M.; Massin, L.; Morfin, F.; Gélin, P.; Piccolo, L. J. Mater. Chem. A 2014, 2, 19822–19832.(7) Nguyen, T.-S.; Laurenti, D.; Afanasiev, P.; Konuspayeva, Z.; Piccolo, L. J. Catal. 2016, 344, 136–140.(8) Piccolo, L.; Li, Z. Y.; Demiroglu, I.; Moyon, F.; Konuspayeva, Z.; Berhault, G.; Afanasiev, P.; Lefebvre, W.; Yuan, J.; Johnston, R. L. Sci. Rep. 2016, 6, 35226.(9) Roiban, L.; Koneti, S.; Morfin, F.; Nguyen, T.-S.; Mascunan, P.; Aouine, M.; Epicier, T.; Piccolo, L. ChemCatChem 2017, 9, 4607–4613.(10) Goyhenex, C.; Piccolo, L. Phys. Chem. Chem. Phys. 2017, 19, 32451–32458
Nanocatalysis for energy applications
SSCI-VIDE+ECI2D+LPIInternational audienceHeterogeneous catalysis, which is currently used in most industrial chemical processes, has an even stronger role to play in the energy transition, owing to its intrinsic ability to decrease the activation energy of thermodynamically feasible reactions.1 Present and future applications of catalysis for energy -including photo- and electrocatalysis- comprise petroleum refining, fuel cells, batteries, hydrogen production and storage, and biomass conversion.2 Heterogeneous catalysts often consist of transition metal nanoparticles and, more recently, single atoms supported on high-surface-area solids. This presentation will illustrate several fundamental aspects of nanocatalysis for energy-related reactions such as preferential oxidation of CO,3–5 methane reforming,6 and hydrodeoxygenation of biosourced compounds.7 It will be shown that the careful design of nanocatalysts, through the choice of suitable metals and supports, and the tuning of nanoparticle size and composition,1 allow improving catalytic performances. These investigations benefit from the use of advanced microscopy and spectroscopy techniques as well as computational methods,8–10 revealing the interplay between catalyst structure, reaction medium, and catalytic properties. (1) Piccolo, L. Surface Studies of Catalysis by Metals: Nanosize and Alloying Effects. In Nanoalloys: Synthesis, Structure and Properties; Alloyeau, D., Mottet, C., Ricolleau, C., Eds.; Engineering Materials; Springer London, 2012; pp 369–404.(2) New and Future Developments in Catalysis, S.L. Suib.; Elsevier: Amsterdam, 2013.(3) Zlotea, C.; Morfin, F.; Nguyen, T.-S.; Nguyen, N.-T.; Nelayah, J.; Ricolleau, C.; Latroche, M.; Piccolo, L. Nanoscale 2014, 6, 9955–9959.(4) Morfin, F.; Nguyen, T.-S.; Rousset, J.-L.; Piccolo, L. Appl. Catal. B 2016, 197, 2–13.(5) Zlotea, C.; Oumellal, Y.; Provost, K.; Morfin, F.; Piccolo, L. Appl. Catal. B 2018, 237, 1059–1065.(6) Nguyen, T. S.; Postole, G.; Loridant, S.; Bosselet, F.; Burel, L.; Aouine, M.; Massin, L.; Morfin, F.; Gélin, P.; Piccolo, L. J. Mater. Chem. A 2014, 2, 19822–19832.(7) Nguyen, T.-S.; Laurenti, D.; Afanasiev, P.; Konuspayeva, Z.; Piccolo, L. J. Catal. 2016, 344, 136–140.(8) Piccolo, L.; Li, Z. Y.; Demiroglu, I.; Moyon, F.; Konuspayeva, Z.; Berhault, G.; Afanasiev, P.; Lefebvre, W.; Yuan, J.; Johnston, R. L. Sci. Rep. 2016, 6, 35226.(9) Roiban, L.; Koneti, S.; Morfin, F.; Nguyen, T.-S.; Mascunan, P.; Aouine, M.; Epicier, T.; Piccolo, L. ChemCatChem 2017, 9, 4607–4613.(10) Goyhenex, C.; Piccolo, L. Phys. Chem. Chem. Phys. 2017, 19, 32451–32458
Interplay between structure, environment and performance in nanocatalysis and single-atom catalysis
SSCI-VIDE+ECI2D+LPIInternational audienceRecent progress in nanomaterials preparation, characterization and theoretical modeling opens the way to tailoring catalysts and understanding their operating mode at the atomic level. Many strategies are possible for improving the performances of metal-based catalysts, e.g., as done in our laboratory, through the use of alloy phases (noble metal nanoalloys [1] and non-noble intermetallics [2]) and/or reducible oxide supports (TiO2 [3] and CeO2 [4]). It will be shown that the targeted catalytic processes (selective hydrogenations and preferential CO oxidation) all benefit from metal-metal and/or metal-oxide synergies. Since these reactions involve hydrogen-rich environments, hydrogen absorption in the metal lattice can have a drastic influence on the catalytic properties [5,6]. Advanced microscopies and spectroscopies reveal additional major effects of the gaseous atmosphere and the support on the metal phase, such as changes in nanoparticle morphology, chemical arrangement and oxidation state (Fig. 1) [4,7]. Finally, as will be shown from operando techniques in the prototypical case of CO oxidation over Pt/-Al2O3, the influence of the thermochemical environment is even more dramatic for the stability of recently emerging “singe-atom catalysts” [8,9]. Confronting experimental observations with computer simulations enables us to identify the key structural drivers and elucidate the reaction mechanisms [2,7,9,10].[1]L. Piccolo, in: D. Alloyeau, C. Mottet, C. Ricolleau (Eds.), Nanoalloys: Synthesis, Structure and Properties, Springer London, 2012, pp. 369–404.[2]L. Piccolo, C. Chatelier, M.-C.D. Weerd, F. Morfin, J. Ledieu, V. Fournée, P. Gille, E. Gaudry, Sci. Technol. Adv. Mater. 20 (2019) 557–567.[3]T.-S. Nguyen, D. Laurenti, P. Afanasiev, Z. Konuspayeva, L. Piccolo, J. Catal. 344 (2016) 136–140.[4]F. Morfin, T.-S. Nguyen, J.-L. Rousset, L. Piccolo, Appl. Catal. B 197 (2016) 2–13.[5]C. Zlotea, F. Morfin, T.-S. Nguyen, N.-T. Nguyen, J. Nelayah, C. Ricolleau, M. Latroche, L. Piccolo, Nanoscale 6 (2014) 9955–9959.[6]C. Zlotea, Y. Oumellal, K. Provost, F. Morfin, L. Piccolo, Appl. Catal. B 237 (2018) 1059–1065.[7]L. Piccolo, Z.Y. Li, I. Demiroglu, F. Moyon, Z. Konuspayeva, G. Berhault, P. Afanasiev, W. Lefebvre, J. Yuan, R.L. Johnston, Sci. Rep. 6 (2016) 35226.[8]C. Dessal, T. Len, F. Morfin, J.-L. Rousset, M. Aouine, P. Afanasiev, L. Piccolo, ACS Catal. 9 (2019) 5752–5759.[9]C. Dessal, A. Sangnier, C. Chizallet, C. Dujardin, F. Morfin, J.-L. Rousset, M. Aouine, M. Bugnet, P. Afanasiev, L. Piccolo, Nanoscale 11 (2019) 6897–6904.[10]C. Goyhenex, L. Piccolo, Phys. Chem. Chem. Phys. 19 (2017) 32451–32458
Environment effects in heterogeneous catalysis: from nanoparticles to single atoms
SSCI-VIDE+ECI2D+LPIInternational audienceRecent progress in nanomaterials preparation, characterization and theoretical modeling opens the way to tailoring catalysts and understanding their operating mode at the atomic level. Many strategies are possible for improving the performances of metal-based catalysts, e.g., as done in our laboratory, through the use of alloy phases (noble metal nanoalloys1 and non-noble intermetallics2) and/or reducible oxide supports (e.g. TiO2 3 and CeO2 4). It will be shown that the targeted catalytic processes (selective hydrogenations and preferential CO oxidation) all benefit from metal-metal and/or metal-oxide synergies. As these reactions involve hydrogen-rich environments, hydrogen absorption in the metal lattice can have a drastic influence on the catalytic properties.5,6 Moreover, advanced microscopy and spectroscopy techniques reveal additional major effects of the gaseous atmosphere and the support on the catalyst phase, such as changes in nanoparticle morphology, chemical arrangement and oxidation state (Fig. 1).4,7 Finally, as will be shown from operando techniques in the prototypical case of CO oxidation over Pt/-Al2O3, the influence of the thermochemical environment is even more dramatic for the stability of recently emerging “singe-atom catalysts”.8,9 Confronting experimental observations with computer simulations enables us to identify the key structural drivers and elucidate the reaction mechanisms.2,7,9,10(1) Piccolo, L. Surface Studies of Catalysis by Metals: Nanosize and Alloying Effects. In Nanoalloys: Synthesis, Structure and Properties; Alloyeau, D., Mottet, C., Ricolleau, C., Eds.; Engineering Materials; Springer London, 2012; pp 369–404.(2) Piccolo, L.; Chatelier, C.; Weerd, M.-C. D.; Morfin, F.; Ledieu, J.; Fournée, V.; Gille, P.; Gaudry, E. Sci. Technol. Adv. Mater. 2019, 20, 557–567.(3) Nguyen, T.-S.; Laurenti, D.; Afanasiev, P.; Konuspayeva, Z.; Piccolo, L. J. Catal. 2016, 344, 136–140.(4) Morfin, F.; Nguyen, T.-S.; Rousset, J.-L.; Piccolo, L. Appl. Catal. B 2016, 197, 2–13.(5) Zlotea, C.; Morfin, F.; Nguyen, T.-S.; Nguyen, N.-T.; Nelayah, J.; Ricolleau, C.; Latroche, M.; Piccolo, L. Nanoscale 2014, 6, 9955–9959.(6) Zlotea, C.; Oumellal, Y.; Provost, K.; Morfin, F.; Piccolo, L. Appl. Catal. B 2018, 237, 1059–1065.(7) Piccolo, L.; Li, Z. Y.; Demiroglu, I.; Moyon, F.; Konuspayeva, Z.; Berhault, G.; Afanasiev, P.; Lefebvre, W.; Yuan, J.; Johnston, R. L. Sci. Rep. 2016, 6, 35226.(8) Dessal, C.; Len, T.; Morfin, F.; Rousset, J.-L.; Aouine, M.; Afanasiev, P.; Piccolo, L. ACS Catal. 2019, 9, 5752–5759.(9) Dessal, C.; Sangnier, A.; Chizallet, C.; Dujardin, C.; Morfin, F.; Rousset, J.-L.; Aouine, M.; Bugnet, M.; Afanasiev, P.; Piccolo, L. Nanoscale 2019, 11, 6897–6904.(10) Goyhenex, C.; Piccolo, L. Phys. Chem. Chem. Phys. 2017, 19, 32451–32458
Interplay between structure, environment and performance in nanocatalysis and single-atom catalysis
SSCI-VIDE+ECI2D+LPIInternational audienceRecent progress in nanomaterials preparation, characterization and theoretical modeling opens the way to tailoring catalysts and understanding their operating mode at the atomic level. Many strategies are possible for improving the performances of metal-based catalysts, e.g., as done in our laboratory, through the use of alloy phases (noble metal nanoalloys [1] and non-noble intermetallics [2]) and/or reducible oxide supports (TiO2 [3] and CeO2 [4]). It will be shown that the targeted catalytic processes (selective hydrogenations and preferential CO oxidation) all benefit from metal-metal and/or metal-oxide synergies. Since these reactions involve hydrogen-rich environments, hydrogen absorption in the metal lattice can have a drastic influence on the catalytic properties [5,6]. Advanced microscopies and spectroscopies reveal additional major effects of the gaseous atmosphere and the support on the metal phase, such as changes in nanoparticle morphology, chemical arrangement and oxidation state (Fig. 1) [4,7]. Finally, as will be shown from operando techniques in the prototypical case of CO oxidation over Pt/-Al2O3, the influence of the thermochemical environment is even more dramatic for the stability of recently emerging “singe-atom catalysts” [8,9]. Confronting experimental observations with computer simulations enables us to identify the key structural drivers and elucidate the reaction mechanisms [2,7,9,10].[1]L. Piccolo, in: D. Alloyeau, C. Mottet, C. Ricolleau (Eds.), Nanoalloys: Synthesis, Structure and Properties, Springer London, 2012, pp. 369–404.[2]L. Piccolo, C. Chatelier, M.-C.D. Weerd, F. Morfin, J. Ledieu, V. Fournée, P. Gille, E. Gaudry, Sci. Technol. Adv. Mater. 20 (2019) 557–567.[3]T.-S. Nguyen, D. Laurenti, P. Afanasiev, Z. Konuspayeva, L. Piccolo, J. Catal. 344 (2016) 136–140.[4]F. Morfin, T.-S. Nguyen, J.-L. Rousset, L. Piccolo, Appl. Catal. B 197 (2016) 2–13.[5]C. Zlotea, F. Morfin, T.-S. Nguyen, N.-T. Nguyen, J. Nelayah, C. Ricolleau, M. Latroche, L. Piccolo, Nanoscale 6 (2014) 9955–9959.[6]C. Zlotea, Y. Oumellal, K. Provost, F. Morfin, L. Piccolo, Appl. Catal. B 237 (2018) 1059–1065.[7]L. Piccolo, Z.Y. Li, I. Demiroglu, F. Moyon, Z. Konuspayeva, G. Berhault, P. Afanasiev, W. Lefebvre, J. Yuan, R.L. Johnston, Sci. Rep. 6 (2016) 35226.[8]C. Dessal, T. Len, F. Morfin, J.-L. Rousset, M. Aouine, P. Afanasiev, L. Piccolo, ACS Catal. 9 (2019) 5752–5759.[9]C. Dessal, A. Sangnier, C. Chizallet, C. Dujardin, F. Morfin, J.-L. Rousset, M. Aouine, M. Bugnet, P. Afanasiev, L. Piccolo, Nanoscale 11 (2019) 6897–6904.[10]C. Goyhenex, L. Piccolo, Phys. Chem. Chem. Phys. 19 (2017) 32451–32458
Interplay between structure, environment and performance in nanocatalysis and single-atom catalysis
SSCI-VIDE+ECI2D+LPIInternational audienceRecent progress in nanomaterials preparation, characterization and theoretical modeling opens the way to tailoring catalysts and understanding their operating mode at the atomic level. Many strategies are possible for improving the performances of metal-based catalysts, e.g., as done in our laboratory, through the use of alloy phases (noble metal nanoalloys [1] and non-noble intermetallics [2]) and/or reducible oxide supports (TiO2 [3] and CeO2 [4]). It will be shown that the targeted catalytic processes (selective hydrogenations and preferential CO oxidation) all benefit from metal-metal and/or metal-oxide synergies. Since these reactions involve hydrogen-rich environments, hydrogen absorption in the metal lattice can have a drastic influence on the catalytic properties [5,6]. Advanced microscopies and spectroscopies reveal additional major effects of the gaseous atmosphere and the support on the metal phase, such as changes in nanoparticle morphology, chemical arrangement and oxidation state (Fig. 1) [4,7]. Finally, as will be shown from operando techniques in the prototypical case of CO oxidation over Pt/gamma-Al2O3, the influence of the thermochemical environment is even more dramatic for the stability of recently emerging “singe-atom catalysts” [8,9]. Confronting experimental observations with computer simulations enables us to identify the key structural drivers and elucidate the reaction mechanisms [2,7,9,10].[1]L. Piccolo, in: D. Alloyeau, C. Mottet, C. Ricolleau (Eds.), Nanoalloys: Synthesis, Structure and Properties, Springer London, 2012, pp. 369–404.[2]L. Piccolo, C. Chatelier, M.-C.D. Weerd, F. Morfin, J. Ledieu, V. Fournée, P. Gille, E. Gaudry, Sci. Technol. Adv. Mater. 20 (2019) 557–567.[3]T.-S. Nguyen, D. Laurenti, P. Afanasiev, Z. Konuspayeva, L. Piccolo, J. Catal. 344 (2016) 136–140.[4]F. Morfin, T.-S. Nguyen, J.-L. Rousset, L. Piccolo, Appl. Catal. B 197 (2016) 2–13.[5]C. Zlotea, F. Morfin, T.-S. Nguyen, N.-T. Nguyen, J. Nelayah, C. Ricolleau, M. Latroche, L. Piccolo, Nanoscale 6 (2014) 9955–9959.[6]C. Zlotea, Y. Oumellal, K. Provost, F. Morfin, L. Piccolo, Appl. Catal. B 237 (2018) 1059–1065.[7]L. Piccolo, Z.Y. Li, I. Demiroglu, F. Moyon, Z. Konuspayeva, G. Berhault, P. Afanasiev, W. Lefebvre, J. Yuan, R.L. Johnston, Sci. Rep. 6 (2016) 35226.[8]C. Dessal, T. Len, F. Morfin, J.-L. Rousset, M. Aouine, P. Afanasiev, L. Piccolo, ACS Catal. 9 (2019) 5752–5759.[9]C. Dessal, A. Sangnier, C. Chizallet, C. Dujardin, F. Morfin, J.-L. Rousset, M. Aouine, M. Bugnet, P. Afanasiev, L. Piccolo, Nanoscale 11 (2019) 6897–6904.[10]C. Goyhenex, L. Piccolo, Phys. Chem. Chem. Phys. 19 (2017) 32451–32458
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