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489 results on '"Cargnello, Matteo"'

1. Steam‐Assisted Selective CO2 Hydrogenation to Ethanol over Ru−In Catalysts

Author

Zhou, Chengshuang, Aitbekova, Aisulu, Liccardo, Gennaro, Oh, Jinwon, Stone, Michael L, McShane, Eric J, Werghi, Baraa, Nathan, Sindhu, Song, Chengyu, Ciston, Jim, Bustillo, Karen C, Hoffman, Adam S, Hong, Jiyun, Perez‐Aguilar, Jorge, Bare, Simon R, and Cargnello, Matteo

Subjects
Chemical Sciences, CO2 Hydrogenation, Heterogeneous Cataysis, Higher Alcohol Synthesis, Strong Metal-Support Interaction, Structure-Performance Relationship, Organic Chemistry, Chemical sciences
Abstract

Multicomponent catalysts can be designed to synergistically combine reaction intermediates at interfacial active sites, but restructuring makes systematic control and understanding of such dynamics challenging. We here unveil how reducibility and mobility of indium oxide species in Ru-based catalysts crucially control the direct, selective conversion of CO2 to ethanol. When uncontrolled, reduced indium oxide species occupy the Ru surface, leading to deactivation. With the addition of steam as a mild oxidant and using porous polymer layers to control In mobility, Ru-In2O3 interface sites are stabilized, and ethanol can be produced with superior overall selectivity (70 %, rest CO). Our work highlights how engineering of bifunctional active ensembles enables cooperativity and synergy at tailored interfaces, which unlocks unprecedented performance in heterogeneous catalysts.

Published
2024

2. Templated encapsulation of platinum-based catalysts promotes high-temperature stability to 1,100 °C

Author

Aitbekova, Aisulu, Zhou, Chengshuang, Stone, Michael L, Lezama-Pacheco, Juan Salvador, Yang, An-Chih, Hoffman, Adam S, Goodman, Emmett D, Huber, Philipp, Stebbins, Jonathan F, Bustillo, Karen C, Ercius, Peter, Ciston, Jim, Bare, Simon R, Plessow, Philipp N, and Cargnello, Matteo

Subjects
Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Affordable and Clean Energy, Platinum, Temperature, Metal Nanoparticles, Steam, Aluminum Oxide, Nanoscience & Nanotechnology
Abstract

Stable catalysts are essential to address energy and environmental challenges, especially for applications in harsh environments (for example, high temperature, oxidizing atmosphere and steam). In such conditions, supported metal catalysts deactivate due to sintering-a process where initially small nanoparticles grow into larger ones with reduced active surface area-but strategies to stabilize them can lead to decreased performance. Here we report stable catalysts prepared through the encapsulation of platinum nanoparticles inside an alumina framework, which was formed by depositing an alumina precursor within a separately prepared porous organic framework impregnated with platinum nanoparticles. These catalysts do not sinter at 800 °C in the presence of oxygen and steam, conditions in which conventional catalysts sinter to a large extent, while showing similar reaction rates. Extending this approach to Pd-Pt bimetallic catalysts led to the small particle size being maintained at temperatures as high as 1,100 °C in air and 10% steam. This strategy can be broadly applied to other metal and metal oxides for applications where sintering is a major cause of material deactivation.

Published
2022

4. Atmospheric methane removal: a research agenda

Author

Jackson, Robert B, Abernethy, Sam, Canadell, Josep G, Cargnello, Matteo, Davis, Steven J, Fron, Sarah, Fuss, Sabine, Heyer, Alexander J, Hong, Chaopeng, Jones, Chris D, Matthews, H Damon, O'Connor, Fiona M, Pisciotta, Maxwell, Rhoda, Hannah M, de Richter, Renaud, Solomon, Edward I, Wilcox, Jennifer L, and Zickfeld, Kirsten

Subjects
Climate Action, methane oxidation, negative emissions, Methane Removal Model Intercomparison Project, iron salt aerosols, solar photocatalysts, zeolites, General Science & Technology
Abstract

Atmospheric methane removal (e.g. in situ methane oxidation to carbon dioxide) may be needed to offset continued methane release and limit the global warming contribution of this potent greenhouse gas. Because mitigating most anthropogenic emissions of methane is uncertain this century, and sudden methane releases from the Arctic or elsewhere cannot be excluded, technologies for methane removal or oxidation may be required. Carbon dioxide removal has an increasingly well-established research agenda and technological foundation. No similar framework exists for methane removal. We believe that a research agenda for negative methane emissions-'removal' or atmospheric methane oxidation-is needed. We outline some considerations for such an agenda here, including a proposed Methane Removal Model Intercomparison Project (MR-MIP). This article is part of a discussion meeting issue 'Rising methane: is warming feeding warming? (part 1)'.

Published
2021

5. Monolayer Support Control and Precise Colloidal Nanocrystals Demonstrate Metal–Support Interactions in Heterogeneous Catalysts

Author

Goodman, Emmett D, Asundi, Arun S, Hoffman, Adam S, Bustillo, Karen C, Stebbins, Jonathan F, Bare, Simon R, Bent, Stacey F, and Cargnello, Matteo

Subjects
Engineering, Chemical Sciences, Nanotechnology, atomic layer deposition, colloidal nanocrystals, heterogeneous catalysis, metal-support interactions, monolayer control, Physical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Electronic and geometric interactions between active and support phases are critical in determining the activity of heterogeneous catalysts, but metal-support interactions are challenging to study. Here, it is demonstrated how the combination of the monolayer-controlled formation using atomic layer deposition (ALD) and colloidal nanocrystal synthesis methods leads to catalysts with sub-nanometer precision of active and support phases, thus allowing for the study of the metal-support interactions in detail. The use of this approach in developing a fundamental understanding of support effects in Pd-catalyzed methane combustion is demonstrated. Uniform Pd nanocrystals are deposited onto Al2 O3 /SiO2 spherical supports prepared with control over morphology and Al2 O3 layer thicknesses ranging from sub-monolayer to a ≈4 nm thick uniform coating. Dramatic changes in catalytic activity depending on the coverage and structure of Al2 O3 situated at the Pd/Al2 O3 interface are observed, with even a single monolayer of alumina contributing an order of magnitude increase in reaction rate. By building the Pd/Al2 O3 interface up layer-by-layer and using uniform Pd nanocrystals, this work demonstrates the importance of controlled and tunable materials in determining metal-support interactions and catalyst activity.

Published
2021

6. Voltage cycling process for the electroconversion of biomass-derived polyols

Author

Kim, Dohyung, Zhou, Chengshuang, Zhang, Miao, and Cargnello, Matteo

Subjects
Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Climate Action, electroconversion, platinum, polyols, voltage cycling
Abstract

Electrification of chemical reactions is crucial to fundamentally transform our society that is still heavily dependent on fossil resources and unsustainable practices. In addition, electrochemistry-based approaches offer a unique way of catalyzing reactions by the fast and continuous alteration of applied potentials, unlike traditional thermal processes. Here, we show how the continuous cyclic application of electrode potential allows Pt nanoparticles to electrooxidize biomass-derived polyols with turnover frequency improved by orders of magnitude compared with the usual rates at fixed potential conditions. Moreover, secondary alcohol oxidation is enhanced, with a ketoses-to-aldoses ratio increased up to sixfold. The idea has been translated into the construction of a symmetric single-compartment system in a two-electrode configuration. Its operation via voltage cycling demonstrates high-rate sorbitol electrolysis with the formation of H2 as a desired coproduct at operating voltages below 1.4 V. The devised method presents a potential approach to using renewable electricity to drive chemical processes.

Published
2021

8. A semi-continuous process for co-production of CO2-free hydrogen and carbon nanotubes via methane pyrolysis

Author

Sun, Eddie, Zhai, Shang, Kim, Dohyung, Gigantino, Marco, Haribal, Vasudev, Dewey, Oliver S., Williams, Steven M., Wan, Gang, Nelson, Alexander, Marin-Quiros, Sebastian, Martis, Joel, Zhou, Chengshuang, Oh, Jinwon, Randall, Richard, Kessler, Max, Kong, Dongjae, Rojas, Jimmy, Tong, Andrew, Xu, Xintong, Huff, Cassandra, Pasquali, Matteo, Gupta, Raghubir, Cargnello, Matteo, and Majumdar, Arun

Published
2023
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9. Steam‐Assisted Selective CO2 Hydrogenation to Ethanol over Ru−In Catalysts.

Author

Zhou, Chengshuang, Aitbekova, Aisulu, Liccardo, Gennaro, Oh, Jinwon, Stone, Michael L., McShane, Eric J., Werghi, Baraa, Nathan, Sindhu, Song, Chengyu, Ciston, Jim, Bustillo, Karen C., Hoffman, Adam S., Hong, Jiyun, Perez‐Aguilar, Jorge, Bare, Simon R., and Cargnello, Matteo

Subjects
HETEROGENEOUS catalysts, POROUS polymers, INTERFACIAL reactions, CARBON dioxide, CATALYSTS, RUTHENIUM catalysts, INDIUM oxide
Abstract

Multicomponent catalysts can be designed to synergistically combine reaction intermediates at interfacial active sites, but restructuring makes systematic control and understanding of such dynamics challenging. We here unveil how reducibility and mobility of indium oxide species in Ru‐based catalysts crucially control the direct, selective conversion of CO2 to ethanol. When uncontrolled, reduced indium oxide species occupy the Ru surface, leading to deactivation. With the addition of steam as a mild oxidant and using porous polymer layers to control In mobility, Ru−In2O3 interface sites are stabilized, and ethanol can be produced with superior overall selectivity (70 %, rest CO). Our work highlights how engineering of bifunctional active ensembles enables cooperativity and synergy at tailored interfaces, which unlocks unprecedented performance in heterogeneous catalysts. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Dynamic structural evolution of supported palladium-ceria core-shell catalysts revealed by in situ electron microscopy.

Author

Zhang, Shuyi, Chen, Chen, Cargnello, Matteo, Fornasiero, Paolo, Gorte, Raymond, Graham, George, and Pan, Xiaoqing

Abstract

The exceptional activity for methane combustion of modular palladium-ceria core-shell subunits on silicon-functionalized alumina that was recently reported has created renewed interest in the potential of core-shell structures as catalysts. Here we report on our use of advanced ex situ and in situ electron microscopy with atomic resolution to show that the modular palladium-ceria core-shell subunits undergo structural evolution over a wide temperature range. In situ observations performed in an atmospheric gas cell within this temperature range provide real-time evidence that the palladium and ceria nanoparticle constituents of the palladium-ceria core-shell participate in a dynamical process that leads to the formation of an unanticipated structure comprised of an intimate mixture of palladium, cerium, silicon and oxygen, with very high dispersion. This finding may open new perspectives about the origin of the activity of this catalyst.

Published
2015

25. A rigorous electrochemical ammonia synthesis protocol with quantitative isotope measurements

Author

Andersen, Suzanne Z., Čolić, Viktor, Yang, Sungeun, Schwalbe, Jay A., Nielander, Adam C., McEnaney, Joshua M., Enemark-Rasmussen, Kasper, Baker, Jon G., Singh, Aayush R., Rohr, Brian A., Statt, Michael J., Blair, Sarah J., Mezzavilla, Stefano, Kibsgaard, Jakob, Vesborg, Peter C. K., Cargnello, Matteo, Bent, Stacey F., Jaramillo, Thomas F., Stephens, Ifan E. L., Nørskov, Jens K., and Chorkendorff, Ib

Published
2019
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31. Engineering titania nanostructure to tune and improve its photocatalytic activity

Author

Cargnello, Matteo, Montini, Tiziano, Smolin, Sergey Y., Priebe, Jacqueline B., Jaén, Juan J. Delgado, Doan-Nguyen, Vicky V. T., McKay, Ian S., Schwalbe, Jay A., Pohl, Marga-Martina, Gordon, Thomas R., Lu, Yupeng, Baxter, Jason B., Brückner, Angelika, Fornasiero, Paolo, and Murray, Christopher B.

Published
2016

42. Controlling the Strong Metal‐Support Interaction Overlayer Structure in Pt/TiO2 Catalysts Prevents Particle Evaporation.

Author

Beck, Arik, Frey, Hannes, Huang, Xing, Clark, Adam H., Goodman, Emmett D., Cargnello, Matteo, Willinger, Marc, and van Bokhoven, Jeroen A.

Subjects
PLATINUM nanoparticles, CATALYST structure, TRANSMISSION electron microscopy, PRECIOUS metals, METAL catalysts
Abstract

Platinum nanoparticles (NPs) supported by titania exhibit a strong metal‐support interaction (SMSI)[1] that can induce overlayer formation and encapsulation of the NP's with a thin layer of support material. This encapsulation modifies the catalyst's properties, such as increasing its chemoselectivity[2] and stabilizing it against sintering.[3] Encapsulation is typically induced during high‐temperature reductive activation and can be reversed through oxidative treatments.[1] However, recent findings indicate that the overlayer can be stable in oxygen.[4, 5] Using in situ transmission electron microscopy, we investigated how the overlayer changes with varying conditions. We found that exposure to oxygen below 400 °C caused disorder and removal of the overlayer upon subsequent hydrogen treatment. In contrast, elevating the temperature to 900 °C while maintaining the oxygen atmosphere preserved the overlayer, preventing platinum evaporation when exposed to oxygen. Our findings demonstrate how different treatments can influence the stability of nanoparticles with or without titania overlayers. expanding the concept of SMSI and enabling noble metal catalysts to operate in harsh environments without evaporation associated losses during burn‐off cycling. [ABSTRACT FROM AUTHOR]

Published
2023
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45. Templated Encapsulation of Pt-based Catalysts Promotes High-Temperature Stability to 1,100 °C

Author

Aitbekova, Aisulu, primary, Zhou, Chengshuang, additional, Stone, Michael, additional, Lezama-Pacheco, Juan, additional, Yang, An-Chih, additional, Hoffman, Adam, additional, Goodman, Emmett, additional, Huber, Philipp, additional, Stebbins, Jonathan, additional, Bustillo, Karen, additional, Ercius, Peter, additional, Ciston, Jim, additional, Bare, Simon, additional, Plessow, Philipp, additional, and Cargnello, Matteo, additional

Published
2022
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