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| Grohsjean, Alexander |
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| Falmagne, G. |
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| Erice, C. |
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| Hernandez, A. M. Vargas |
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| Leiton, A. G. Stahl |
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| Lipka, K. |
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| Pantaleo, F. |
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| Torterotot, L. |
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| Savina, M. |
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| Cerri, O. |
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| Jung, A. W. |
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| Chiarito, B. |
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| Sahin, M. O. |
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| Strong, G. |
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| Saradhy, R. |
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| Joshi, B. M. |
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| Kaynak, B. |
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| Barrera, C. Baldenegro |
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| Longo, Egidio |
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| Kolberg, Ted |
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| Ferguson, Thomas |
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| Leverington, Blake |
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| Haase, Fabian |
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| Heath, Helen F. |
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| Kokkas, Panagiotis |
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Mayrhofer, K.
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (18/18 displayed)
- 2022Engineering gold-platinum core-shell nanoparticles by self-limitation in solutioncitations
- 2021The Impact of Antimony on the Performance of Antimony Doped Tin Oxide Supported Platinum for the Oxygen Reduction Reactioncitations
- 2021Chemical Vapor Deposition of Hollow Graphitic Spheres for Improved Electrochemical Durability ; ACS Applied Energy Materialscitations
- 2020Stable and Active Oxygen Reduction Catalysts with Reduced Noble Metal Loadings through Potential Triggered Support Passivationcitations
- 2020Transition Metal-Carbon Bond Enthalpies as Descriptor for the Electrochemical Stability of Transition Metal Carbides in Electrocatalytic Applicationscitations
- 2019Towards maximized utilization of iridium for the acidic oxygen evolution reactioncitations
- 2018Influence of hydrodynamic flow patterns on the corrosion behavior of carbon steel in a neutral LiBr solutioncitations
- 2018Ir–Ni Bimetallic OER Catalysts Prepared by Controlled Ni Electrodeposition on Ir poly and Ir(111)citations
- 2018Unravelling Degradation Pathways of Oxide-Supported Pt Fuel Cell Nanocatalysts under In Situ Operating Conditionscitations
- 2017Growth of Porous Platinum Catalyst Structures on Tungsten Oxide Support Materials: A New Design for Electrodescitations
- 2017Addressing stability challenges of using bimetallic electrocatalysts: the case of gold-palladium nanoalloyscitations
- 2016Structure-Activity-Stability Relationships for Space-Confined Pt x Ni y Nanoparticles in the Oxygen Reduction Reactioncitations
- 2016High temperature stability study of carbon supported high surface area catalysts - Expanding the boundaries of ex-situ diagnosticscitations
- 2016Importance and Challenges of Electrochemical in Situ Liquid Cell Electron Microscopy for Energy Conversion Researchcitations
- 2015General Method for the Synthesis of Hollow Mesoporous Carbon Spheres with Tunable Textural Propertiescitations
- 2014Design criteria for stable Pt/C fuel cell catalystscitations
- 2014Nitrogen-Doped Hollow Carbon Spheres as a Support for Platinum-Based Electrocatalystscitations
- 2012Toward Highly Stable Electrocatalysts via Nanoparticle Pore Confinementcitations
Places of action
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article
General Method for the Synthesis of Hollow Mesoporous Carbon Spheres with Tunable Textural Properties
Abstract
A versatile synthetic procedure to prepare hollow mesoporous carbon spheres (HMCS) is presented here. This approach is based on the deposition of a homogeneous hybrid polymer/silica composite shell on the outer surface of silica spheres through the surfactant-assisted simultaneous polycondensation of silica and polymer precursors in a colloidal suspension. Such composite materials can be further processed to give hollow mesoporous carbon spheres. The flexibility of this method allows for independent control of the morphological (i.e., core diameter and shell thickness) and textural features of the carbon spheres. In particular, it is demonstrated that the size of the pores within the mesoporous shell can be precisely tailored over an extended range (2–20 nm) by simply adjusting the reaction conditions. In a similar fashion, also the specific carbon surface area as well as the total shell porosity can be tuned. Most importantly, the textural features can be adjusted without affecting the dimension or the morphology of the spheres. The possibility to directly modify the shell textural properties by varying the synthetic parameters in a scalable process represents a distinct asset over the multistep hard-templating (nanocasting) routes. As an exemplary application, Pt nanoparticles were encapsulated in the mesoporous shell of HMCS. The resulting Pt@HMCS catalyst showed an enhanced stability during the oxygen reduction reaction, one of the most important reactions in electrocatalysis. This new synthetic procedure could allow the expansion, perhaps even beyond the lab-scale, of advanced carbon nanostructured supports for applications in catalysis.