ChemCatChem 2025 (Schellenburg)
Type: Publication show more
ObjectId: 35886
Created: 11/9/2025 9:59:56 PM by A06) Dhaka Kapil [kapil.dhaka@uni-due.de]
Updated: 11/9/2025 11:47:58 PM by A06) Dhaka Kapil [kapil.dhaka@uni-due.de]
Access: Public Sort Code (asc): 0
License: CC BY 4.0
Description: D. Schellenburg, T. Bihnam, C. Placke-Yan, G. Bendt, O. Prymak, T. Sato, D. Jennings, C. Leiva-Leroy, D. Zhang, M. Nachev, K. Dhaka, F. Nkou, U. Hagemann, M. Heidelmann, S. Kenmoe, K. S. Exner, B. Sures, M. Muhler, C. H. Liebscher, A. Schnegg, S. Schulz, S. Barcikowski, S. Reichenberger, “Mechanistic Understanding of Laser-Induced Defect Engineering of Anisotropic Cobalt Oxide Spinel Platelets in Water,” ChemCatChem, 2025, 17, e202501054. DOI: 10.1002/cctc.202501054.
File attached: file not found [ChemCatChem - 2025 - Schellenburg - Mechanistic Understanding of Laser‐Induced Defect Engineering of Anisotropic Cobalt.pdf]
InfProject.Models.Reference - generic form start
ReferenceId: 35886
Authors list (comma-separated): D. Schellenburg, T. Bihnam, C. Placke-Yan, G. Bendt, O. Prymak, T. Sato, D. Jennings, C. Leiva-Leroy, D. Zhang, M. Nachev, K. Dhaka, F. Nkou, U. Hagemann, M. Heidelmann, S. Kenmoe, K. S. Exner, B. Sures, M. Muhler, C. H. Liebscher, A. Schnegg, S. Schulz, S. Barcikowski, S. Reichenberger
Title: Mechanistic Understanding of Laser-Induced Defect Engineering of Anisotropic Cobalt Oxide Spinel Platelets in Water
Journal: ChemCatChem
Year: 2025
Volume: 17
Number (issue):
Start Page: e202501054
End Page:
DOI: 10.1002/cctc.202501054
URL: https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/cctc.202501054
BibTeX :
InfProject.Models.Reference - generic form end
Associated Objects
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OER_at_Co3O4(111)
Catalysis Results (png)Structural models and reaction energetics of OER on Co 3 O4 (111) with different hydroxyl (*OH) coverages. a) Different possible terminations of theCo 3 O4 {111} facet, highlighting the selected Co-rich Co 3+ termination. b) Bare Co-rich Co 3+ terminated Co 3 O4 (111) surface. c) Hydroxylated Co 3 O4 (111)termination, showing the adsorption configuration of *OH groups. d) Free energy diagram for OER at U = 1.53 V versus RHE, comparing 8OH, 12OH, and16OH coverages. The equation was done using descriptor-based analysis (descriptor Gmax (U)), assuming the mononuclear OER mechanism.[69] The limitingsteps are indicated by arrows in blue, green, and red with the corresponding activation energy.
OER_at_Co3O4(111).png
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Archive-3EG_6OH_Co3+terminated
AIMD raw data (xyz, ener, vel, restart, in, out, inp, zip) Archive-3EG_6OH_Co3+terminated.zip -
Electron_density-Electrostatic_Potential_FinalConfigure_20ps
AIMD raw data (xyz, ener, vel, restart, in, out, inp, zip) Electron_density-Electrostatic_Potential_FinalConfigure_20ps.zip -
Electron_density-Electrostatic_Potential_InitialConfiguration
AIMD raw data (xyz, ener, vel, restart, in, out, inp, zip) Electron_density-Electrostatic_Potential_InitialConfiguration.zip -
4EG_4OH-Electron_density_4EG_4OH-Electrostatic_Potential_InitialConfiguration
AIMD raw data (xyz, ener, vel, restart, in, out, inp, zip) 4EG_4OH-Electron_density_4EG_4OH-Electrostatic_Potential_FinalConfiguration.zip -
4EG_4OH-Electron_density_Electrostatic_Potential_FinalConfiguration_20ps
AIMD raw data (xyz, ener, vel, restart, in, out, inp, zip) Electron_density-4EG_4OH_Electrostatic_Potential_FinalConfigure_20ps.zip -
Archive-4EG_4OH_Co3+terminated
AIMD raw data (xyz, ener, vel, restart, in, out, inp, zip) Archive-4EG_4OH_Co3+terminated.zip
All properties (except table)
No properties found