Teitl: CO₂ interaction with the violarite FeNi₂S₄{001} and {111} surfaces
Dyfyniad
Posada-Pérez S, Santos-Carballal D, Terranova U, et al. (2018). CO₂ interaction with the violarite FeNi₂S₄{001} and {111} surfaces. Cardiff University. https://doi.org/10.17035/d.2018.0046360243
Hawliau Mynediad: Gall data fod ar gael yn rhad ac am ddim yn amodol ar briodoli
Dull Mynediad: I anfon cais i gael y data hwn, ebostiwch opendata@caerdydd.ac.uk
Crewyr y Set Ddata o Brifysgol Caerdydd
Manylion y Set Ddata
Cyhoeddwr: Cardiff University
Dyddiad (y flwyddyn) pryd y daeth y data ar gael i'r cyhoedd: 2018
Fformat y data: .txt
Meddalwedd ofynnol: Any text editor.
Amcangyfrif o gyfanswm maint storio'r set ddata: Llai na 100 megabeit
DOI : 10.17035/d.2018.0046360243
DOI URL: http://doi.org/10.17035/d.2018.0046360243
The spinel structured violarite (FeNi2S4) is a ternary transition metal sulfide with an intermediate composition within the solid solution formed between Ni3S4 and greigite (Fe3S4) as end members. FeNi2S4 has structural similarities to Fe3S4, which has attracted considerable interest as a potential catalyst for the CO2 adsorption, activation and conversion. This work involved studying the structure and stabilities of various non-polar terminations of the FeNi2S4{001} and {111} surfaces by means of density functional theory (DFT) calculations. We have also investigated the CO2 interaction with the most stable terminations of FeNi2S4{001} and {111} surfaces. The data described here are ASCII files containing the atomic charges and spin moments of all the naked surface terminations and CO2 interaction geometries. Calculations were carried out using the Vienna Ab-initio Simulation Package (VASP). Research results based upon these data are pulished at http://doi.org/10.1039/C8CP03430C
Disgrifiad
Allweddeiriau
Carbon Dioxide Activation, Density functional theory, Iron-nickel sulfides, Surface science, Thiospinels
Meysydd Ymchwil
Prosiectau Cysylltiedig
- A co-ordinated, comprehensive approach to carbon capture and utilisation (01.01.2015 - 06.09.2017)
- Bio-inspired sulphide nanocatalysts: From proof of concept to 'real' catalysis (01.01.2015 - 31.10.2017)
- Energy materials: Computational solutions (01.02.2015 - 19.05.2019)