Surface Chemistry of the Molecular Solar Thermal Energy Storage System 2,3‐Dicyano‐Norbornadiene/Quadricyclane on Ni(111)

Molecular solar thermal (MOST) systems are a promising approach for the introduction of sustainable energy storage solutions. We investigated the feasibility of the dicyano‐substituted norbornadiene/quadricyclane molecule pair on Ni(111) for catalytic model studies. This derivatization is known to l...

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Bibliographic Details
Published in:Chemphyschem 2022-08, Vol.23 (16), p.e202200199-n/a
Main Authors: Hemauer, Felix, Bauer, Udo, Fromm, Lukas, Weiß, Cornelius, Leng, Andreas, Bachmann, Philipp, Düll, Fabian, Steinhauer, Johann, Schwaab, Valentin, Grzonka, Robert, Hirsch, Andreas, Görling, Andreas, Steinrück, Hans‐Peter, Papp, Christian
Format: Article
Language:English
Subjects:
Adsorption
catalysis
Decomposition reactions
Energy storage
Isomerization
Low temperature
MOST system
photoelectron spectroscopy
Solar heating
Surface chemistry
surface reactions
Thermal energy
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Summary:Molecular solar thermal (MOST) systems are a promising approach for the introduction of sustainable energy storage solutions. We investigated the feasibility of the dicyano‐substituted norbornadiene/quadricyclane molecule pair on Ni(111) for catalytic model studies. This derivatization is known to lead to a desired bathochromic shift of the absorption maximum of the parent compound. In our experiments further favorable properties were found: At low temperatures, both molecules adsorb intact without any dissociation. In situ temperature‐programmed HR‐XPS experiments reveal the conversion of (CN)2‐quadricyclane to (CN)2‐norbornadiene under energy release between 175 and 260 K. The absence of other surface species due to side reactions indicates full isomerization. Further heating leads to the decomposition of the molecular framework into smaller carbonaceous fragments above 290 K and finally to amorphous structures, carbide and nitride above 400 K. DFT calculations gave insights into the adsorption geometries. (CN)2‐norbornadiene is expected to interact stronger with the surface, with flat configurations being favorable. (CN)2‐quadricyclane exhibits smaller adsorption energies with negligible differences for flat and side‐on geometries. Simulated XP spectra are in good agreement with experimental findings further supporting the specific spectroscopic fingerprints for both valence isomers. Temperature‐programmed XPS investigations of the molecule pair 2,3‐dicyano‐norbornadiene/quadricyclane confirmed promising properties of this couple as a potential molecular solar thermal (MOST) system for energy storage. Besides the successful observation of a cycloreversion reaction, DFT calculations gave insights into the existence of different adsorption geometries.
ISSN:1439-4235
1439-7641
DOI:10.1002/cphc.202200199