The results achieved so far can be summarized as follows:
- Establishment of a reliable and reproducible synthetic route for covalent organic frameworks.
- Development of a stepwise post-synthetic modification strategy that reinforces the framework stability while introducing pore functionalities in a controlled and tunable manner.
- Quantitative determination of functional group incorporation, including evaluation of the efficiency of each individual reaction step.
- Implementation of an operando spectroelectrochemical platform enabling detection of chemical species formed at the COF electrode interface under applied potential.
These results are expected, in the longer term, to support the development of more durable COF-based catalyst designs for carbon dioxide conversion and to establish clearer correlations between framework structure, local chemical environment, reaction intermediates, and catalytic performance. In this way, the project contributes to shifting the field from empirical trial-and-error screening toward transferable, evidence-based design rules that can be adopted and further developed by other research groups.
To ensure further uptake and maximize impact, several key steps are required: (i) completion and optimization of the targeted vinylene-linked porphyrin COFs; (ii) generation of comprehensive benchmark datasets covering activity, selectivity, stability, and durability; (iii) validation of performance under more practically relevant electrochemical conditions and extended operating times; (iv) improvement of reproducibility at larger synthesis scale; and (v) once a clear enhancement in carbon dioxide affinity and catalytic performance is demonstrated for the functionalized materials, assessment of intellectual property protection in collaboration with the Knowledge and Technology Transfer unit, alongside identification of appropriate pathways for further development, scale-up, and potential demonstration.