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Solar-to-Chemical Conversion


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based on dendrimer architectures or assembled on scaffolds. Dendrimers [35, 36] lend themselves to V‐shaped or circular arrangements of covalently bonded chromophores and can exhibit inherent directionality in excitation energy transfer at the molecular level. An important design concept in this area is the linkage of different but complementary chromophores to enable wide spectral coverage and to create energy gradients for efficient excitation energy transfer cascades. An additional requirement for a synthetic antenna complex is the successful interfacing with the synthetic reaction center. The coupling of the two modules should ensure efficient energy transfer from the light‐harvesting system to the charge separation site while avoiding uncontrolled perturbation of the latter by the former.

Examples of synthetic approaches to multi‐chromophore arrays: (a) a nine‐porphyrin array unit comprising a central free‐base porphyrin core that acts as final acceptor and is surrounded by eight energy‐donating zinc porphyrins [43]

      Source: Choi et al. [41]. (b) Dendrimer consisting of a terrylenediimide (TDI) core with four attached perylenemonoimides (PMI) and eight peripheral naphthalenemonoimides (NMI) [44].

      Source: Balzani et al. [34].

Simplified Z‐scheme of natural oxygenic photosynthesis, showing how two photons are used per electron flowing from the terminal donor (H2O) to the terminal acceptor (NADP+) of the light‐dependent reactions Photosystem II from T. vulcanus (PDB ID: 3WU2, a) and major redox‐active components within a PS‐II monomer involved in the main‐pathway electron transfer indicated with red arrows (b)