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Solar-to-Chemical Conversion


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by pigment–protein complexes known as antenna complexes. These are associated with the photosystems, and their role is to collect as much as possible of the available light and funnel the excitation energy to them. The photosynthetic pigments are mostly bacteriochlorophylls, chlorophylls, and carotenoids (carotenes and xanthophylls). Figure 3.3 shows some of the chlorophylls utilized by photosynthetic organisms. They differ in substituents on ring A at positions 2 and 3 and on ring B at position 7 of the chlorin system. Chlorin differs from the porphin tetrapyrrole in having a reduced D ring, while in bacteriochlorins the B ring is also reduced. The principal characteristic of the electronic structure of chlorophyll‐type pigments is the conjugated π orbital system that is delocalized over the aromatic rings. Differences in substituents such as those shown in Figure 3.3 create slight variations in electronic structure that contribute to distinct optical properties by affecting the nature and energies of π–π* excitations, the lowest of which falls within the red or near‐infrared (NIR) region. Thus, among the four types of chlorophyll shown in Figure 3.3, with respect to the most common chlorophyll a (Chl a) that has an absorption maximum (λmax) at ca. 662 nm in vitro, Chl b is blueshifted (λmax = 644 nm) and Chl d is redshifted (λmax = 697 nm) [4]. Chl f was discovered only recently [21] and is the most redshifted chlorophyll known in oxygenic photosynthesis (λmax = 707 nm). It has been suggested that its presence in key positions within PS‐I and PS‐II enables charge separation to occur with far‐red light [22].

Selected types of chlorophyll molecules encountered in natural photosynthesis (a) Side and top view of the light‐harvesting complex LH2 from the purple bacterium R. acidophila 10050 (PDB: 1KZU [24]), showing bacteriochlorophyll a pigments in green and carotenoids (rhodopin glucoside) in orange. (b) Rod structure of c‐phycocyanin from the phycobilisome light‐harvesting antenna of cyanobacterium T. vulcanus (PDB: 3O18 [25]). (c) Light‐harvesting complex II (LHCII) from pea (PDB: 2BHW [26]), showing Chl a pigments in dark green and Chl b in light green

      Considering biomimetic approaches to artificial versions of antenna complexes, certain challenges become immediately apparent. The pigments used in biological light harvesting are rather small molecules that are elaborately positioned and electronically fine‐tuned by a “smart” protein matrix, resorting only to limited extent to covalent bonding. In this respect, it is tempting to consider the possible role of template‐guided assembly of pigments as opposed to the conventional synthetic approach of covalently linking arrays of chromophores. It is remarkable that even when using several molecules of the same pigment, the protein matrix can modulate their absorption profile to produce a range of site energies with well‐defined spatial distribution. This is important for expanding the spectral range and light‐harvesting ability of the antenna beyond the intrinsic features of a given pigment, but its directed nature makes it also the basis of a crucial functionality: the creation of energy gradients within the antennae that enable efficient transfer of excitation energy to the reaction centers. It is likely that similar functionality could be built synthetically by utilizing ordering of distinct chromophores rather than manipulating the properties of a given pigment in a site‐dependent manner. The high effective concentration of chromophores achieved in antenna complexes also appears hard to achieve in artificial analogs while avoiding concentration quenching (self‐absorption) and seems to be possible in nature only because of the pigment organization imposed by the protein scaffold. Finally, the adaptability to changing light conditions, for example, by rerouting excitation energy transfer pathways, and the intrinsic photoprotection mechanisms of photosynthetic enzymes and antenna complexes are features that would be difficult, though not impossible [32], to replicate outside biology.