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Molecular insights and future frontiers in cell photosensitization for solar-driven CO2 conversion

Stefano Cestellos-Blanco, Ji Min Kim, Nicholas George Watanabe, Rachel R. Chan, Peidong Yang

2021iScience36 citationsDOIOpen Access PDF

Abstract

fixation selectively and reliably generate products. Nanomaterials harvest solar light and biocompatibly associate with microorganisms owing to similar lengths scales. Although this is a nascent field, a variety of approaches have been implemented encompassing different microorganisms and nanomaterials. To advance the field in an impactful manner, it is paramount to understand the molecular underpinnings of PBSs. In this perspective, we highlight studies inspecting charge uptake pathways and singularities in photosensitized cells. We discuss further analyses to more completely elucidate these constructs, and we focus on criteria to be met for designing photosensitizing nanomaterials. As a result, we advocate for the pairing of microorganisms with naturally occurring and highly biocompatible mineral-based semiconductor nanomaterials.

Topics & Concepts

NanomaterialsNanotechnologyBiocompatible materialBiochemical engineeringMicroorganismMaterials scienceChemistryComputational biologyBiologyEngineeringBiomedical engineeringBacteriaGeneticsAlgal biology and biofuel productionMicrobial Fuel Cells and BioremediationPhotosynthetic Processes and Mechanisms
Molecular insights and future frontiers in cell photosensitization for solar-driven CO2 conversion | Litcius