Photocurrent Generation in Artificial Light-Harvesting Protein Matrices

Agam, Yuval; Amdursky, Nadav

doi:10.1021/acs.jpcc.3c02717

J. Phys. Chem. C

2023

DOI: 10.1021/acs.jpcc.3c02717

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Photocurrent Generation in Artificial Light-Harvesting Protein Matrices

Yuval Agam,

Nadav Amdursky

Abstract: Light-harvesting is at the heart of photocurrent generation devices, and it is also one of the most important natural phenomena of which photosynthesis is an example. Inspired by natural light-harvesting complexes, we present here a synthetic and artificial solid-state protein-based matrix that is molecularly doped with natural light-harvesting chlorophyll molecules. Such protein matrices are capable of photocurrent generation over a wide range of wavelengths in a source−drain configuration. We show that the p… Show more

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2024

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Cited by 2 publications

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Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting

Travaglini,

Lam,

Sawicki

et al. 2024

Small

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Electronically conductive protein‐based materials can enable the creation of bioelectronic components and devices from sustainable and nontoxic materials, while also being well‐suited to interface with biological systems, such as living cells, for biosensor applications. However, as proteins are generally electrical insulators, the ability to render protein assemblies electroactive in a tailorable manner can usher in a plethora of useful materials. Here, an approach to fabricate electronically conductive protein nanowires is presented by aligning heme molecules in proximity along protein filaments, with these nanowires also possessing charge transfer abilities that enable energy harvesting from ambient humidity. The heme‐incorporated protein nanowires demonstrate electron transfer over micrometer distances, with conductive atomic force microscopy showing individual nanowires having comparable conductance to other previously characterized heme‐based bacterial nanowires. Exposure of multilayer nanowire films to humidity produces an electrical current, presumably through water molecules ionizing carboxyl groups in the filament and creating an unbalanced total charge distribution that is enhanced by the heme. Incorporation of heme and potentially other metal‐center porphyrin molecules into protein nanostructures could pave the way for structurally‐ and electrically‐defined protein‐based bioelectronic devices.

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Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting

Travaglini,

Lam,

Sawicki

et al. 2024

Small

View full text Add to dashboard Cite

show abstract

Long range electron transfer and proton transfer in biology: What do we know and how does it work?

Amdursky

2024

Current Opinion in Electrochemistry

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Photocurrent Generation in Artificial Light-Harvesting Protein Matrices

Cited by 2 publications

References 49 publications

Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting

Fabrication of Electronically Conductive Protein‐Heme Nanowires for Power Harvesting

Long range electron transfer and proton transfer in biology: What do we know and how does it work?

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