Skip to main content
Journal cover image

Efficiency Limits of Energy Conversion by Light-Driven Redox Chains.

Publication ,  Journal Article
Schultz, JD; Parker, KA; Therien, MJ; Beratan, DN
Published in: Journal of the American Chemical Society
November 2024

The conversion of absorbed sunlight to spatially separated electron-hole pairs is a crucial outcome of natural photosynthesis. Many organisms achieve near-unit quantum yields of charge separation (one electron-hole pair per incident photon) by dissipating as heat more than half of the light energy that is deposited in the primary donor. Might alternative choices have been made by Nature that would sacrifice quantum yield in favor of producing higher energy electron/hole pairs? Here, we use a multisite electron hopping model to address the kinetic and thermodynamic compromises that can be made in electron transfer chains, with the aim of understanding Nature's choices and opportunities in bioinspired energy-converting systems. We find that if the electron-transfer coordinates are even weakly coupled to a high-frequency vibrational mode, substantial energy dissipation is necessary to achieve the maximum possible energy storage in an electron-transfer chain. Since high-frequency vibronic coupling is common in physiological redox cofactors, we posit that biological reaction centers have recruited a strategy to convert light energy into redox potential with the near-optimum energy efficiency that is possible in an electron-transfer chain. Our simulations also find that charge separation in electron-transfer chains is subject to a minimum intercofactor separation distance, beneath which energy-dissipating charge recombination is unavoidable. We find that high quantum yield and low energy dissipation can thus be realized simultaneously for multistep electron transfer if recombination pathways are uncoupled from high-frequency vibrations and if the cofactors are held at small-to-intermediate distances apart (ca. 3 to 8 Å edge-to-edge). Our analysis informs the design of bioinspired light-harvesting structures that may exceed 60% energy efficiency, as opposed to the ∼30% efficiency achieved in natural photosynthesis.

Duke Scholars

Altmetric Attention Stats
Dimensions Citation Stats

Published In

Journal of the American Chemical Society

DOI

EISSN

1520-5126

ISSN

0002-7863

Publication Date

November 2024

Volume

146

Issue

47

Start / End Page

32805 / 32815

Related Subject Headings

  • General Chemistry
  • 40 Engineering
  • 34 Chemical sciences
  • 03 Chemical Sciences
 

Citation

APA
Chicago
ICMJE
MLA
NLM
Schultz, J. D., Parker, K. A., Therien, M. J., & Beratan, D. N. (2024). Efficiency Limits of Energy Conversion by Light-Driven Redox Chains. Journal of the American Chemical Society, 146(47), 32805–32815. https://doi.org/10.1021/jacs.4c13345
Schultz, Jonathan D., Kelsey A. Parker, Michael J. Therien, and David N. Beratan. “Efficiency Limits of Energy Conversion by Light-Driven Redox Chains.Journal of the American Chemical Society 146, no. 47 (November 2024): 32805–15. https://doi.org/10.1021/jacs.4c13345.
Schultz JD, Parker KA, Therien MJ, Beratan DN. Efficiency Limits of Energy Conversion by Light-Driven Redox Chains. Journal of the American Chemical Society. 2024 Nov;146(47):32805–15.
Schultz, Jonathan D., et al. “Efficiency Limits of Energy Conversion by Light-Driven Redox Chains.Journal of the American Chemical Society, vol. 146, no. 47, Nov. 2024, pp. 32805–15. Epmc, doi:10.1021/jacs.4c13345.
Schultz JD, Parker KA, Therien MJ, Beratan DN. Efficiency Limits of Energy Conversion by Light-Driven Redox Chains. Journal of the American Chemical Society. 2024 Nov;146(47):32805–32815.
Journal cover image

Published In

Journal of the American Chemical Society

DOI

EISSN

1520-5126

ISSN

0002-7863

Publication Date

November 2024

Volume

146

Issue

47

Start / End Page

32805 / 32815

Related Subject Headings

  • General Chemistry
  • 40 Engineering
  • 34 Chemical sciences
  • 03 Chemical Sciences