The Kinetics of Electron Transfer from CdS Nanorods to the MoFe Protein of Nitrogenase

Authors

Jesse L. Ruzicka, University of Colorado Boulder
Lauren M. Pellows, University of Colorado Boulder
Hayden Kallas, Utah State University
Katherine E. Shulenberger, University of Colorado Boulder
Oleg A. Zadvornyy, Washington State University
Bryant Chica, National Renewable Energy Laboratory
Katherine A. Brown, National Renewable Energy Laboratory
John W. Peters, Washington State University Pullman
Paul W. King, National Renewable Energy Laboratory
Lance C. Seefeldt, Utah State UniversityFollow
Gordana Dukovic, University of Colorado Boulder

Document Type

Article

Journal/Book Title

Journal of Physical Chemistry C

Publication Date

5-9-2022

Publisher

American Chemical Society

Volume

126

First Page

8425

Last Page

8435

Abstract

Combining the remarkable catalytic properties of redox enzymes with highly tunable light absorbing properties of semiconductor nanocrystals enables the light-driven catalysis of complex, multielectron redox reactions. This Article focuses on systems that combine CdS nanorods (NRs) with the MoFe protein of nitrogenase to drive photochemical N2 reduction. We used transient absorption spectroscopy (TAS) to examine the kinetics of electron transfer (ET) from CdS NRs to the MoFe protein. For CdS NRs with dimensions similar to those previously used for photochemical N2 reduction, the rate constant for ET from CdS NRs competes with other electron relaxation processes, such that when a MoFe protein is bound to a NR, about one-half of the photoexcited electrons are delivered to the enzyme. The NR-MoFe protein binding is incomplete with more than one-half of the NRs in solution not having a MoFe protein bound to accept electrons. The quantum efficiency of ET (QEET) in these ensemble samples is similar to previously reported efficiencies of product (NH3 and H2) formation, suggesting that the enzyme utilizes the delivered electrons without major loss pathways. Our analysis suggests that QEET, and therefore the photochemical product formation, is limited at the ensemble level by the NR-MoFe protein binding and at the single-complex level by the competitiveness of ET. We characterized ET kinetics for several CdS NRs samples with varying dimensions and found that for CdS NRs with an average diameter of 4.2 nm the ET efficiency dropped to undetectable levels, defining a maximum NR diameter that should be used to photochemically drive the MoFe protein. The work described here provides insights into the design of systems with increased control of photochemical N2 reduction catalyzed by the MoFe protein of nitrogenase.

Recommended Citation

Ruzicka, J. L., Pellows, L. M., Kallas, H., Shulenberger, K. E., Zadvornyy, O. A., Chica, B., Brown, K. A., Peters, J. W., King, P. W., Seefeldt, L. C., and Dukovic, G. (2022) The Kinetics of Electron Transfer from CdS Nanorods to the MoFe Protein of Nitrogenase. J. Phys. Chem. C126, 8425–8435.