Abstract

The development of technology for the inexpensive generation of the renewable energy vector H2 through water splitting is of immediate economic, ecological, and humanitarian interest. Recent interest in hydrogenases has been fueled by their exceptionally high catalytic rates for H2 production at a marginal overpotential, which is presently only matched by the nonscalable noble metal platinum. The mechanistic understanding of hydrogenase function guides the design of synthetic catalysts, and selection of a suitable hydrogenase enables direct applications in electro- and photocatalysis. [FeFe]-hydrogenases display excellent H2 evolution activity, but they are irreversibly damaged upon exposure to O2, which currently prevents their use in full water splitting systems. O2-tolerant [NiFe]-hydrogenases are known, but they are typically strongly biased toward H2 oxidation, while H2 production by [NiFe]-hydrogenases is often product (H2) inhibited. [NiFeSe]-hydrogenases are a subclass of [NiFe]-hydrogenases with a selenocysteine residue coordinated to the active site nickel center in place of a cysteine. They exhibit a combination of unique properties that are highly advantageous for applications in water splitting compared with other hydrogenases. They display a high H2 evolution rate with marginal inhibition by H2 and tolerance to O2. [NiFeSe]-hydrogenases are therefore one of the most active molecular H2 evolution catalysts applicable in water splitting. Herein, we summarize our recent progress in exploring the unique chemistry of [NiFeSe]-hydrogenases through biomimetic model chemistry and the chemistry with [NiFeSe]-hydrogenases in semiartificial photosynthetic systems. We gain perspective from the structural, spectroscopic, and electrochemical properties of the [NiFeSe]-hydrogenases and compare them with the chemistry of synthetic models of this hydrogenase active site. Our synthetic models give insight into the effects on the electronic properties and reactivity of the active site upon the introduction of selenium. We have utilized the exceptional properties of the [NiFeSe]-hydrogenase from Desulfomicrobium baculatum in a number of photocatalytic H2 production schemes, which are benchmark systems in terms of single site activity, tolerance toward O2, and in vitro water splitting with biological molecules. Each system comprises a light-harvesting component, which allows for light-driven electron transfer to the hydrogenase in order for it to catalyze H2 production. A system with [NiFeSe]-hydrogenase on a dye-sensitized TiO2 nanoparticle gives an enzyme-semiconductor hybrid for visible light-driven generation of H2 with an enzyme-based turnover frequency of 50 s(-1). A stable and inexpensive polymeric carbon nitride as a photosensitizer in combination with the [NiFeSe]-hydrogenase shows good activity for more than 2 days. Light-driven H2 evolution with the enzyme and an organic dye under high O2 levels demonstrates the excellent robustness and feasibility of water splitting with a hydrogenase-based scheme. This has led, most recently, to the development of a light-driven full water splitting system with a [NiFeSe]-hydrogenase wired to the water oxidation enzyme photosystem II in a photoelectrochemical cell. In contrast to the other systems, this photoelectrochemical system does not rely on a sacrificial electron donor and allowed us to establish the long sought after light-driven water splitting with an isolated hydrogenase.

Highlights

  • Enormous effort is currently invested in the establishment of natural and artificial photosynthetic systems for efficient, sunlight-driven water splitting into the renewable fuel H2 and byproduct O2

  • We explore the unique chemistry of [NiFeSe]-hydrogenases through biomimetic chemistry to gain insight into the role of selenium in the active site, and exploit the excellent activity of the enzyme for solar fuel synthesis in semiartificial photosynthetic systems

  • Three main active site structures were solved with various selenium oxidation states and different ligands at nickel: Ox4B, Ox4C, and Ox0.26 in the Desulfovibrio vulgaris Hildenborough [NiFeSe]-hydrogenase, which was both purified and crystallized aerobically, the active site exists in three states with partial occupancy

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Summary

INTRODUCTION

Enormous effort is currently invested in the establishment of natural and artificial photosynthetic systems for efficient, sunlight-driven water splitting into the renewable fuel H2 and byproduct O2. Hydrogenases serve as a benchmark, and as a blueprint to inspire the design of synthetic 3d transition metal catalysts In this Account, we summarize our work on [NiFeSe]hydrogenase; a selenium-containing subclass of the [NiFe]hydrogenase. The [NiFeSe]-hydrogenase displays fast reactivation from O2 inactivation at a low redox potential indicative of O2 tolerance.[8,14] This effect is demonstrated, where reactivation of the enzyme was observed at cathodic potentials following injection of an O2 saturated electrolyte solution and purging of the headspace with H2.8 The O2 sensitivity of Desulfomicrobium baculatum [NiFeSe]-hydrogenase during H2 oxidation at positive potentials prevents its use in enzyme fuel cells and other applications, and we focus only on its unique H2 evolution activity.[2,8]. The activity of the [NiFeSe]-hydrogenase for H2 production was reported to be 40 times higher than the corresponding [NiFe]-hydrogenase.[7]

Chemical Basis for High Activity
Fast Reactivation from Oxidative Damage and O2-Tolerance
SYNTHETIC ACTIVE SITE MODELS
PHOTOCATALYTIC H2 PRODUCTION SYSTEMS
CONCLUSIONS
■ ACKNOWLEDGMENTS
Findings
■ REFERENCES

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