Stephen D. House scite author profile

Electrocatalytic water splitting to produce hydrogen comprises the hydrogen and oxygen evolution half reactions (HER and OER), with the latter as the bottleneck process. Thus, enhancing the OER performance and understanding the mechanism are critically important. Herein, we report a strategy for OER enhancement by utilizing gold nanoclusters to form cluster/CoSe composites; the latter exhibit largely enhanced OER activity in alkaline solutions. The Au/CoSe composite affords a current density of 10 mA cm at small overpotential of ∼0.43 V (cf. CoSe: ∼0.52 V). The ligand and gold cluster size can also tune the catalytic performance of the composites. Based upon XPS analysis and DFT simulations, we attribute the activity enhancement to electronic interactions between nanocluster and CoSe, which favors the formation of the important intermediate (OOH) as well as the desorption of oxygen molecules over Au/CoSe composites in the process of water oxidation. Such an atomic level understanding may provide some guidelines for design of OER catalysts.

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Silver Cluster Formation, Dynamics, and Chemistry in Metal−Organic Frameworks

Houk

et al. 2009

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Synthetic methods used to produce metal nanoparticles typically lead to a distribution of particle sizes. In addition, creation of the smallest clusters, with sizes of a few to tens of atoms, remains very challenging. Nanoporous metal-organic frameworks (MOFs) are a promising solution to these problems, since their long-range crystalline order creates completely uniform pore sizes with the potential for both steric and chemical stabilization. We report a systematic investigation of silver nanocluster formation within MOFs using three representative MOF templates. The as-synthesized clusters are spectroscopically consistent with dimensions < or =1 nm, with a significant fraction existing as Ag(3) clusters, as shown by electron paramagnetic resonance. Importantly, we show conclusively that very rapid TEM-induced MOF degradation leads to agglomeration and stable, easily imaged particles, explaining prior reports of particles larger than MOF pores. These results solve an important riddle concerning MOF-based templates and suggest that heterostructures composed of highly uniform arrays of nanoparticles within MOFs are feasible.

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Influence of Atomic-Level Morphology on Catalysis: The Case of Sphere and Rod-Like Gold Nanoclusters for CO₂ Electroreduction

et al. 2018

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Gold-based materials hold promise in electrocatalytic reduction of CO2 to fuels. However, the polydispersity of conventional gold nanostructures limits mechanistic studies. Here, we report two types of atomically precise Au25 nanoclusters (1 nm) with distinct morphology (i.e., nanosphere and nanorod) for CO2 reduction catalysis. The Au25 nanosphere exhibits higher Faradaic efficiency for CO with higher formation rates compared to the Au25 nanorod. First-principles calculations reveal that the negative charge and the energetically favorable removal of one ligand to generate an active site on the nanosphere can better stabilize the important *COOH intermediate in CO2 electroreduction.

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Monopalladium Substitution in Gold Nanoclusters Enhances CO₂ Electroreduction Activity and Selectivity

et al. 2020

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Atomically precise gold nanoclusters provide opportunities for correlating the structure and electrocatalytic properties at the atomic level. Here, we report the single-atom doping effect on CO2 reduction by comparing monopalladium-doped Pd1Au24 and homogold Au25 nanoclusters (both protected by thiolates) that share an identical core structure. Experimental results show that single Pd-substitution drastically inhibits H2 evolution at large currents; thus, Pd1Au24 can convert CO2 to CO with ∼100% faradaic efficiency ranging from −0.6 (onset) to −1.2 V (vs RHE), while Au25 starts to decline at −0.9 V. Theoretical simulations reveal that the Pd dopant influences the Au nanocluster properties through a unique mechanism different from that in conventional alloy nanoparticles. The surface S atoms of the thiolate ligand are identified as the active sites (with the Au13 core as the electron reservoir) for selective CO2 reduction, whereas undercoordinated Au atom active sites are predicted to favor H2 evolution. Thermodynamic analysis of the ligand removal process predicts that Pd1Au24 should retain a larger population of S atom active sites under cathodic potentials compared with Au25, which extends the potential range for selective CO2 reduction. Our results demonstrate that single-atom substitution can substantially improve the CO2 reduction selectivity of gold nanoclusters at large potentials. The dopant-induced ligand stability may serve as a design strategy to modify the stability of catalytic active sites under harsh conditions.

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Time-dependent, protein-directed growth of gold nanoparticles within a single crystal of lysozyme

et al. 2011

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Gold nanoparticles are useful in biomedical applications due to their distinct optical properties and high chemical stability. Reports of the biogenic formation of gold colloids from gold complexes has also led to an increased level of interest in the biomineralization of gold. However, the mechanism responsible for biomolecule-directed gold nanoparticle formation remains unclear due to the lack of structural information about biological systems and the fast kinetics of biomimetic chemical systems in solution. Here we show that intact single crystals of lysozyme can be used to study the time-dependent, protein-directed growth of gold nanoparticles. The protein crystals slow down the growth of the gold nanoparticles, allowing detailed kinetic studies to be carried out, and permit a three-dimensional structural characterization that would be difficult to achieve in solution. Furthermore, we show that additional chemical species can be used to fine-tune the growth rate of the gold nanoparticles.

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Stephen D. House

Gold Nanoclusters Promote Electrocatalytic Water Oxidation at the Nanocluster/CoSe₂ Interface

Silver Cluster Formation, Dynamics, and Chemistry in Metal−Organic Frameworks

Influence of Atomic-Level Morphology on Catalysis: The Case of Sphere and Rod-Like Gold Nanoclusters for CO₂ Electroreduction

Monopalladium Substitution in Gold Nanoclusters Enhances CO₂ Electroreduction Activity and Selectivity

Time-dependent, protein-directed growth of gold nanoparticles within a single crystal of lysozyme

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Stephen D. House

Gold Nanoclusters Promote Electrocatalytic Water Oxidation at the Nanocluster/CoSe2 Interface

Silver Cluster Formation, Dynamics, and Chemistry in Metal−Organic Frameworks

Influence of Atomic-Level Morphology on Catalysis: The Case of Sphere and Rod-Like Gold Nanoclusters for CO2 Electroreduction

Monopalladium Substitution in Gold Nanoclusters Enhances CO2 Electroreduction Activity and Selectivity

Time-dependent, protein-directed growth of gold nanoparticles within a single crystal of lysozyme

Contact Info

Product

Resources

About

Gold Nanoclusters Promote Electrocatalytic Water Oxidation at the Nanocluster/CoSe₂ Interface

Influence of Atomic-Level Morphology on Catalysis: The Case of Sphere and Rod-Like Gold Nanoclusters for CO₂ Electroreduction

Monopalladium Substitution in Gold Nanoclusters Enhances CO₂ Electroreduction Activity and Selectivity