Your search keyword '"Thomas F. Jaramillo"' showing total 180 results

1. Acid anion electrolyte effects on platinum for oxygen and hydrogen electrocatalysis

Author

Gaurav Ashish Kamat, José A. Zamora Zeledón, G. T. Kasun Kalhara Gunasooriya, Samuel M. Dull, Joseph T. Perryman, Jens K. Nørskov, Michaela Burke Stevens, and Thomas F. Jaramillo

Subjects

Chemistry, QD1-999

Abstract

Microenvironment engineering through electrolyte optimization is a promising approach to mitigate catalyst poisoning effects in electrochemical systems, but the role of electrolyte anions is not fully understood. Here, in a combined experimental-theoretical evaluation, the authors study the effects of different acidic electrolytes (pH 1) on platinum for hydrogen (HER/HOR) and oxygen electrocatalysis (ORR/OER), finding that oxygen reduction performance can be improved 4-fold using nitric rather than sulfuric acid.

Published

2022

2. Readily Constructed Glass Piston Pump for Gas Recirculation

Author

Adam C. Nielander, Sarah J. Blair, Joshua M. McEnaney, Jay A. Schwalbe, Tom Adams, Sawson Taheri, Lei Wang, Sungeun Yang, Matteo Cargnello, and Thomas F. Jaramillo

Subjects

Chemistry, QD1-999

Published

2020

3. Chemical Modifications of Ag Catalyst Surfaces with Imidazolium Ionomers Modulate H2 Evolution Rates during Electrochemical CO2 Reduction

Author

Siwei Liang, Sarah E. Baker, Sneha A. Akhade, Christopher Hahn, Thomas F. Jaramillo, Eric B. Duoss, Stephen E. Weitzner, Zhenan Bao, Kabir Abiose, David M. Koshy, Joel B. Varley, Adam Shugar, James S. Oakdale, and Jingwei Shi

Subjects

Steric effects, chemistry.chemical_classification, Chemistry, General Chemistry, Polymer, Electrochemistry, Ring (chemistry), Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Chemical engineering, Density functional theory, Selectivity, Ionomer

Abstract

Bridging polymer design with catalyst surface science is a promising direction for tuning and optimizing electrochemical reactors that could impact long-term goals in energy and sustainability. Particularly, the interaction between inorganic catalyst surfaces and organic-based ionomers provides an avenue to both steer reaction selectivity and promote activity. Here, we studied the role of imidazolium-based ionomers for electrocatalytic CO2 reduction to CO (CO2R) on Ag surfaces and found that they produce no effect on CO2R activity yet strongly promote the competing hydrogen evolution reaction (HER). By examining the dependence of HER and CO2R rates on concentrations of CO2 and HCO3-, we developed a kinetic model that attributes HER promotion to intrinsic promotion of HCO3- reduction by imidazolium ionomers. We also show that varying the ionomer structure by changing substituents on the imidazolium ring modulates the HER promotion. This ionomer-structure dependence was analyzed via Taft steric parameters and density functional theory calculations, which suggest that steric bulk from functionalities on the imidazolium ring reduces access of the ionomer to both HCO3- and the Ag surface, thus limiting the promotional effect. Our results help develop design rules for ionomer-catalyst interactions in CO2R and motivate further work into precisely uncovering the interplay between primary and secondary coordination in determining electrocatalytic behavior.

Published

2021

4. Guiding the Catalytic Properties of Copper for Electrochemical CO2 Reduction by Metal Atom Decoration

Author

Christopher Hahn, Thomas F. Jaramillo, Carlos G. Morales-Guio, Hong-Jie Peng, Michal Bajdich, Stephanie A. Nitopi, Yusaku F. Nishimura, Lei Wang, and Frank Abild-Pedersen

Subjects

Materials science, Electrochemistry, Catalysis, Metal, chemistry.chemical_compound, chemistry, Chemical engineering, visual_art, Physical vapor deposition, visual_art.visual_art_medium, General Materials Science, Formate, Selectivity, Bimetallic strip, Oxygenate

Abstract

Tuning bimetallic effects is a promising strategy to guide catalytic properties. However, the nature of these effects can be difficult to assess and compare due to the convolution with other factors such as the catalyst surface structure and morphology and differences in testing environments. Here, we investigate the impact of atomic-scale bimetallic effects on the electrochemical CO2 reduction performance of Cu-based catalysts by leveraging a systematic approach that unifies protocols for materials synthesis and testing and enables accurate comparisons of intrinsic catalytic activity and selectivity. We used the same physical vapor deposition method to epitaxially grow Cu(100) films decorated with a small amount of noble or base metal atoms and a combination of experimental characterization and first-principles calculations to evaluate their physicochemical and catalytic properties. The results indicate that the metal atoms segregate to under-coordinated Cu sites during physical vapor deposition, suppressing CO reduction to oxygenates and hydrocarbons and promoting competing pathways to CO, formate, and hydrogen. Leveraging these insights, we rationalize bimetallic design principles to improve catalytic selectivity for CO2 reduction to CO, formate, oxygenates, or hydrocarbons. Our study provides one of the most extensive studies on Cu bimetallics for CO2 reduction, establishing a systematic approach that is broadly applicable to research in catalyst discovery.

Published

2021

5. Electrolyte-Guided Design of Electroreductive CO Coupling on Copper Surfaces

Author

Sarah Lamaison, Thomas F. Jaramillo, Sarah E. Baker, Christopher Hahn, Stephen E. Weitzner, Sneha A. Akhade, Hannah V. Eshelman, Julie Hamilton, Jeremy T. Feaster, David W. Wakerley, Joel B. Varley, Buddhinie S. Jayathilake, Lei Wang, Dong Un Lee, and Eric B. Duoss

Subjects

Coupling (electronics), Materials science, chemistry, Chemical physics, Materials Chemistry, Electrochemistry, Energy Engineering and Power Technology, Chemical Engineering (miscellaneous), chemistry.chemical_element, Electrolyte, Electrical and Electronic Engineering, Copper

Published

2021

6. Dynamics and Hysteresis of Hydrogen Intercalation and Deintercalation in Palladium Electrodes: A Multimodal In Situ X-ray Diffraction, Coulometry, and Computational Study

Author

Thomas F. Jaramillo, David M. Koshy, Ryan C. Davis, Soo Hong Lee, Junko Yano, Frank Abild-Pedersen, Apurva Mehta, Walter S. Drisdell, Christopher Hahn, Drew Higgins, A. L. Landers, Jeremy T. Feaster, Michal Bajdich, Hong-Jie Peng, John C. Lin, and Jeffrey W. Beeman

Subjects

In situ, Materials science, Hydrogen, General Chemical Engineering, Intercalation (chemistry), chemistry.chemical_element, General Chemistry, Coulometry, Hysteresis, chemistry, Electrode, X-ray crystallography, Materials Chemistry, Physical chemistry, Palladium

Published

2021

7. Phosphate-passivated mordenite for tandem-catalytic conversion of syngas to ethanol or acetic acid

Author

Marat Orazov, Thomas F. Jaramillo, and D. Chester Upham

Subjects

010405 organic chemistry, 010402 general chemistry, 01 natural sciences, Catalysis, Mordenite, 0104 chemical sciences, law.invention, Acetic acid, chemistry.chemical_compound, chemistry, law, Calcination, Methanol, Physical and Theoretical Chemistry, Carbonylation, Oxygenate, Syngas, Nuclear chemistry

Abstract

Selective and stable production of C2 oxygenates from syngas is enabled by a phosphate-passivated mordenite catalyst used in tandem with a commercial Cu/ZnO/AlMgOx catalyst. Unmodified mordenite used in this arrangement is accompanied by substantial hydrocarbon formation and carbon deposition. Therefore, phosphate groups are used to remove or significantly reduce Bronsted acidity in mordenite by capping aluminum sites. Such groups are stable to calcination and catalyst regeneration. Trimethylphosphite is used as a phosphate precursor because it is able to enter the 12 membered-ring pores of mordenite where hydrocarbon formation occurs, but not enter the 8 membered-ring side-pockets, where methanol carbonylation occurs selectively. The catalyst was characterized using X-ray fluorescence, X-ray diffraction, and thermal gravimetric analysis. Optionally, a third bed of Cu/ZnO/AlMgO x catalyst is able to hydrodeoxygenate acetic acid to ethanol. The C2 oxygenate selectivity is over 96% and among the best reported in a single reactor with a syngas feed.

Published

2021

8. Bridging Thermal Catalysis and Electrocatalysis: Catalyzing CO 2 Conversion with Carbon‐Based Materials

Author

Drew Higgins, David A. Cullen, Zhenan Bao, Samuel M. Dull, Sindhu S. Nathan, Arun S. Asundi, David M. Koshy, Thomas F. Jaramillo, Ahmed M. Abdellah, and Stacey F. Bent

Subjects

biology, Chemistry, Kinetics, Active site, chemistry.chemical_element, General Chemistry, Electrocatalyst, Electrochemistry, Catalysis, Water-gas shift reaction, Characterization (materials science), Chemical engineering, biology.protein, Carbon

Abstract

Understanding the differences between reactions driven by elevated temperature or electric potential remains challenging, largely due to materials incompatibilities between thermal catalytic and electrocatalytic environments. We show that Ni, N-doped carbon (NiPACN), an electrocatalyst for the reduction of CO2 to CO (CO2 R), can also selectively catalyze thermal CO2 to CO via the reverse water gas shift (RWGS) representing a direct analogy between catalytic phenomena across the two reaction environments. Advanced characterization techniques reveal that NiPACN likely facilitates RWGS on dispersed Ni sites in agreement with CO2 R active site studies. Finally, we construct a generalized reaction driving-force that includes temperature and potential and suggest that NiPACN could facilitate faster kinetics in CO2 R relative to RWGS due to lower intrinsic barriers. This report motivates further studies that quantitatively link catalytic phenomena across disparate reaction environments.

Published

2021

9. Tungsten oxide-coated copper gallium selenide sustains long-term solar hydrogen evolution

Author

Nicolas Gaillard, Imran Khan, David W. Palm, Thomas F. Jaramillo, Christopher P. Muzzillo, and Micha Ben-Naim

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Gallium selenide, Energy Engineering and Power Technology, chemistry.chemical_element, Solar hydrogen, Tungsten oxide, engineering.material, Copper, Durability, Catalysis, Fuel Technology, chemistry, Coating, Chemical engineering, engineering, Layer (electronics)

Abstract

This work demonstrates that ultrathin (4 nm) tungsten oxide (WO3) coatings on copper gallium selenide (CuGa3Se5) photocathodes have the potential for long-term solar hydrogen evolution. With a combination of a robust 1.84 eV CuGa3Se5 absorber layer, a WO3 protective coating, and a Pt catalyst, we obtain a new durability milestone for any non-silicon photoelectrochemical hydrogen-producing device by passing 21 490 C cm−2 of charge across six weeks of continuously-illuminated chronoamperometric testing under applied bias.

Published

2021

10. Oxidation State and Surface Reconstruction of Cu under CO2 Reduction Conditions from In Situ X-ray Characterization

Author

Maryam Farmand, Christopher Hahn, A. L. Landers, Walter S. Drisdell, Jeremy T. Feaster, Jeffrey W. Beeman, Apurva Mehta, Jaime E. Aviles Acosta, Soo Hong Lee, John C. Lin, Ryan C. Davis, Thomas F. Jaramillo, Junko Yano, and Yifan Ye

Subjects

Absorption spectroscopy, Chemistry, General Chemistry, 010402 general chemistry, Electrocatalyst, Electrochemistry, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Metal, Colloid and Surface Chemistry, Chemical engineering, Oxidation state, visual_art, visual_art.visual_art_medium, Crystallite, Surface reconstruction

Abstract

The electrochemical CO2 reduction reaction (CO2RR) using Cu-based catalysts holds great potential for producing valuable multi-carbon products from renewable energy. However, the chemical and structural state of Cu catalyst surfaces during the CO2RR remains a matter of debate. Here, we show the structural evolution of the near-surface region of polycrystalline Cu electrodes under in situ conditions through a combination of grazing incidence X-ray absorption spectroscopy (GIXAS) and X-ray diffraction (GIXRD). The in situ GIXAS reveals that the surface oxide layer is fully reduced to metallic Cu before the onset potential for CO2RR, and the catalyst maintains the metallic state across the potentials relevant to the CO2RR. We also find a preferential surface reconstruction of the polycrystalline Cu surface toward (100) facets in the presence of CO2. Quantitative analysis of the reconstruction profiles reveals that the degree of reconstruction increases with increasingly negative applied potentials, and it persists when the applied potential returns to more positive values. These findings show that the surface of Cu electrocatalysts is dynamic during the CO2RR, and emphasize the importance of in situ characterization to understand the surface structure and its role in electrocatalysis.

Published

2020

11. Identifying and Tuning the In Situ Oxygen-Rich Surface of Molybdenum Nitride Electrocatalysts for Oxygen Reduction

Author

Brenna M. Gibbons, Ryan C. Davis, Anjli M. Patel, Apurva Mehta, Melissa E. Kreider, Thomas F. Jaramillo, Michaela Burke Stevens, Yunzhi Liu, Robert Sinclair, Jens K. Nørskov, Michael J. Statt, Anton V. Ievlev, Laurie A. King, Zhenbin Wang, and Alessandro Gallo

Subjects

In situ, Materials science, Inorganic chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, Nitride, Electrocatalyst, Oxygen reduction, Catalysis, chemistry, Molybdenum, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Oxygen reduction reaction, Oxygen rich, Electrical and Electronic Engineering

Abstract

Rigorous in situ studies of electrocatalysts are required to enable the design of higher performing materials. Nonplatinum group metals for oxygen reduction reaction (ORR) catalysis containing ligh...

Published

2020

12. Addressing the Stability Gap in Photoelectrochemistry: Molybdenum Disulfide Protective Catalysts for Tandem III–V Unassisted Solar Water Splitting

Author

Todd G. Deutsch, Thomas F. Jaramillo, Chase Aldridge, Laurie A. King, Adam C. Nielander, Reuben J. Britto, Myles A. Steiner, Rachel Mow, James L. Young, Micha Ben-Naim, and Daniel J. Friedman

Subjects

Materials science, Tandem, Renewable Energy, Sustainability and the Environment, business.industry, Photoelectrochemistry, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Durability, 0104 chemical sciences, Corrosion, Catalysis, chemistry.chemical_compound, Fuel Technology, Semiconductor, chemistry, Chemical engineering, Chemistry (miscellaneous), Materials Chemistry, Water splitting, 0210 nano-technology, business, Molybdenum disulfide

Abstract

While photoelectrochemical (PEC) solar-to-hydrogen efficiencies have greatly improved over the past few decades, advances in PEC durability have lagged behind. Corrosion of semiconductor photoabsorbers in the aqueous conditions needed for water splitting is a major challenge that limits device stability. In addition, a precious-metal catalyst is often required to efficiently promote water splitting. Herein, we demonstrate unassisted water splitting using a nonprecious metal molybdenum disulfide nanomaterial catalytic protection layer paired with a GaInAsP/GaAs tandem device. This device was able to achieve stable unassisted water splitting for nearly 12 h, while a sibling sample with a PtRu catalyst was only stable for 2 h, highlighting the advantage of the nonprecious metal catalyst. In situ optical imaging illustrates the progression of macroscopic degradation that causes device failure. In addition, this work compares unassisted water splitting devices across the field in terms of the efficiency and stability, illustrating the need for improved stability.

Published

2020

13. Readily Constructed Glass Piston Pump for Gas Recirculation

Author

Thomas F. Jaramillo, Lei Wang, Joshua M. McEnaney, Adam C. Nielander, Sungeun Yang, Tom Adams, Sarah J. Blair, Sawson Taheri, Matteo Cargnello, and Jay A. Schwalbe

Subjects

chemistry.chemical_classification, Inert, Piston pump, Materials science, Atmospheric pressure, General Chemical Engineering, General Chemistry, Polymer, Electrolyte, Article, Volumetric flow rate, chemistry.chemical_compound, Chemistry, chemistry, Chemical engineering, Peek, Tetrafluoroethylene, QD1-999

Abstract

The recirculation of gases in a sealed reactor system is a broadly useful method in catalytic and electrocatalytic studies. It is especially relevant when a reactant gas reacts slowly with respect to residence time in a catalytic reaction zone and when mass transport control through the reaction zone is necessary. This need is well illustrated in the field of electrocatalytic N2 reduction, where the need for recirculation of 15N2 has recently become more apparent. Herein, we describe the design, fabrication, use, and specifications of a lubricant-free, readily constructed recirculating pump fabricated entirely from glass and inert polymer (poly(ether ether ketone) (PEEK), poly(tetrafluoroethylene) (PTFE)) components. Using these glass and polymer components ensures chemical compatibility between the piston pump and a wide range of chemical environments, including strongly acidic and organic electrolytes often employed in studies of electrocatalytic N2 reduction. The lubricant-free nature of the pump and the presence of components made exclusively of glass and PEEK/PTFE mitigate contamination concerns associated with recirculating gases saturated with corrosive or reactive vapors for extended periods. The gas recirculating glass pump achieved a flow rate of >500 mL min-1 N2 against atmospheric pressure at 15 W peak power input and >100 mL min-1 N2 against a differential pressure of +6 in. H2O (∼15 mbar) at 10 W peak power input.

Published

2020

14. In Situ X-Ray Absorption Spectroscopy Disentangles the Roles of Copper and Silver in a Bimetallic Catalyst for the Oxygen Reduction Reaction

Author

Thomas F. Jaramillo, Melissa E. Kreider, Michaela Burke Stevens, Ryan C. Davis, Samira Siahrostami, Apurva Mehta, Drew Higgins, Brenna M. Gibbons, Melissa Wette, and Bruce M. Clemens

Subjects

In situ, X-ray absorption spectroscopy, Materials science, business.industry, General Chemical Engineering, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Copper, 0104 chemical sciences, Renewable energy, Catalysis, chemistry, Chemical engineering, Materials Chemistry, Oxygen reduction reaction, Fuel cells, 0210 nano-technology, business, Bimetallic strip

Abstract

Silver-based bimetallic catalysts for the oxygen reduction reaction (ORR) are promising for a wide variety of renewable energy technologies, including alkaline fuel cells and metal-air batteries. T...

Published

2020

15. Electrolyte Engineering for Efficient Electrochemical Nitrate Reduction to Ammonia on a Titanium Electrode

Author

Matteo Cargnello, Thomas F. Jaramillo, Sarah J. Blair, Adam C. Nielander, David M. Koshy, Joshua M. McEnaney, and Jay A. Schwalbe

Subjects

Pollutant, Waste management, Renewable Energy, Sustainability and the Environment, General Chemical Engineering, Groundwater remediation, 02 engineering and technology, General Chemistry, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, Industrial waste, 0104 chemical sciences, chemistry.chemical_compound, Ammonia, Nitrate, chemistry, Hazardous waste, Environmental Chemistry, Environmental science, 0210 nano-technology

Abstract

Nitrates from agricultural runoff and industrial waste streams are a notorious waste product and hazardous pollutant. Traditional electrochemical water remediation approaches aim to solve this prob...

Published

2020

16. Understanding the Origin of Highly Selective CO 2 Electroreduction to CO on Ni,N‐doped Carbon Catalysts

Author

Allessandro Gallo, Dennis Nordlund, Drew Higgins, Michaela Burke Stevens, Zhenan Bao, Christopher Hahn, David M. Koshy, Ahmed M. Abdellah, Thomas F. Jaramillo, Gan Chen, Samuel M. Dull, Dong Un Lee, and Shucheng Chen

Subjects

X-ray absorption spectroscopy, biology, 010405 organic chemistry, Inorganic chemistry, Active site, chemistry.chemical_element, General Chemistry, 010402 general chemistry, Electrocatalyst, Heterogeneous catalysis, Electrochemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry, biology.protein, Carbon, Pyrolysis

Abstract

Ni,N-doped carbon catalysts have shown promising catalytic performance for CO2 electroreduction (CO2 R) to CO; this activity has often been attributed to the presence of nitrogen-coordinated, single Ni atom active sites. However, experimentally confirming Ni-N bonding and correlating CO2 reduction (CO2 R) activity to these species has remained a fundamental challenge. We synthesized polyacrylonitrile-derived Ni,N-doped carbon electrocatalysts (Ni-PACN) with a range of pyrolysis temperatures and Ni loadings and correlated their electrochemical activity with extensive physiochemical characterization to rigorously address the origin of activity in these materials. We found that the CO2 R to CO partial current density increased with increased Ni content before plateauing at 2 wt % which suggests a dispersed Ni active site. These dispersed active sites were investigated by hard and soft X-ray spectroscopy, which revealed that pyrrolic nitrogen ligands selectively bind Ni atoms in a distorted square-planar geometry that strongly resembles the active sites of molecular metal-porphyrin catalysts.

Published

2020

17. A Spin Coating Method To Deposit Iridium-Based Catalysts onto Silicon for Water Oxidation Photoanodes

Author

Micha Ben-Naim, Drew Higgins, Alaina L. Strickler, Adam C. Nielander, Joel Sanchez, David W. Palm, Thomas F. Jaramillo, and Laurie A. King

Subjects

Photocurrent, Spin coating, Materials science, chemistry, Chemical engineering, Silicon, Oxygen evolution, Water splitting, chemistry.chemical_element, Reversible hydrogen electrode, General Materials Science, Iridium, Catalysis

Abstract

Silicon has shown promise for use as a small band gap (1.1 eV) absorber material in photoelectrochemical (PEC) water splitting. However, the limited stability of silicon in acidic electrolyte requires the use of protection strategies coupled with catalysts. Herein, spin coating is used as a versatile method to directly coat silicon photoanodes with an IrOₓ oxygen evolution reaction (OER) catalyst, reducing the processing complexity compared to conventional fabrication schemes. Biphasic strontium chloride/iridium oxide (SrCl₂:IrOₓ) catalysts are also developed, and both catalysts form photoactive junctions with silicon and demonstrate highphotoanode activity. The iridium oxide photoanode displays a photocurrent onset at 1.06 V vs reversible hydrogen electrode (RHE), while the SrCl₂:IrOₓ photoanode onsets earlier at 0.96 V vs RHE. The differing potentials are consistent with the observed photovoltages of 0.43 and 0.53 V for the IrOₓ and SrCl₂:IrOₓ, respectively. By measuring the oxidation of a reversible redox couple, Fe(CN)₆ ³¯⁄⁴¯, we compare the charge carrier extraction of the devices and show that the addition of SrCl₂ to the IrOx catalyst improves the silicon−electrolyte interface compared to pure IrOₓ. However, the durability of the strontium-containing photoanode remains a challenge, with its photocurrent density decreasing by 90% over 4 h. The IrOₓ photoanode, on the other hand, maintained a stable photocurrent density over this timescale. Characterization of the as-prepared and post-tested material structure via Auger electron spectroscopy identifies catalyst film cracking and delamination as the primary failure modes. We propose that improvements to catalyst adhesion should further the viability of spin coating as a technique for photoanode preparation.

Published

2020

18. Morphology control of metal-modified zirconium phosphate support structures for the oxygen evolution reaction

Author

Daniel E. Del Toro-Pedrosa, Mario V. Ramos-Garcés, Joel Sanchez, Thomas F. Jaramillo, Kálery La Luz-Rivera, and Jorge L. Colón

Subjects

Materials science, Oxygen evolution, chemistry.chemical_element, Electrochemistry, Catalysis, Inorganic Chemistry, Metal, Nickel, chemistry.chemical_compound, Chemical engineering, Transition metal, chemistry, Zirconium phosphate, visual_art, visual_art.visual_art_medium, Cobalt

Abstract

The electrochemical oxygen evolution reaction (OER) is the half-cell reaction for many clean-energy production technologies, including water electrolyzers and metal-air batteries. However, its sluggish kinetics hinders the performance of those technologies, impeding them from broader implementation. Recently, we reported the use of zirconium phosphate (ZrP) as a support for transition metal catalysts for the oxygen evolution reaction (OER). These catalysts achieve promising overpotentials with high mass activities. Herein, we synthesize ZrP structures with controlled morphology: hexagonal platelets, rods, cubes, and spheres, and subsequently modify them with Co(ii) and Ni(ii) cations to assess their electrochemcial OER behavior. Through inductively coupled plasma mass-spectrometry measurements, the maximum ion exchange capacity is found to vary based on the morphology of the ZrP structure and cation selection. Trends in geometric current density and mass activity as a function of cation selection are discussed. We find that the loading and coverage of cobalt and nickel species on the ZrP supports are key factors that control OER performance.

Published

2020

19. Using pH dependence to understand mechanisms in electrochemical CO reduction

Author

Christopher Hahn, Hendrik H. Heenen, Karen Chan, Lei Wang, Georg Kastlunger, Thomas F. Jaramillo, Stefan Ringe, and Nitish Govindarajan

Subjects

Reaction rate, Reaction mechanism, chemistry.chemical_compound, Tafel equation, chemistry, Inorganic chemistry, Protonation, Electrolyte, Electrochemistry, Rate-determining step, Methane

Abstract

Utilizing electrochemical conversion of CO(2) into hydrocarbons and oxygenates is envisioned as a promising path towards closing the carbon cycle in modern technology. To this day, however, the exact reaction mechanisms towards the plethora of single and multi-carbon products on Cu electrodes are still disputed. This uncertainty even extends to the rate-limiting step of the respective reactions. Since multi-carbon products do not show a dependence on the electrolyte pH in neutral and alkaline media, CO dimerization on the Cu surface has been proposed as the rate-limiting step. However, other elementary steps would lead to the same pH dependence, namely the proton-electron transfer to *CO followed by subsequent coupling or the protonation of the *OCCO dimer. The pH dependence of methane production on the other hand suggests that the rate limiting step is located beyond the first proton-electron transfer to *CO. In order to conclusively identify the rate limiting steps in CO reduction, we analyzed the mechanisms on the basis of constant potential DFT calculations, CO reduction experiments on Cu at varying pH values (3 - 13) and fundamental rate theory. We find that, even in acidic media, the reaction rate towards multi-carbon products is nearly unchanged on an SHE potential scale, which indicates that its rate limiting step does not involve a proton donor. Hence, we deduce that the rate limiting step can indeed only consist of the coupling of two CO molecules on the surface, both in acidic and alkaline conditions. For methane, on the other hand, the rate-limiting step changes with the electrolyte pH from the first protonation step in acidic/neutral conditions to a later step in alkaline conditions. Finally, based on an in-depth kinetic analysis, we conclude that the pathway towards CH4 involving a surface combination of *CO and *H is unlikely, since it is unable to reproduce the measured current densities and Tafel slopes.

Published

2021

20. First-row Transition Metal Antimonates for the Oxygen Reduction Reaction

Author

Yunzhi Liu, Zhenbin Wang, G. T. Kasun Kalhara Gunasooriya, Eduardo Valle, Jens K. Nørskov, An-Chih Yang, Melissa E. Kreider, Michaela Burke Stevens, José A. Zamora Zeledón, Thomas F. Jaramillo, Alessandro Gallo, and Robert Sinclair

Subjects

Aqueous solution, Materials science, Inorganic chemistry, General Engineering, Oxide, General Physics and Astronomy, Pourbaix diagram, Catalysis, Metal, chemistry.chemical_compound, chemistry, Transition metal, visual_art, visual_art.visual_art_medium, General Materials Science, Antimonate, Oxygen binding

Abstract

The development of inexpensive and abundant catalysts with high activity, selectivity, and stability for the oxygen reduction reaction (ORR) is imperative for the widespread implementation of fuel cell devices. Herein, we present a combined theoretical-experimental approach to discover and design first-row transition metal antimonates as promising electrocatalytic materials for the ORR. Theoretically, we identify first-row transition metal antimonates – MSb2O6, where M = Mn, Fe, Co, and Ni – as non-precious metal catalysts with promising oxygen binding energetics, conductivity, thermodynamic phase stability and aqueous stability. Among the considered antimonates, MnSb2O6 shows the highest theoretical ORR activity based on the 4e− ORR kinetic volcano. Experimentally, nanoparticulate transition metal antimonate catalysts are found to have a minimum of a 2.5-fold enhancement in intrinsic mass activity (on transition metal mass basis) relative to the corresponding transition metal oxide at 0.7 V vs RHE in 0.1 M KOH. MnSb2O6 is the most active catalyst under these conditions, with a 3.5-fold enhancement on a per Mn mass activity basis and 25-fold enhancement on a surface area basis over its antimony-free counterpart. Electrocatalytic and material stability are demonstrated over a 5 h chronopotentiometry experiment in the stability window identified by Pourbaix analysis. This study further highlights the stable and electrically conductive antimonate structure as a promising framework to tune the activity and selectivity of non-precious metal oxide active sites for ORR catalysis.

Published

2021

21. Using Microenvironments to Control Reactivity in CO2 Electrocatalysis

Author

Thomas F. Jaramillo and Christopher Hahn

Subjects

Imagination, General Energy, Chemistry, media_common.quotation_subject, Reactivity (chemistry), Nanotechnology, Raw material, Electrocatalyst, media_common

Abstract

Climate change has necessitated the development of technologies that are able to efficiently capture, utilize, and store CO2, creating new opportunities to utilize CO2 as a feedstock to produce fuels and chemicals that are vital to our society. In Nature, Sargent, Peters, Agapie, et al. control microenvironments around Cu electrocatalysts to achieve an impressive selectivity of 72% for CO2 conversion to ethylene, stimulating our imagination of what industrial CO2 electrolyzers may look like in the near future.

Published

2020

22. A non-precious metal hydrogen catalyst in a commercial polymer electrolyte membrane electrolyser

Author

McKenzie A. Hubert, Nemanja Danilovic, Thomas R. Hellstern, Laurie A. King, Katherine E. Ayers, Thomas F. Jaramillo, Judith Manco, Christopher Capuano, and Eduardo Valle

Subjects

Materials science, Hydrogen, Biomedical Engineering, chemistry.chemical_element, Bioengineering, 02 engineering and technology, Electrolyte, 010402 general chemistry, 01 natural sciences, Catalysis, Affordable and Clean Energy, General Materials Science, Nanoscience & Nanotechnology, Electrical and Electronic Engineering, Hydrogen production, chemistry.chemical_classification, Polymer, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Membrane, chemistry, Chemical engineering, 0210 nano-technology, Platinum, Carbon

Abstract

We demonstrate the translation of a low-cost, non-precious metal cobalt phosphide (CoP) catalyst from 1 cm2 lab-scale experiments to a commercial-scale 86 cm2 polymer electrolyte membrane (PEM) electrolyser. A two-step bulk synthesis was adopted to produce CoP on a high-surface-area carbon support that was readily integrated into an industrial PEM electrolyser fabrication process. The performance of the CoP was compared head to head with a platinum-based PEM under the same operating conditions (400 psi, 50 °C). CoP was found to be active and stable, operating at 1.86 A cm-2 for >1,700 h of continuous hydrogen production while providing substantial material cost savings relative to platinum. This work illustrates a potential pathway for non-precious hydrogen evolution catalysts developed in past decades to translate to commercial applications.

Published

2019

23. Crystalline Strontium Iridate Particle Catalysts for Enhanced Oxygen Evolution in Acid

Author

Thomas F. Jaramillo, Drew Higgins, and Alaina L. Strickler

Subjects

Materials science, Mixed metal, Oxide, Oxygen evolution, Energy Engineering and Power Technology, chemistry.chemical_element, Electrocatalyst, Photochemistry, chemistry.chemical_compound, chemistry, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Water splitting, Iridium, Electrical and Electronic Engineering

Abstract

Iridium-based mixed metal oxide phases have been shown as promising electrocatalysts for the oxygen evolution reaction (OER) because of their ability to stabilize unique Ir-based surface sites with...

Published

2019

24. Transition Metal-Modified Exfoliated Zirconium Phosphate as an Electrocatalyst for the Oxygen Evolution Reaction

Author

Eduardo Valle, Thomas F. Jaramillo, Jorge L. Colón, Isabel Barraza Alvarez, Yanyu Wu, Mario V. Ramos-Garcés, Dino Villagrán, Daniel E. Del Toro-Pedrosa, and Joel Sanchez

Subjects

Materials science, Tetrabutylammonium hydroxide, Oxygen evolution, Energy Engineering and Power Technology, Nanoparticle, Overpotential, Electrocatalyst, Exfoliation joint, Catalysis, chemistry.chemical_compound, Chemical engineering, chemistry, Zirconium phosphate, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Electrical and Electronic Engineering

Abstract

Improved electrochemical oxygen evolution catalysis is crucial for many clean-energy production technologies. Recently, transition-metal-modified zirconium phosphate (ZrP) catalysts were studied for the oxygen evolution reaction (OER) in alkaline media. These studies suggest that the OER occurs preferentially on the surface of the layered ZrP nanoparticles rather than the interlayer gallery. Herein, ZrP nanoparticles are exfoliated with tetrabutylammonium hydroxide (TBA+OH–) to further expose surface sites which are subsequently modified with Co and Ni cations by an ion-exchange reaction. Because of the greater surface accessibility of the exfoliated ZrP support, higher loadings of catalyst material were achieved along with improved site access for catalysis. These new composite materials have improved geometric area normalized overpotentials than metal-adsorbed ZrP nanoparticles without exfoliation. Specifically, Co-modified and Ni-modified exfoliated ZrP show a reduction in overpotential at a current de...

Published

2019

25. Robust and biocompatible catalysts for efficient hydrogen-driven microbial electrosynthesis

Author

Christopher Hahn, Alfred M. Spormann, Karen Maegaard, Andrew B. Wong, Frauke Kracke, Joerg S. Deutzmann, Thomas F. Jaramillo, and McKenzie A. Hubert

Subjects

Single product, Hydrogen, High selectivity, Microbial electrosynthesis, chemistry.chemical_element, General Chemistry, Biocompatible material, Biochemistry, Catalysis, Reaction rate, lcsh:Chemistry, chemistry, Chemical engineering, lcsh:QD1-999, Biocatalysis, Materials Chemistry, Environmental Chemistry

Abstract

CO2 reduction by combined electro- and bio-catalytic reactions is a promising technology platform for sustainable production of chemicals from CO2 and electricity. While heterogeneous electrocatalysts can reduce CO2 to a variety of organic compounds at relatively high reaction rates, these catalysts have limitations achieving high selectivity for any single product beyond CO. Conversely, microbial CO2 reduction pathways proceed at high selectivity; however, the rates at bio-cathodes using direct electron supply via electricity are commonly limiting. Here we demonstrate the use of non-precious metal cathodes that produce hydrogen in situ to support microbial CO2 reduction to C1 and C2 compounds. CoP, MoS2 and NiMo cathodes perform durable hydrogen evolution under biologically relevant conditions, and the integrated system achieves coulombic efficiencies close to 100% without accumulating hydrogen. Moreover, the one-reactor hybrid platform is successfully used for efficient acetate production from electricity and CO2 by microbes previously reported to be inactive in bioelectrochemical systems. The reduction of CO2 by electro- and biocatalysis offers a promising route to the sustainable production of chemicals and fuels. Here, the integration of methanogenic or homoacetogenic microbes with earth-abundant electrodes allows robust, rapid, and selective CO2 reduction with coulombic efficiencies of up to 100%.

Published

2019

26. Revealing the Synergy between Oxide and Alloy Phases on the Performance of Bimetallic In–Pd Catalysts for CO2 Hydrogenation to Methanol

Author

Jonathan L. Snider, Frank Abild-Pedersen, Julia Schumann, Thomas F. Jaramillo, Melis S. Duyar, D. Chester Upham, McKenzie A. Hubert, Alessandro Gallo, Tej S. Choksi, Eduardo Valle, and Verena Streibel

Subjects

Materials science, 010405 organic chemistry, Alloy, Intermetallic, Oxide, General Chemistry, engineering.material, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Chemical engineering, chemistry, engineering, Methanol, Bimetallic strip

Abstract

In2O3 has recently emerged as a promising catalyst for methanol synthesis from CO2. In this work, we present the promotional effect of Pd on this catalyst and investigate structure–performance rela...

Published

2019

27. Molybdenum Disulfide Catalytic Coatings via Atomic Layer Deposition for Solar Hydrogen Production from Copper Gallium Diselenide Photocathodes

Author

Wanli Yang, Lothar Weinhardt, Thomas R. Hellstern, James Carter, David W. Palm, Thomas F. Jaramillo, Monika Blum, Kimberly Horsley, Clemens Heske, A. Deangelis, and Nicolas Gaillard

Subjects

Photocurrent, Materials science, Inorganic chemistry, Energy Engineering and Power Technology, Cadmium sulfide, Photocathode, Overlayer, chemistry.chemical_compound, Atomic layer deposition, chemistry, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Electrical and Electronic Engineering, Thin film, Layer (electronics), Molybdenum disulfide

Abstract

We demonstrate that applying atomic layer deposition-derived molybdenum disulfide (MoS2) catalytic coatings on copper gallium diselenide (CGSe) thin film absorbers can lead to efficient wide band gap photocathodes for photoelectrochemical hydrogen production. We have prepared a device that is free of precious metals, employing a CGSe absorber and a cadmium sulfide (CdS) buffer layer, a titanium dioxide (TiO2) interfacial layer, and a MoS2 catalytic layer. The resulting MoS2/TiO2/CdS/CGSe photocathode exhibits a photocurrent onset of +0.53 V vs RHE and a saturation photocurrent density of −10 mA cm–2, with stable operation for >5 h in acidic electrolyte. Spectroscopic investigations of this device architecture indicate that overlayer degradation occurs inhomogeneously, ultimately exposing the underlying CGSe absorber.

Published

2019

28. Nanostructuring Strategies To Increase the Photoelectrochemical Water Splitting Activity of Silicon Photocathodes

Author

Stacey F. Bent, Thomas R. Hellstern, Christopher Hahn, Adam C. Nielander, Callisto MacIsaac, Thomas F. Jaramillo, Pongkarn Chakthranont, Fritz B. Prinz, Joshua J. Willis, Shicheng Xu, and Laurie A. King

Subjects

Materials science, Silicon, business.industry, Open-circuit voltage, chemistry.chemical_element, Nanotechnology, Electrocatalyst, Photocathode, chemistry.chemical_compound, Semiconductor, chemistry, Electrode, Water splitting, General Materials Science, business, Molybdenum disulfide

Abstract

Photoelectrochemical water splitting is a promising route for sustainable hydrogen production. Herein, we demonstrate a photoelectrode motif that enables a nanostructured large-surface area electrocatalyst without requiring a nanostructured semiconductor surface with the goal of promoting electrocatalysis while minimizing surface recombination. We compare the photoelectrochemical H2 evolution activity of two silicon photocathode nanostructuring strategies: (1) direct nanostructuring of the silicon surface and (2) incorporation of nanostructured zinc oxide to increase the electrocatalyst surface area on planar silicon. We observed that silicon photocathodes that utilized nanostructured ZnO supports outperformed nanostructured silicon electrodes by ∼50 mV at open circuit under 1 sun illumination and demonstrated comparable electrocatalytic activity.

Published

2019

29. Interfacial engineering of gallium indium phosphide photoelectrodes for hydrogen evolution with precious metal and non-precious metal based catalysts

Author

Reuben J. Britto, Myles A. Steiner, David T. LaFehr, Ye Yang, Todd G. Deutsch, Mathew C. Beard, James L. Young, Thomas F. Jaramillo, and Daniel J. Friedman

Subjects

Photocurrent, Materials science, Hydrogen, Renewable Energy, Sustainability and the Environment, business.industry, Band gap, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Catalysis, chemistry.chemical_compound, Semiconductor, chemistry, Indium phosphide, Optoelectronics, General Materials Science, Gallium, 0210 nano-technology, business, Molybdenum disulfide

Abstract

Gallium indium phosphide (GaInP2) is a semiconductor with promising optical and electronic properties to serve as the large bandgap, top junction in a dual absorber tandem solar water splitting device. Poor intrinsic catalytic ability and surface corrosion in aqueous electrolyte remain key obstacles. Significant progress has been made developing thin-film protection layers and active catalysts for photoelectrochemical devices, but combining these into a catalytic protection layer that can provide long-term stability without sacrificing performance has proven difficult due, in large part, to challenges in developing active and stable interfaces. In this work, we demonstrate that a nanoscale molybdenum disulfide (MoS2) film functions both as an effective protection layer and excellent hydrogen evolution catalyst for GaInP2 photocathodes, with only a ∼10% loss in initial light-limited current density after 100 h, and a photocurrent onset potential better than that of the same state-of-the-art device with a platinum–ruthenium catalyst. Using transient photoreflectance spectroscopy, we probed the carrier dynamics of these photocathodes and show that the MoS2 coated device exhibits improved electron transfer at the surface interface compared to the PtRu catalyzed device. These MoS2 protected devices are among the most active and stable single-absorber photocathodes for solar water splitting to date and offer a promising pathway towards generating hydrogen with high efficiency and significant longevity.

Published

2019

30. Isolating the Electrocatalytic Activity of a Confined NiFe Motif within Zirconium Phosphate

Author

Michaela Burke Stevens, Micha Ben-Naim, Thomas F. Jaramillo, Laurie A. King, Alessandro Gallo, Jorge L. Colón, Meng Zhao, Yunzhi Liu, Joel Sanchez, Alexandra R. Young, Robert Sinclair, Mario V. Ramos-Garcés, and Michal Bajdich

Subjects

Materials science, biology, Renewable Energy, Sustainability and the Environment, Intercalation (chemistry), Oxygen evolution, Active site, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Chemical engineering, Zirconium phosphate, chemistry, Transition metal, biology.protein, Molecule, General Materials Science, 0210 nano-technology

Abstract

Unique classes of active-site motifs are needed for improved electrocatalysis. Herein, the activity of a new catalyst motif is engineered and isolated for the oxygen evolution reaction (OER) created by nickel–iron transition metal electrocatalysts confined within a layered zirconium phosphate matrix. It is found that with optimal intercalation, confined NiFe catalysts have an order of magnitude improved mass activity compared to more conventional surface-adsorbed systems in 0.1 m KOH. Interestingly, the confined environments within the layered structure also stabilize Fe-rich compositions (90%) with exceptional mass activity compared to known Fe-rich OER catalysts. Through controls and by grafting inert molecules to the outer surface, it is evidenced that the intercalated Ni/Fe species stay within the interlayer during catalysis and serve as the active site. After determining a possible structure (wycherproofite), density functional theory is shown to correlate with the observed experimental compositional trends. It is further demonstrated that the improved activity of this motif is correlated to the Fe and water content/composition within the confined space. This work highlights the catalytic enhancement possibilities available through zirconium phosphate and isolates the activity from the intercalated species versus surface/edge ones, thus opening new avenues to develop and understand catalysts within unique nanoscale chemical environments.

Published

2021

31. Understanding Selectivity in CO2 Hydrogenation to Methanol for MoP Nanoparticle Catalysts Using In Situ Techniques

Author

Joseph A. Singh, Alessandro Gallo, Samuel K. Regli, Magnus Rønning, Joshua M. McEnaney, Eduardo Valle, Jonathan L. Snider, Stacey F. Bent, Thomas F. Jaramillo, and Melis S. Duyar

Subjects

methanol synthesis, MoP, Diffuse reflectance infrared fourier transform, Absorption spectroscopy, Phosphide, 010402 general chemistry, Photochemistry, lcsh:Chemical technology, 01 natural sciences, Catalysis, lcsh:Chemistry, chemistry.chemical_compound, support effects, Formate, lcsh:TP1-1185, Physical and Theoretical Chemistry, in situ characterization, X-ray absorption spectroscopy, 010405 organic chemistry, 0104 chemical sciences, chemistry, lcsh:QD1-999, Methanol, Selectivity, CO2 hydrogenation

Abstract

Molybdenum phosphide (MoP) catalyzes the hydrogenation of CO, CO2 , and their mixtures to methanol, and it is investigated as a high-activity catalyst that overcomes deactivation issues (e.g., formate poisoning) faced by conventional transition metal catalysts. MoP as a new catalyst for hydrogenating CO2 to methanol is particularly appealing for the use of CO2 as chemical feedstock. Herein, we use a colloidal synthesis technique that connects the presence of MoP to the formation of methanol from CO2 , regardless of the support being used. By conducting a systematic support study, we see that zirconia (ZrO2 ) has the striking ability to shift the selectivity towards methanol by increasing the rate of methanol conversion by two orders of magnitude compared to other supports, at a CO2 conversion of 1.4% and methanol selectivity of 55.4%. In situ X-ray Absorption Spectroscopy (XAS) and in situ X-ray Diffraction (XRD) indicate that under reaction conditions the catalyst is pure MoP in a partially crystalline phase. Results from Diffuse Reflectance Infrared Fourier Transform Spectroscopy coupled with Temperature Programmed Surface Reaction (DRIFTSTPSR) point towards a highly reactive monodentate formate intermediate stabilized by the strong interaction of MoP and ZrO2 . This study definitively shows that the presence of a MoP phase leads to methanol formation from CO2 , regardless of support and that the formate intermediate on MoP governs methanol formation rate. : © 2021 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https:// creativecommons.org/licenses/by/ 4.0/).

Published

2021

32. Direct Integration of Strained-Pt Catalysts into Proton-Exchange-Membrane Fuel Cells with Atomic Layer Deposition

Author

Marat Orazov, Drew Higgins, Thomas F. Jaramillo, Juan S. Lezama Pacheco, Sam Dull, Shicheng Xu, Thomas D. Schladt, Peter Schindler, Jonathan E. Mueller, Jan Torgersen, Zhaoxuan Wang, Venkatasubramanian Viswanathan, Per Erik Vullum, Fritz B. Prinz, Dong Un Lee, Gerold Huebner, Olga Vinogradova, Sebastian Kirsch, Qizhan Tam, Anup L. Dadlani, and Yunzhi Liu

Subjects

Materials science, Mechanical Engineering, Membrane electrode assembly, chemistry.chemical_element, Proton exchange membrane fuel cell, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, Atomic layer deposition, chemistry, Chemical engineering, Mechanics of Materials, Hydrogen fuel, General Materials Science, 0210 nano-technology, Platinum, Carbon

Abstract

The design and fabrication of lattice-strained platinum catalysts achieved by removing a soluble core from a platinum shell synthesized via atomic layer deposition, is reported. The remarkable catalytic performance for the oxygen reduction reaction (ORR), measured in both half-cell and full-cell configurations, is attributed to the observed lattice strain. By further optimizing the nanoparticle geometry and ionomer/carbon interactions, mass activity close to 0.8 A mgPt-1 @0.9 V iR-free is achievable in the membrane electrode assembly. Nevertheless, active catalysts with high ORR activity do not necessarily lead to high performance in the high-current-density (HCD) region. More attention shall be directed toward HCD performance for enabling high-power-density hydrogen fuel cells.

Published

2021

33. Acidic Oxygen Evolution Reaction Activity–Stability Relationships in Ru-Based Pyrochlores

Author

Dimosthenis Sokaras, McKenzie A. Hubert, Robert Sinclair, Yunzhi Liu, Eduardo Valle, Anjli M. Patel, Joel Sanchez, Laurie A. King, Jens K. Nørskov, Alessandro Gallo, Thomas F. Jaramillo, Micha Ben-Naim, and Michal Bajdich

Subjects

Electrolysis of water, 010405 organic chemistry, Chemistry, Oxygen evolution, chemistry.chemical_element, General Chemistry, Theoretical Pourbaix stability, Activity descriptors, 010402 general chemistry, 01 natural sciences, Ruthenium, Catalysis, 0104 chemical sciences, Chemical engineering, Pyrochlore, Water splitting, Degradation (geology), SDG 7 - Affordable and Clean Energy, Dissolution

Abstract

Ru-based oxygen evolution reaction (OER) catalysts show significant promise for efficient water electrolysis, but rapid degradation poses a major challenge for commercial applications. In this work, we explore several Ru-based pyrochlores (A2Ru2O7, A = Y, Nd, Gd, Bi) as OER catalysts and demonstrate improved activity and stability of catalytic Ru sites relative to RuO2. Furthermore, we combine complementary experimental and theoretical analysis to understand how the A-site element impacts activity and stability under acidic OER conditions. Among the A2Ru2O7 studied herein, we find that a longer Ru-O bond and a weaker interaction of the Ru 4d and O 2p orbitals compared with RuO2 results in enhanced initial activity. We observe that the OER activity of the catalysts changes over time and is accompanied by both A-site and Ru dissolution at different relative rates depending on the identity of the A-site. Pourbaix diagrams constructed using density functional theory (DFT) calculations reveal a driving force for this experimentally observed dissolution, indicating that all compositions studied herein are thermodynamically unstable in acidic OER conditions. Theoretical activity predictions show consistent trends between A-site cation leaching and OER activity. These trends coupled with Bader charge analysis suggest that dissolution exposes highly oxidized Ru sites that exhibit enhanced activity. Overall, using the stability number (molO2 evolved/molRu dissolved) as a comparative metric, the A2Ru2O7 materials studied in this work show substantially greater stability than a standard RuO2 and commensurate stability to some Ir mixed metal oxides. The insights described herein provide a pathway to enhanced Ru catalyst activity and durability, ultimately improving the efficiency of water electrolyzers.

Published

2020

34. Selective reduction of CO to acetaldehyde with CuAg electrocatalysts

Author

Yongfei Ji, Carlos G. Morales-Guio, Karen Chan, Drew Higgins, Thomas F. Jaramillo, Lei Wang, and Christopher Hahn

Subjects

Multidisciplinary, Ethanol, Arthur M. Sackler Colloquium on the Status and Challenges in Decarbonizing our Energy Landscape, Acetaldehyde, CO reduction, Electrocatalyst, Combinatorial chemistry, Catalysis, chemistry.chemical_compound, heterogeneous catalysis, chemistry, Affordable and Clean Energy, CO2 reduction, Reversible hydrogen electrode, electrocatalysis, Selective reduction, Selectivity, bimetallics, Electrode potential

Abstract

Electrochemical CO reduction can serve as a sequential step in the transformation of CO 2 into multicarbon fuels and chemicals. In this study, we provide insights on how to steer selectivity for CO reduction almost exclusively toward a single multicarbon oxygenate by carefully controlling the catalyst composition and its surrounding reaction conditions. Under alkaline reaction conditions, we demonstrate that planar CuAg electrodes can reduce CO to acetaldehyde with over 50% Faradaic efficiency and over 90% selectivity on a carbon basis at a modest electrode potential of −0.536 V vs. the reversible hydrogen electrode. The Faradaic efficiency to acetaldehyde was further enhanced to 70% by increasing the roughness factor of the CuAg electrode. Density functional theory calculations indicate that Ag ad-atoms on Cu weaken the binding energy of the reduced acetaldehyde intermediate and inhibit its further reduction to ethanol, demonstrating that the improved selectivity to acetaldehyde is due to the electronic effect from Ag incorporation. These findings will aid in the design of catalysts that are able to guide complex reaction networks and achieve high selectivity for the desired product.

Published

2020

35. A cyclic electrochemical strategy to produce acetylene from CO2, CH4, or alternative carbon sources

Author

Brian A. Rohr, Thomas F. Jaramillo, Laurie A. King, Jens K. Nørskov, Adam C. Nielander, Joshua M. McEnaney, and Aayush R. Singh

Subjects

Solid-state chemistry, Aqueous solution, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, chemistry.chemical_element, Electrochemistry, Redox, chemistry.chemical_compound, Fuel Technology, Acetylene, chemistry, Chemical engineering, Selectivity, Carbon, Stoichiometry

Abstract

Electrochemical transformation of potent greenhouse gases such as CO2 and CH4 to produce useful carbon-based products is a highly desirable sustainability goal. However, selectivity challenges remain in aqueous electrochemical processes as selective CO2 reduction to desired products is difficult and electrochemical CH4 oxidation often proceeds at very low rates. The formation of C-C coupled products in these fields is particularly desirable as this provides a path for the production of high-value fuels and chemicals. We have developed a cyclic electrochemical strategy which can produce acetylene, a C-C coupled product, from such carbon sources and water, with favorable current density and selectivity. This strategy is exemplified with a lithium-mediated cycle: an active Li0 surface is electrochemically generated from LiOH, the newly formed Li0 reacts with a carbon source to form Li2C2, and Li2C2 is hydrolyzed to form acetylene and regenerate LiOH. We demonstrate this process primarily using CO2 gas, achieving a current efficiency of 15% to acetylene (which represents 82% of the maximum based on stoichiometric production of oxygenated byproducts, e.g.LiCO3 and/or Li2O), as verified by gas chromatography and Fourier transform infrared radiation studies. We also explore CH4, CO, and C as alternative precursors in the acetylene synthesis. Notably, the use of graphitic carbon at higher temperatures resulted in over 55% current efficiency to acetylene, with opportunity for further optimization. Importantly, this cycling method avoids the formation of common side products observed during aqueous electrochemical CO2 and CH4 redox reactions, such as H2, CO, HCO2−, or CO2. Theoretical considerations elucidate the feasibility and general applicability of this cycle and the process steps have been characterized with specific electrochemical and materials chemistry techniques. The continued development of this strategy may lead to a viable route for the sustainable production of C-C coupled carbon fuels and chemicals.

Published

2020

36. A Combined Theory‐Experiment Analysis of the Surface Species in Lithium‐Mediated NH3 Electrosynthesis

Author

Cullen Chosy, Adam C. Nielander, Michael J. Statt, Matteo Cargnello, Jon G. Baker, Aayush R. Singh, Brian A. Rohr, Jens K. Nørskov, Suzanne Zamany Andersen, Thomas F. Jaramillo, Jay A. Schwalbe, and Joshua M. McEnaney

Subjects

Materials science, chemistry, Inorganic chemistry, Electrochemistry, chemistry.chemical_element, Lithium, SDG 7 - Affordable and Clean Energy, Electrosynthesis, SDG 2 - Zero Hunger, Catalysis

Abstract

Electrochemical processes for ammonia synthesis could potentially replace the high temperature and pressure conditions of the Haber‐Bosch process, with voltage offering a pathway to distributed fertilizer production that leverages the rapidly decreasing cost of renewable electricity. However, nitrogen is an unreactive molecule and the hydrogen evolution reaction presents a major selectivity challenge. An electrode of electrodeposited lithium in tetrahydrofuran solvent overcomes both problems by providing a surface that easily reacts with nitrogen and by limiting the access of protons with a nonaqueous electrolyte. Under these conditions, we measure relatively high faradaic efficiencies (ca. 10 %) and rates (0.1 mA cm−2) toward NH3. We observe the development of a solid electrolyte interface layer as well as the accumulation of lithium and lithium‐containing species. Detailed DFT studies suggest lithium nitride and hydride to be catalytically active phases given their thermodynamic and kinetic stability relative to metallic lithium under reaction conditions and the fast diffusion of nitrogen in lithium.

Published

2020

37. Nitride or Oxynitride? Elucidating the Composition-Activity Relationships in Molybdenum Nitride Electrocatalysts for the Oxygen Reduction Reaction

Author

Ryan C. Davis, Jens K. Nørskov, Alessandro Gallo, Anjli M. Patel, Thomas F. Jaramillo, Melissa E. Kreider, Michael J. Statt, Micha Ben-Naim, Apurva Mehta, Michaela Burke Stevens, Brenna M. Gibbons, Anton V. Ievlev, Robert Sinclair, Yunhzi Liu, and Laurie A. King

Subjects

inorganic chemicals, General Chemical Engineering, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, Nitride, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Oxygen, 0104 chemical sciences, Catalysis, chemistry, Molybdenum, Materials Chemistry, Oxygen reduction reaction, Composition (visual arts), 0210 nano-technology

Abstract

Molybdenum nitride (Mo-N) catalysts have shown promising activity and stability for the oxygen reduction reaction (ORR) in acid. However, the effect of oxygen (O) incorporation (from synthesis, catalysis, or exposure to air) on their activity remains elusive. Here, we use reactive sputtering to synthesize three compositions of thin-film catalysts and use extensive materials characterization to investigate the depth-dependent structure and incorporated O. We show that the as-deposited Mo-N films are highly oxidized both at the surface (>30% O) and in the bulk (3-21% O) and that the ORR performance is strongly correlated with the bulk structure and composition. Activity for 4e- ORR is highest for compositions with the highest N/O and N/Mo ratio. Furthermore, H2O2 production for the films with moderate O content is comparable to or higher than the most H2O2-selective nonprecious metal catalysts in acidic electrolyte, on a moles per mass or surface area of catalyst basis. Density functional theory provides insight into the energetics of O incorporation and vacancy formation, and we hypothesize that activity trends with O/N ratios can be traced to the varying crystallite phases and their interactions with ORR adsorbates. This work demonstrates the prevalence and significance of O in metal nitride electrocatalysts and motivates further investigation into the role of O in other nonprecious metal materials.

Published

2020

38. Improving intrinsic oxygen reduction activity and stability: Atomic layer deposition preparation of platinum-titanium alloy catalysts

Author

Thomas F. Jaramillo, Dong Un Lee, Anup L. Dadlani, Zhaoxuan Wang, Drew Higgins, Dilip Krishnamurthy, Peter Schindler, Ryan C. Davis, Sam Dull, Shicheng Xu, Joonsuk Park, Tanja Graf, Fritz B. Prinz, Venkatasubramanian Viswanathan, Marat Orazov, Olga Vinogradova, Jonathan E. Mueller, Thomas D. Schladt, Ritimukta Sarangi, Yongmin Kim, and Hyun Soo Han

Subjects

Materials science, Annealing (metallurgy), Process Chemistry and Technology, Titanium alloy, Nanoparticle, chemistry.chemical_element, Electrochemistry, Catalysis, Atomic layer deposition, Chemical engineering, chemistry, Crystallite, Platinum, General Environmental Science

Abstract

Improved activity and stability Pt-based catalysts for the oxygen reduction reaction (ORR) are needed to perpetuate the deployment of polymer electrolyte fuel cells (PEFCs) in the transportation sector. Here, we use atomic layer deposition of TiO2 and Pt coupled with thermal reductive annealing to prepare Pt3Ti electrocatalysts. The atomic level synthetic control resulted in Pt3Ti nanoparticles with high ORR performance, including a mass activity of 1.84 A/mgPt and excellent electrochemical stability. The Pt3Ti nanoparticles show excellent specific activity — 5.3-fold higher than commercial Pt/C and 3-fold higher than polycrystalline Pt, exceeding the performance of any PtTi catalysts reported to date. Combined experimental and computational efforts indicate that Pt enrichment on the Pt3Ti enhances the activity, and the intrinsic stability of the Pt3Ti phase provides durability. This knowledge, along with the facile fabrication of alloys by atomic layer deposition, can be leveraged to designed improved performance catalysts.

Published

2022

39. A Highly Active Molybdenum Phosphide Catalyst for Methanol Synthesis from CO and CO 2

Author

Charlie Tsai, Thomas F. Jaramillo, Stacey F. Bent, Frank Abild-Pedersen, Jakob Kibsgaard, Jong Suk Yoo, Alessandro Gallo, Jens K. Nørskov, Jonathan L. Snider, Andrew J. Medford, Joseph A. Singh, Melis S. Duyar, and Felix Studt

Subjects

010405 organic chemistry, Phosphide, Inorganic chemistry, chemistry.chemical_element, General Chemistry, Raw material, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Synthetic fuel, Molybdenum, Formate, Methanol, Syngas

Abstract

Methanol is a major fuel and chemical feedstock currently produced from syngas, a CO/CO2/H2 mixture. Herein we identify formate binding strength as a key parameter limiting the activity and stability of known catalysts for methanol synthesis in the presence of CO2. We present a molybdenum phosphide catalyst for CO and CO2 reduction to methanol, which through a weaker interaction with formate, can improve the activity and stability of methanol synthesis catalysts in a wide range of CO/CO2/H2 feeds.

Published

2018

40. Improved CO2 reduction activity towards C2+ alcohols on a tandem gold on copper electrocatalyst

Author

Ariel Jackson, Kendra P. Kuhl, Jeremy T. Feaster, Natalie C. Johnson, Thomas F. Jaramillo, David N. Abram, Stephanie A. Nitopi, Carlos G. Morales-Guio, Toru Hatsukade, Lei Wang, Etosha R. Cave, and Christopher Hahn

Subjects

Chemistry, Process Chemistry and Technology, Inorganic chemistry, chemistry.chemical_element, Bioengineering, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, Electrocatalyst, 01 natural sciences, Biochemistry, Copper, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloidal gold, Methanol, 0210 nano-technology, Selectivity, Bimetallic strip

Abstract

The discovery of materials for the electrochemical transformation of carbon dioxide into liquid fuels has the potential to impact large-scale storage of renewable energies and reduce carbon emissions. Here, we report the discovery of an electrocatalyst composed of gold nanoparticles on a polycrystalline copper foil (Au/Cu) that is highly active for CO2 reduction to alcohols. At low overpotentials, the Au/Cu electrocatalyst is over 100 times more selective for the formation of products containing C–C bonds versus methane or methanol, largely favouring the generation of alcohols over hydrocarbons. A combination of electrochemical testing and transport modelling supports the hypothesis that CO2 reduction on gold generates a high CO concentration on nearby copper, where CO is further reduced to alcohols such as ethanol and n-propanol under locally alkaline conditions. The bimetallic Au/Cu electrocatalyst exhibits synergistic activity and selectivity superior to gold, copper or AuCu alloys, and opens new possibilities for the development of CO2 reduction electrodes exploiting tandem catalysis mechanisms. The electrochemical transformation of CO2 into liquid fuels is a major challenge. Now, Jaramillo, Hahn and co-workers present a Au/Cu catalyst highly active to C2+ alcohols at low overpotentials as a result of a tandem mechanism where CO2 is reduced to CO on Au and further reduced to C2+ alcohols on nearby Cu.

Published

2018

41. Electrochemical Carbon Monoxide Reduction on Polycrystalline Copper: Effects of Potential, Pressure, and pH on Selectivity toward Multicarbon and Oxygenated Products

Author

Erlend Bertheussen, Xinyan Liu, Drew Higgins, Thomas F. Jaramillo, Jens K. Nørskov, Marat Orazov, Carlos G. Morales-Guio, Karen Chan, Stephanie A. Nitopi, Christopher Hahn, and Lei Wang

Subjects

Chemistry, Inorganic chemistry, 02 engineering and technology, General Chemistry, Reaction intermediate, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, Electrocatalyst, 01 natural sciences, Catalysis, 0104 chemical sciences, Electrochemical cell, chemistry.chemical_compound, 0210 nano-technology, Oxygenate, Carbon monoxide

Abstract

Understanding the surface reactivity of CO, which is a key intermediate during electrochemical CO2 reduction, is crucial for the development of catalysts that selectively target desired products for the conversion of CO2 to fuels and chemicals. In this study, a custom-designed electrochemical cell is utilized to investigate planar polycrystalline copper as an electrocatalyst for CO reduction under alkaline conditions. Seven major CO reduction products have been observed including various hydrocarbons and oxygenates which are also common CO2 reduction products, strongly indicating that CO is a key reaction intermediate for these further-reduced products. A comparison of CO and CO2 reduction demonstrates that there is a large decrease in the overpotential for C–C coupled products under CO reduction conditions. The effects of CO partial pressure and electrolyte pH are investigated; we conclude that the aforementioned large potential shift is primarily a pH effect. Thus, alkaline conditions can be used to inc...

Published

2018

42. Trends in the Catalytic Activity of Hydrogen Evolution during CO2 Electroreduction on Transition Metals

Author

David N. Abram, Christopher Hahn, Toru Hatsukade, Chuan Shi, Thomas F. Jaramillo, Kendra P. Kuhl, Karen Chan, and Etosha R. Cave

Subjects

Chemistry, Binding energy, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, Catalysis, 0104 chemical sciences, Volcano plot, Transition metal, Physical chemistry, Hydrogen evolution, Density functional theory, 0210 nano-technology, Polarization (electrochemistry)

Abstract

During CO2 electroreduction (CO2R), the hydrogen evolution reaction (HER) is a competing reaction. We present a combined experimental and theoretical investigation of the HER activity of transition metals under CO2R conditions. Experimental HER polarization curves were measured for six polycrystalline metal surfaces (Au, Ag, Cu, Ni, Pt, and Fe) in the presence of CO2 gas. We found that the HER activity of the transition metals is significantly shifted, relative to the CO2-free case. Density functional theory (DFT) calculations suggest that this shift arises from adsorbate–adsorbate interactions between *CO and *H on intermediate and strong binding metals, which weakens the *H binding energy. Using a simple model for the effect of *CO on the *H binding energy, we construct an activity volcano for HER in the presence of CO2 gas that is consistent with experimental trends. The significant changes in HER activity in the presence of CO2 gas is an important consideration in catalyst design and could help develo...

Published

2018

43. High-efficiency oxygen reduction to hydrogen peroxide catalysed by oxidized carbon materials

Author

Lei Liao, Guangxu Chen, Yi Cui, Yayuan Liu, Dingchang Lin, Zhiyi Lu, Jens K. Nørskov, Kai Liu, Samira Siahrostami, Zhihua Chen, Jin Xie, Thomas F. Jaramillo, and Tong Wu

Subjects

Process Chemistry and Technology, chemistry.chemical_element, Bioengineering, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Biochemistry, Oxygen, Peroxide, Combinatorial chemistry, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Anthraquinone process, 0210 nano-technology, Hydrogen peroxide, Selectivity, Carbon

Abstract

Hydrogen peroxide (H2O2) is a valuable chemical with a wide range of applications, but the current industrial synthesis of H2O2 involves an energy-intensive anthraquinone process. The electrochemical synthesis of H2O2 from oxygen reduction offers an alternative route for on-site applications; the efficiency of this process depends greatly on identifying cost-effective catalysts with high activity and selectivity. Here, we demonstrate a facile and general approach to catalyst development via the surface oxidation of abundant carbon materials to significantly enhance both the activity and selectivity (~90%) for H2O2 production by electrochemical oxygen reduction. We find that both the activity and selectivity are positively correlated with the oxygen content of the catalysts. The density functional theory calculations demonstrate that the carbon atoms adjacent to several oxygen functional groups (–COOH and C–O–C) are the active sites for oxygen reduction reaction via the two-electron pathway, which are further supported by a series of control experiments. The direct synthesis of hydrogen peroxide via oxygen reduction is an attractive alternative to the anthraquinone process. Here, a general trend linking oxygenation of carbon surfaces with electrocatalytic performance in peroxide synthesis is demonstrated, and computational studies provide further insight into the nature of the active sites.

Published

2018

44. Rapid flame doping of Co to WS2 for efficient hydrogen evolution

Author

Meredith Fields, Charlie Tsai, Jens K. Nørskov, Joonsuk Park, Joshua M. McEnaney, Hongping Yan, Robert Sinclair, Xinjian Shi, Thomas F. Jaramillo, Xiaolin Zheng, and Yirui Zhang

Subjects

chemistry.chemical_classification, Tafel equation, Materials science, Hydrogen, Dopant, Sulfide, Renewable Energy, Sustainability and the Environment, Binding energy, Doping, Analytical chemistry, chemistry.chemical_element, 02 engineering and technology, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Pollution, 0104 chemical sciences, Nuclear Energy and Engineering, Transition metal, chemistry, Environmental Chemistry, 0210 nano-technology

Abstract

Transition metal sulfides have been widely studied as electrocatalysts for the hydrogen evolution reaction (HER). Though elemental doping is an effective way to enhance sulfide activity for the HER, most studies have only focused on the effect of doping sulfide edge sites. Few studies have investigated the effect of doping the basal plane or the effect of doping concentration on basal plane activity. Probing the dopant concentration dependence of HER activity is challenging due to experimental difficulties in controlling dopant incorporation. Here, we overcome this challenge by first synthesizing doped transition metal oxides and then sulfurizing the oxides to sulfides, yielding core/shell Co-doped WS2/W18O49 nanotubes with a tunable amount of Co. Our combined density functional theory (DFT) calculations and experiments demonstrate that the HER activity of basal plane WS2 changes non-monotonically with the concentration of Co due to local changes in the binding energy of H and the formation energy of S-vacancies. At an optimal Co doping concentration, the overpotential to reach −10 mA cm−2 is reduced by 210 mV, and the Tafel slope is reduced from 122 to 49 mV per decade (mV dec−1) compared to undoped WS2 nanotubes.

Published

2018

45. Designing a Zn–Ag Catalyst Matrix and Electrolyzer System for CO 2 Conversion to CO and Beyond

Author

John M. Gregoire, Alfred M. Spormann, McKenzie A. Hubert, Frauke Kracke, Victor A. Beck, Marc Fontecave, Lei Wang, Dong Un Lee, Thomas F. Jaramillo, Sarah E. Baker, Christopher Hahn, Jaime E. Aviles Acosta, David W. Wakerley, Lan Zhou, Eric B. Duoss, Sarah Lamaison, and Thomas A. Moore

Subjects

Electrolysis, Materials science, Gas diffusion electrode, Mechanical Engineering, Halide, Electrolyte, Electrocatalyst, Catalysis, law.invention, chemistry.chemical_compound, Chemical engineering, chemistry, Mechanics of Materials, law, Electrode, General Materials Science, Carbon monoxide

Abstract

CO2 emissions can be transformed into high-added-value commodities through CO2 electrocatalysis; however, efficient low-cost electrocatalysts are needed for global scale-up. Inspired by other emerging technologies, the authors report the development of a gas diffusion electrode containing highly dispersed Ag sites in a low-cost Zn matrix. This catalyst shows unprecedented Ag mass activity for CO production: -614 mA cm-2 at 0.17 mg of Ag. Subsequent electrolyte engineering demonstrates that halide anions can further improve stability and activity of the Zn-Ag catalyst, outperforming pure Ag and Au. Membrane electrode assemblies are constructed and coupled to a microbial process that converts the CO to acetate and ethanol. Combined, these concepts present pathways to design catalysts and systems for CO2 conversion toward sought-after products.

Published

2021

46. Microenvironment Effects on Electrocatalytic Oxygen Reduction: The Role of Acid Electrolyte Anions

Author

Thomas F. Jaramillo, Michaela Burke Stevens, José A. Zamora Zeledón, Jens K. Nørskov, G. T. Kasun Kalhara Gunasooriya, and Gaurav A. Kamat

Subjects

Acid electrolyte, Chemistry, Inorganic chemistry, Oxygen reduction

Published

2021

47. Impact of Nanostructuring on the Photoelectrochemical Performance of Si/Ta3N5 Nanowire Photoanodes

Author

Ieva Narkeviciute and Thomas F. Jaramillo

Subjects

Materials science, business.industry, Nanowire, Nanotechnology, 02 engineering and technology, Carrier lifetime, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Effective nuclear charge, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, General Energy, Semiconductor, chemistry, Electrode, Physical and Theoretical Chemistry, Reactive-ion etching, Ferrocyanide, 0210 nano-technology, business, Absorption (electromagnetic radiation)

Abstract

The nanostructuring of light-absorbing materials in photoelectrochemical applications can potentially improve the performance of charge transport limited semiconductors by increasing incident light absorption as well as the electrochemically active surface area. However, a drawback associated with an increase in electrode surface area is the increased effect of surface recombination on device performance. To understand the interplay of the positive and negative impacts of nanostructuring, we studied these effects by varying the nanowire length and thereby surface area on the photoelectrochemical performance of tandem core–shell Si/Ta3N5 photoanodes. Si/Ta3N5 nanowires of different lengths, 1.2–3.3 μm, were fabricated by changing the reactive ion etch duration by which the Si nanowires are formed and subsequently characterized by optical UV–vis reflectance measurements, effective charge carrier lifetime measurements, and photoelectrochemical ferrocyanide oxidation. Overall, we show that as the nanowire len...

Published

2017

48. Defective Carbon-Based Materials for the Electrochemical Synthesis of Hydrogen Peroxide

Author

Drew Higgins, Robert Sinclair, Dimosthenis Sokaras, Taeho Roy Kim, Jens K. Nørskov, Dennis Nordlund, Zhihua Chen, Shucheng Chen, John W. F. To, Thomas F. Jaramillo, Samira Siahrostami, Zhenan Bao, and S. Nowak

Subjects

Renewable Energy, Sustainability and the Environment, Graphene, General Chemical Engineering, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, Redox, Chemical reaction, 0104 chemical sciences, Catalysis, law.invention, chemistry.chemical_compound, chemistry, Chemical engineering, law, Anthraquinone process, Environmental Chemistry, 0210 nano-technology, Hydrogen peroxide, Carbon

Abstract

Hydrogen peroxide (H2O2), an important industrial chemical, is currently produced through an energy-intensive anthraquinone process that is limited to large-scale facilities. Small-scale decentralized electrochemical production of H2O2 via a two-electron oxygen reduction reaction (ORR) offers unique opportunities for sanitization applications and the purification of drinking water. The development of inexpensive, efficient, and selective catalysts for this reaction remains a challenge. Herein, we examine two different porous carbon-based electrocatalysts and show that they exhibit high selectivity for H2O2 under alkaline conditions. By rationally varying synthetic methods, we explore the effect of pore size on electrocatalytic performance. Furthermore, by means of density functional calculations, we point out the critical role of carbon defects. Our theory results show that the majority of defects in graphene are naturally selective for the two-electron reduction of O2 to H2O2, and we identify the types o...

Published

2017

49. Building upon the Koutecky-Levich Equation for Evaluation of Next-Generation Oxygen Reduction Reaction Catalysts

Author

Drew Higgins, Maha Yusuf, Thomas F. Jaramillo, Fritz B. Prinz, Shicheng Xu, and Yongmin Kim

Subjects

Order of reaction, Chemistry, General Chemical Engineering, Inorganic chemistry, Thermodynamics, 02 engineering and technology, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, Chemical kinetics, Electrokinetic phenomena, symbols.namesake, Levich equation, Electrochemistry, symbols, Nernst equation, Rotating disk electrode, 0210 nano-technology

Abstract

The performance of oxygen reduction reaction (ORR) catalysts has been substantially improved over the past several decades. These catalysts are evaluated for electrochemical activity in a rotating disk electrode (RDE) assembly using an oxygen saturated liquid electrolyte. Koutecky-Levich (K-L) analysis provides a simple and effective method to extract electrokinetic information by correcting for mass transport effects. We propose extensions to the K-L analysis to address some of the simplifying assumptions made during its derivation. In particular, we demonstrate that decreased concentrations of surface reactants contribute to measured overpotentials in a Nernst fashion, and can lead to an underestimation of catalytic activity. By applying a Nernst overpotential correction in conjunction with K-L analysis, more accurate measurements of the intrinsic reaction kinetics under mass transport limited conditions are possible. As the K-L method assumes a reaction order of unity, we also consider kinetic reaction order deviation from unity due to measurement conditions. We show that examining the dependence of the reaction order on overpotential can provide a straightforward technique to probe blocking effects of surface absorbents. We propose that these extensions to the K-L method can allow for increased versatility of the RDE technique for extracting electrokinetic parameters for ORR catalysts.

Published

2017

50. Electrochemical CO2 Reduction over Compressively Strained CuAg Surface Alloys with Enhanced Multi-Carbon Oxygenate Selectivity

Author

Thomas F. Jaramillo, Alexis T. Bell, Christopher Hahn, and Ezra L. Clark

Subjects

Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Biochemistry, Copper, Catalysis, Methane, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Carbon dioxide, 0210 nano-technology, Carbon, Oxygenate, Electrochemical reduction of carbon dioxide

Abstract

The electrochemical reduction of carbon dioxide using renewably generated electricity offers a potential means for producing fuels and chemicals in a sustainable manner. To date, copper has been found to be the most effective catalyst for electrochemically reducing carbon dioxide to products such as methane, ethene, and ethanol. Unfortunately, the current efficiency of the process is limited by competition with the relatively facile hydrogen evolution reaction. Since multi-carbon products are more valuable precursors to chemicals and fuels than methane, there is considerable interest in modifying copper to enhance the multi-carbon product selectivity. Here, we report our investigations of electrochemical carbon dioxide reduction over CuAg bimetallic electrodes and surface alloys, which we find to be more selective for the formation of multi-carbon products than pure copper. This selectivity enhancement is a result of the selective suppression of hydrogen evolution, which occurs due to compressive strain i...

Published

2017