Your search keyword '"David J. Dvorak"' showing total 31 results

1. Bioelectrocatalysis with a palladium membrane reactor

Author

Aiko Kurimoto, Seyed A. Nasseri, Camden Hunt, Mike Rooney, David J. Dvorak, Natalie E. LeSage, Ryan P. Jansonius, Stephen G. Withers, and Curtis P. Berlinguette

Subjects

Science

Abstract

Enzymatic catalysis requires cofactors such as NAD(P)H, whose regeneration is currently accomplished via secondary enzymes or electrolytic cell. Here, the authors report an electrochemical method of cofactors regeneration without supporting enzymes or mediators, nor formation of NAD2 dimers.

Published

2023

2. A self-driving laboratory advances the Pareto front for material properties

Author

Benjamin P. MacLeod, Fraser G. L. Parlane, Connor C. Rupnow, Kevan E. Dettelbach, Michael S. Elliott, Thomas D. Morrissey, Ted H. Haley, Oleksii Proskurin, Michael B. Rooney, Nina Taherimakhsousi, David J. Dvorak, Hsi N. Chiu, Christopher E. B. Waizenegger, Karry Ocean, Mehrdad Mokhtari, and Curtis P. Berlinguette

Subjects

Science

Abstract

Useful materials must satisfy multiple objectives. The Pareto front expresses the trade-offs of competing objectives. This work uses a self-driving laboratory to map out the Pareto front for making highly conductive coatings at low temperatures.

Published

2022

3. Solution-Deposited Solid-State Electrochromic Windows

Author

Wei Cheng, Marta Moreno-Gonzalez, Ke Hu, Caroline Krzyszkowski, David J. Dvorak, David M. Weekes, Brian Tam, and Curtis P. Berlinguette

Subjects

Science

Abstract

Summary: Commercially available electrochromic (EC) windows are based on solid-state devices in which WO3 and NiOx films commonly serve as the EC and counter electrode layers, respectively. These metal oxide layers are typically physically deposited under vacuum, a time- and capital-intensive process when using rigid substrates. Herein we report a facile solution deposition method for producing amorphous WO3 and NiOx layers that prove to be effective materials for a solid-state EC device. The full device containing these solution-processed layers demonstrates performance metrics that meet or exceed the benchmark set by devices containing physically deposited layers of the same compositions. The superior EC performance measured for our devices is attributed to the amorphous nature of the NiOx produced by the solution-based photodeposition method, which yields a more effective ion storage counter electrode relative to the crystalline NiOx layers that are more widely used. This versatile method yields a distinctive approach for constructing EC windows. : Materials Science; Coatings; Energy Materials Subject Areas: materials science, coatings, energy materials

Published

2018

4. Direct H2O2 Synthesis, without H2 Gas

Author

Aoxue Huang, Roxanna S. Delima, Yongwook Kim, Eric W. Lees, Fraser G. L. Parlane, David J. Dvorak, Michael B. Rooney, Ryan P. Jansonius, Arthur G. Fink, Zishuai Zhang, and Curtis P. Berlinguette

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Published

2022

5. Spatiotemporal visualization of CO2 electrolysis

Author

Curtis Berlinguette, Xin Lu, Chris Zhou, Roxanna Delima, Eric Lees, Abhishek Soni, David J. Dvorak, Shaoxuan Ren, Tengxiao Ji, Addie Bahi, and Frank Ko

Abstract

We report here an electrolysis optical coherence tomography (eOCT) platform to visualize the chemical reactions occurring in a CO2 electrolyzer. The eOCT platform was designed to capture three dimensional images and videos at high spatial (~1 µm) and temporal (3 to reduce CO2 into CO at applied current densities of 50-800 mA cm−2. This video resolved the nucleation and formation of CO2 in the cathode compartment upon reaction of HCO3– with H+ delivered through the membrane, the formation of CO at the cathode|electrolyte interface, and H2 throughout the cathode compartment. The video captured the strikingly dynamic movement of the cathode and membrane components during electrolysis, and linked CO production to regions of the electrolyzer in which CO2 were in direct contact with both the membrane and the catalyst layers. This visualization enabled us to correlate the decrease in CO production to a buildup of CO2, CO, and H2, and (bi)carbonate salts at the cathode layer. The statistical analysis of phase distribution images allowed us to understand the competition between main (CO2 reduction) and side (hydrogen evolution) reactions in both time and space domains. We also show how a pulsing current liberates these residual bubbles and (bi)carbonates to recover CO production. These results highlight the power of using an eOCT platform to temporally and spatially resolve CO2RR electrolysis.

Published

2023

6. Selective hydrogenation of furfural using a membrane reactor

Author

Ryan P. Jansonius, Mia D. Stankovic, Benjamin P. MacLeod, Roxanna S. Delima, Aoxue Huang, Michael B. Rooney, Arthur G. Fink, Curtis P. Berlinguette, and David J. Dvorak

Subjects

Electrolysis, Membrane reactor, Renewable Energy, Sustainability and the Environment, Chemistry, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, Furfural, 01 natural sciences, 7. Clean energy, Pollution, 0104 chemical sciences, Catalysis, law.invention, Furfuryl alcohol, chemistry.chemical_compound, Nuclear Energy and Engineering, law, Environmental Chemistry, Organic chemistry, 0210 nano-technology, Derivative (chemistry), Palladium

Abstract

Electrocatalytic palladium membrane reactors (ePMRs) use electricity and water to drive hydrogenation reactions without forming H2 gas. In these reactors, a hydrogen-permeable palladium foil physically separates electrochemical proton generation in aqueous media from chemical hydrogenation in organic media. We report herein the use of the ePMR to electrolytically hydrogenate furfural, an important biomass derivative. This system was proven to convert furfural into furfuryl alcohol and tetrahydrofurfuryl alcohol with 84% and 98% selectivities, respectively. To reach these high selectivities, we designed and built an ePMR for high-throughput testing. Using this apparatus, we tested how different solvents, catalysts, and applied currents impacted furfural hydrogenation. We found that bulky solvents with weak nucleophilicities suppressed the formation of side products. Notably, these types of solvents are not compatible with standard electrochemical hydrogenation architectures where electrolysis and hydrogenation occur in the same reaction chamber. This work highlights the utility of the ePMR for selective furfural hydrogenation without H2 gas, and presents a possible pathway for helping to decarbonize the hydrogenation industry.

Published

2022

7. Direct H

Author

Aoxue, Huang, Roxanna S, Delima, Yongwook, Kim, Eric W, Lees, Fraser G L, Parlane, David J, Dvorak, Michael B, Rooney, Ryan P, Jansonius, Arthur G, Fink, Zishuai, Zhang, and Curtis P, Berlinguette

Abstract

We report here the direct hydrogenation of O

Published

2022

8. Physical Separation of H2Activation from Hydrogenation Chemistry Reveals the Specific Role of Secondary Metal Catalysts

Author

Antonio M. Marelli, Curtis P. Berlinguette, Ryan P. Jansonius, Aiko Kurimoto, Aoxue Huang, Camden Hunt, and David J. Dvorak

Subjects

inorganic chemicals, Membrane reactor, Hydrogen, 010405 organic chemistry, Chemistry, chemistry.chemical_element, General Chemistry, 02 engineering and technology, General Medicine, Electrochemistry, Electrocatalyst, 010402 general chemistry, 021001 nanoscience & nanotechnology, Redox, 7. Clean energy, 01 natural sciences, Catalysis, 0104 chemical sciences, Membrane, Chemical engineering, 0210 nano-technology, Palladium

Abstract

An electrocatalytic palladium membrane reactor (ePMR) uses electricity and water to drive hydrogenation without H2 gas. The device contains a palladium membrane to physically separate the formation of reactive hydrogen atoms from hydrogenation of the unsaturated organic substrate. This separation provides an opportunity to independently measure the hydrogenation reaction at a surface without any competing H2 activation or proton reduction chemistry. We took advantage of this feature to test how different metal catalysts coated on the palladium membrane affect the rates of hydrogenation of C=O and C=C bonds. Hydrogenation occurs at the secondary metal catalyst and not the underlying palladium membrane. These secondary catalysts also serve to accelerate the reaction and draw a higher flux of hydrogen through the membrane. These results reveal insights into hydrogenation chemistry that would be challenging using thermal or electrochemical hydrogenation experiments.

Published

2021

9. Electrocatalysts Derived from Copper Complexes Transform CO into C 2+ Products Effectively in a Flow Cell

Author

Shaoxuan Ren, Zishuai Zhang, Eric W. Lees, Arthur G. Fink, Luke Melo, Camden Hunt, David J. Dvorak, Wen Yu Wu, Edward R. Grant, and Curtis P. Berlinguette

Subjects

Organic Chemistry, General Chemistry, Catalysis

Published

2022

10. Sulfuric Acid Electrolyte Impacts Palladium Chemistry at Reductive Potentials

Author

Ke Hu, David J. Dvorak, Aoxue Huang, David K. Fork, Phil A. Schauer, Adam Bottomley, Curtis P. Berlinguette, Brian Lam, James W. Grayson, and Marta Moreno-Gonzalez

Subjects

inorganic chemicals, Hydrogen sorption, Hydrogen, General Chemical Engineering, Kinetics, Inorganic chemistry, chemistry.chemical_element, Sulfuric acid, 02 engineering and technology, General Chemistry, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, complex mixtures, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Desorption, Materials Chemistry, 0210 nano-technology, Palladium

Abstract

We report herein that sulfuric acid electrolyte affects the kinetics of hydrogen sorption and desorption, the amount of absorbed hydrogen, and the electrocatalytic activity of palladium using X-ray...

Published

2020

11. Electrodes Designed for Converting Bicarbonate into CO

Author

Danielle A. Salvatore, Maxwell Goldman, Eric W. Lees, David J. Dvorak, Zishuai Zhang, Arthur G. Fink, Curtis P. Berlinguette, and Nicholas W. X. Loo

Subjects

Waste management, Renewable Energy, Sustainability and the Environment, Bicarbonate, Energy Engineering and Power Technology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 7. Clean energy, 0104 chemical sciences, chemistry.chemical_compound, Fuel Technology, chemistry, Chemistry (miscellaneous), Electrode, Materials Chemistry, Environmental science, Upstream (networking), 0210 nano-technology

Abstract

The deployment of electrolyzers that convert CO2 into chemicals and fuels requires appropriate integration with upstream carbon capture processes. To this end, the electrolytic conversion of aqueou...

Published

2020

12. Strain Influences the Hydrogen Evolution Activity and Absorption Capacity of Palladium

Author

Curtis P. Berlinguette, David K. Fork, Ryan P. Jansonius, Phil A. Schauer, Benjamin P. MacLeod, and David J. Dvorak

Subjects

inorganic chemicals, Materials science, Working electrode, Hydrogen, Strain (chemistry), 010405 organic chemistry, chemistry.chemical_element, General Chemistry, General Medicine, 010402 general chemistry, Electrocatalyst, Electrochemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Electrochemical cell, Strain engineering, chemistry, Chemical engineering, Palladium

Abstract

Strain engineering can increase the activity and selectivity of an electrocatalyst. Tensile strain is known to improve the electrocatalytic activity of palladium electrodes for reduction of carbon dioxide or dioxygen, but determining how strain affects the hydrogen evolution reaction (HER) is complicated by the fact that palladium absorbs hydrogen concurrently with HER. We report here a custom electrochemical cell, which applies tensile strain to a flexible working electrode, that enabled us to resolve how tensile strain affects hydrogen absorption and HER activity for a thin film palladium electrocatalyst. When the electrodes were subjected to mechanically-applied tensile strain, the amount of hydrogen that absorbed into the palladium decreased, and HER electrocatalytic activity increased. This study showcases how strain can be used to modulate the hydrogen absorption capacity and HER activity of palladium.

Published

2020

13. Managing Hydration at the Cathode Enables Efficient CO2 Electrolysis at Commercially Relevant Current Densities

Author

Danika G. Wheeler, Curtis P. Berlinguette, Benjamin A. W. Mowbray, David J. Dvorak, Angelica Reyes, Ryan P. Jansonius, Yang Cao, and Jacky Chau

Subjects

Electrolysis, Materials science, Renewable Energy, Sustainability and the Environment, Continuous reactor, Energy Engineering and Power Technology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 7. Clean energy, 01 natural sciences, Cathode, 0104 chemical sciences, law.invention, Fuel Technology, Chemical engineering, Chemistry (miscellaneous), law, Materials Chemistry, Current (fluid), 0210 nano-technology

Abstract

Gas-fed CO2 electrochemical flow reactors are appealing platforms for the electrolytic conversion of CO2 into fuels and chemical feedstocks at commercially relevant current densities (≥100 mA/cm2)....

Published

2020

14. Linking gas diffusion electrode composition to CO2 reduction in a flow cell

Author

Eric W. Lees, Curtis P. Berlinguette, Grace Simpson, Jacky Chau, Shaoxuan Ren, Danielle A. Salvatore, David J. Dvorak, Katherine L. Milton, and Benjamin A. W. Mowbray

Subjects

Materials science, Gas diffusion electrode, Renewable Energy, Sustainability and the Environment, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, Electrocatalyst, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Chemical engineering, Electrode, Gaseous diffusion, General Materials Science, Formate, 0210 nano-technology, Ionomer, Faraday efficiency

Abstract

Gas diffusion electrodes (GDEs) mediate the transport of reagents, products, and electrons in electrochemical reactors designed to reduce CO2 into fuels or chemicals. While the ratio of ionomer to electrocatalyst in the precursor catalyst ink is typically assumed not to change after being deposited on the GDE, we show herein that this assumption is likely not valid. Moreover, we discovered that the faradaic efficiency for formate, which is considered to be inconsequential relative to CO when using Ag electrocatalysts, can be modulated by 20% by a mere 5 wt% change in GDE Nafion® content. We were able to resolve these small differences in GDE composition by developing an X-ray fluorescence (XRF) spectroscopic protocol that quantifies the sulfonate groups appended to the polytetrafluoroethylene (PTFE) backbone of Nafion®. Using this protocol, we were able to determine how to precisely control the relative amount of ionomer to electrocatalyst for each GDE. We also found that maintaining a uniform ionomer–catalyst composition across the entire GDE can likely be done more effectively with automated spray coating than with manual deposition methods. We recommend following these procedures in order to generate reproducible CO2RR performance parameters in flow cells.

Published

2020

15. Quantification of the Effect of an External Magnetic Field on Water Oxidation with Cobalt Oxide Anodes

Author

Camden Hunt, Zishuai Zhang, Karry Ocean, Ryan P. Jansonius, Mohamad Abbas, David J. Dvorak, Aiko Kurimoto, Eric W. Lees, Supriya Ghosh, Ari Turkiewicz, Felipe A. Garcés Pineda, David K. Fork, and Curtis P. Berlinguette

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Abstract

Here, we quantify the effect of an external magnetic field (β) on the oxygen evolution reaction (OER) for a cobalt oxide|fluorine-doped tin oxide coated glass (CoO

Published

2022

16. Electrocatalysts derived from copper complexes transform CO into C2+ products effectively in a flow cell

Author

Wen Yu Wu, Edward R. Grant, Zishuai Zhang, Camden Hunt, Eric W. Lees, Shaoxuan Ren, Curtis P. Berlinguette, Luke Melo, Arthur G. Fink, and David J. Dvorak

Subjects

chemistry, Chemical engineering, chemistry.chemical_element, Flow cell, Copper

Abstract

The highest performance flow cells capable of electrolytically converting CO2 into higher value chemicals and fuels pass a concentrated hydroxide electrolyte across the cathode. A major problem for CO2 electrolysis is that this strongly alkaline medium converts the majority of CO2 into unreactive HCO3– and CO32– rather than CO2 reduction reaction (CO2RR) products. The electrolysis of CO (instead of CO2) does not suffer from this same problem because CO does not react with hydroxide. Moreover, CO can be more readily converted into products containing two or more carbon atoms (i.e., C2+ products). While several solid-state electrocatalysts have proven competent at converting CO into C2+ products, we demonstrate here that molecular electrocatalysts are also effective at mediating this transformation in a flow cell. Using a molecular copper phthalocyanine (CuPc) electrocatalyst, CO was electrolyzed into C2+ products at high rates of product formation (i.e., current densities J ≥200 mA/cm2), and at high Faradaic efficiencies for C2+ production (FEC2+; 72% at 200 mA/cm2). These findings present a new class of electrocatalysts for making carbon-neutral chemicals and fuels.

Published

2021

17. A self-driving laboratory advances the Pareto front for material properties

Author

Benjamin P, MacLeod, Fraser G L, Parlane, Connor C, Rupnow, Kevan E, Dettelbach, Michael S, Elliott, Thomas D, Morrissey, Ted H, Haley, Oleksii, Proskurin, Michael B, Rooney, Nina, Taherimakhsousi, David J, Dvorak, Hsi N, Chiu, Christopher E B, Waizenegger, Karry, Ocean, Mehrdad, Mokhtari, and Curtis P, Berlinguette

Abstract

Useful materials must satisfy multiple objectives, where the optimization of one objective is often at the expense of another. The Pareto front reports the optimal trade-offs between these conflicting objectives. Here we use a self-driving laboratory, Ada, to define the Pareto front of conductivities and processing temperatures for palladium films formed by combustion synthesis. Ada discovers new synthesis conditions that yield metallic films at lower processing temperatures (below 200 °C) relative to the prior art for this technique (250 °C). This temperature difference makes possible the coating of different commodity plastic materials (e.g., Nafion, polyethersulfone). These combustion synthesis conditions enable us to to spray coat uniform palladium films with moderate conductivity (1.1 × 10

Published

2021

18. Protocol for Quantifying the Doping of Organic Hole-Transport Materials

Author

Kitty Y. Chen, David M. Weekes, David J. Dvorak, Curtis P. Berlinguette, Rebecka L. Forward, and Yang Cao

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Doping, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Fuel Technology, Chemistry (miscellaneous), Materials Chemistry, Optoelectronics, 0210 nano-technology, business, Protocol (object-oriented programming)

Published

2019

19. Dopant-free molecular hole transport material that mediates a 20% power conversion efficiency in a perovskite solar cell

Author

Thomas D. Morrissey, Yunlong Li, David J. Dvorak, Zhicheng Xia, Curtis P. Berlinguette, Timothy L. Kelly, Brian O. Patrick, Brian Lam, and Yang Cao

Subjects

Chemical Physics (physics.chem-ph), Electron mobility, Materials science, Dopant, Renewable Energy, Sustainability and the Environment, Annealing (metallurgy), Intermolecular force, Energy conversion efficiency, FOS: Physical sciences, Perovskite solar cell, Physics - Applied Physics, Applied Physics (physics.app-ph), 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 7. Clean energy, Pollution, 0104 chemical sciences, Nuclear Energy and Engineering, Chemical engineering, Physics - Chemical Physics, Environmental Chemistry, Amine gas treating, 0210 nano-technology

Abstract

Organic molecular hole-transport materials (HTMs) are appealing for the scalable manufacture of perovskite solar cells (PSCs) because they are easier to reproducibly prepare in high purity than polymeric and inorganic HTMs. There is also a need to construct PSCs without dopants and additives to avoid formidable engineering and stability issues. We report here a power conversion efficiency (PCE) of 20.6% with a molecular HTM in an inverted (p–i–n) PSC without any dopants or interlayers. This new benchmark was made possible by the discovery that, upon annealing, a spiro-based dopant-free HTM (denoted DFH) containing redox-active triphenyl amine (TPA) units undergoes preferential molecular organization normal to the substrate. This structural order, governed by the strong intermolecular interactions of the DFH dioxane groups, affords high intrinsic hole mobility (1 × 10−3 cm2 V−1 s−1). Annealing films of DFH also enables the growth of large perovskite grains (up to 2 μm) that minimize charge recombination in the PSC. DFH can also be isolated at a fraction of the cost of any other organic HTM.

Published

2019

20. Design rules for high mobility xanthene-based hole transport materials

Author

Yang Cao, Daniel P. Tabor, Pascal Friederich, Alán Aspuru-Guzik, Curtis P. Berlinguette, David J. Dvorak, and Valerie A. Chiykowski

Subjects

Steric effects, Organic electronics, Xanthene, Technology, Electron mobility, Materials science, 010405 organic chemistry, business.industry, General Chemistry, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, OLED, Surface modification, Optoelectronics, business, ddc:600, Electrical conductor, Perovskite (structure)

Abstract

Tunable and highly conductive hole transport materials are crucial for the performance of organic electronics applications such as organic light emitting diodes and perovskite solar cells. For commercial applications, these materials' requirements include easy synthesis, high hole mobility, and highly tuned and compatible electronic energy levels. Here, we present a systematic study of a recently discovered, easy-to-synthesize class of spiro[fluorene-9,9′-xanthene]-based organic hole transport materials. Systematic side group functionalization allows us to control the HOMO energy and charge carrier mobility. Analysis of the bulk simulations enables us to derive design rules for mobility enhancement. We show that larger functional groups (e.g. methyl) decrease the conformational disorder due to steric effects and thus increase the hole mobility. Highly asymmetric or polar side groups (e.g. fluorine), however, increase the electrostatic disorder and thus reduce the hole mobility. These generally applicable design rules will help in the future to further optimize organic hole transport materials.

Published

2019

21. Supported palladium membrane reactor architecture for electrocatalytic hydrogenation

Author

Roxanna S. Delima, David J. Dvorak, Aiko Kurimoto, Curtis P. Berlinguette, and Rebecca S. Sherbo

Subjects

inorganic chemicals, Materials science, Membrane reactor, Hydrogen, Renewable Energy, Sustainability and the Environment, chemistry.chemical_element, 02 engineering and technology, General Chemistry, Electrolyte, 021001 nanoscience & nanotechnology, Electrocatalyst, Membrane, chemistry, Chemical engineering, Reagent, General Materials Science, 0210 nano-technology, FOIL method, Palladium

Abstract

Electrolytic palladium membrane reactors offer a means to perform hydrogenation chemistry utilizing electrolytically produced hydrogen derived from water instead of hydrogen gas. While previous embodiments of these reactors employed thick (≥25 μm) palladium foil membranes, we report here that the amount of palladium can be reduced by depositing a thin (1–2 μm) layer of palladium onto a porous polytetrafluoroethylene (PTFE) support. The supported palladium membrane can be designed to ensure the fast diffusion of reagent and hydrogen to the palladium layer. The hydrogenation of 1-hexyne, for example, shows that the supported Pd/PTFE membrane can achieve reaction rates (e.g., 0.71 mmol h−1) which are comparable to 0.92 mmol h−1 measured for palladium membranes with a high-surface area palladium electrocatalyst layer. The root cause of these comparable rates is that the high porosity of PTFE enables a 12-fold increase in electrocatalytic surface area compared to planar palladium foil membranes. These results provide a pathway for designing a cost-effective and potentially scalable electrolytic palladium membrane reactor.

Published

2019

22. Electrolytic conversion of carbon capture solutions containing carbonic anhydrase

Author

Arthur G, Fink, Eric W, Lees, Julie, Gingras, Eric, Madore, Sylvie, Fradette, Shaffiq A, Jaffer, Maxwell, Goldman, David J, Dvorak, and Curtis P, Berlinguette

Subjects

Inorganic Chemistry, Bicarbonates, Carbon Dioxide, Biochemistry, Carbon, Electrolysis, Carbonic Anhydrases

Abstract

The electrolysis of carbon capture solutions bypasses energy-intensive CO

Published

2022

23. Physical Separation of H

Author

Aiko, Kurimoto, Ryan P, Jansonius, Aoxue, Huang, Antonio M, Marelli, David J, Dvorak, Camden, Hunt, and Curtis P, Berlinguette

Abstract

An electrocatalytic palladium membrane reactor (ePMR) uses electricity and water to drive hydrogenation without H

Published

2021

24. Molecular electrocatalysts transform CO into C2+ products effectively in a flow cell

Author

Zishuai Zhang, Wen Yu Wu, Eric W. Lees, Shaoxuan Ren, Arthur G. Fink, David J. Dvorak, and Curtis P. Berlinguette

Subjects

Chemical engineering, Chemistry, Flow cell

Abstract

The highest performance flow cells capable of electrolytically converting CO2 into higher value chemicals and fuels pass a concentrated hydroxide electrolyte across the cathode. A major problem for CO2 electrolysis is that this strongly alkaline medium converts the majority of CO2 into unreactive HCO3– and CO32– rather than CO2 reduction reaction (CO2RR) products. The electrolysis of CO (instead of CO2) does not suffer from this same problem because CO does not react with hydroxide. Moreover, CO can be more readily converted into products containing two or more carbon atoms (i.e., C2+ products). While several solid-state electrocatalysts have proven competent at converting CO into C2+ products, we demonstrate here that molecular electrocatalysts are also effective at mediating this transformation in a flow cell. Using a molecular copper phthalocyanine (CuPc) electrocatalyst, CO was electrolyzed into C2+ products at high rates of product formation (i.e., current densities J ≥200 mA/cm2), and at high Faradaic efficiencies for C2+ production (FEC2+; 72% at 200 mA/cm2). These findings present a new class of electrocatalysts for making carbon-neutral chemicals and fuels.

Published

2020

25. Self-driving laboratory for accelerated discovery of thin-film materials

Author

Raphaell Moreira, Henry Situ, Thomas D. Morrissey, Joseph R. Deeth, Veronica Lai, Michael S. Elliott, Alán Aspuru-Guzik, Ray H. Zhang, Loïc M. Roch, Jason E. Hein, Fraser G. L. Parlane, Gordon J. Ng, Curtis P. Berlinguette, Benjamin P. MacLeod, Florian Häse, Lars P. E. Yunker, Michael B. Rooney, Kevan E. Dettelbach, David J. Dvorak, and Ted H. Haley

Subjects

Materials Science, FOS: Physical sciences, Applied Physics (physics.app-ph), 02 engineering and technology, 010402 general chemistry, 01 natural sciences, 7. Clean energy, Condensed Matter::Materials Science, Self driving, Condensed Matter::Superconductivity, Electronics, Thin film, Process engineering, Research Articles, Condensed Matter - Materials Science, Multidisciplinary, Optimization algorithm, business.industry, Materials Science (cond-mat.mtrl-sci), SciAdv r-articles, Physics - Applied Physics, Modular design, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 021001 nanoscience & nanotechnology, Research process, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Clean energy, Condensed Matter::Strongly Correlated Electrons, Inorganic materials, 0210 nano-technology, business, Research Article

Abstract

An autonomous laboratory for thin film discovery is used to optimize the doping and annealing of organic semiconductors., Discovering and optimizing commercially viable materials for clean energy applications typically takes more than a decade. Self-driving laboratories that iteratively design, execute, and learn from materials science experiments in a fully autonomous loop present an opportunity to accelerate this research process. We report here a modular robotic platform driven by a model-based optimization algorithm capable of autonomously optimizing the optical and electronic properties of thin-film materials by modifying the film composition and processing conditions. We demonstrate the power of this platform by using it to maximize the hole mobility of organic hole transport materials commonly used in perovskite solar cells and consumer electronics. This demonstration highlights the possibilities of using autonomous laboratories to discover organic and inorganic materials relevant to materials sciences and clean energy technologies.

Published

2020

26. Solution-Deposited Solid-State Electrochromic Windows

Author

Ke Hu, Brian Tam, David M. Weekes, Wei Cheng, Caroline Krzyszkowski, Curtis P. Berlinguette, Marta Moreno-Gonzalez, and David J. Dvorak

Subjects

energy materials, Auxiliary electrode, Materials science, materials science, Solid-state, Oxide, 02 engineering and technology, coatings, 010402 general chemistry, 01 natural sciences, Article, Ion, Metal, chemistry.chemical_compound, lcsh:Science, Deposition (law), Multidisciplinary, business.industry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Amorphous solid, chemistry, Electrochromism, visual_art, visual_art.visual_art_medium, Optoelectronics, lcsh:Q, 0210 nano-technology, business

Abstract

Summary Commercially available electrochromic (EC) windows are based on solid-state devices in which WO3 and NiOx films commonly serve as the EC and counter electrode layers, respectively. These metal oxide layers are typically physically deposited under vacuum, a time- and capital-intensive process when using rigid substrates. Herein we report a facile solution deposition method for producing amorphous WO3 and NiOx layers that prove to be effective materials for a solid-state EC device. The full device containing these solution-processed layers demonstrates performance metrics that meet or exceed the benchmark set by devices containing physically deposited layers of the same compositions. The superior EC performance measured for our devices is attributed to the amorphous nature of the NiOx produced by the solution-based photodeposition method, which yields a more effective ion storage counter electrode relative to the crystalline NiOx layers that are more widely used. This versatile method yields a distinctive approach for constructing EC windows., Graphical Abstract, Highlights • Amorphous WO3 and NiOx films are produced by a solution-deposition method • The WO3 and NiOx films are assembled into a solid-state electrochromic device • The solid-state device exhibits state-of-the-art electrochromic performance • Amorphous NiOx is a superior counter electrode material compared with crystalline NiOx, Materials Science; Coatings; Energy Materials

Published

2018

27. Accurate Coulometric Quantification of Hydrogen Absorption in Palladium Nanoparticles and Thin Films

Author

David K. Fork, David J. Dvorak, Curtis P. Berlinguette, Marta Moreno-Gonzalez, Noah J. J. Johnson, and Rebecca S. Sherbo

Subjects

Materials science, Hydrogen, General Chemical Engineering, Inorganic chemistry, Nanoparticle, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 7. Clean energy, 01 natural sciences, Casting, 0104 chemical sciences, Coulometry, Adsorption, chemistry, Materials Chemistry, Thin film, 0210 nano-technology, Palladium

Abstract

We report here an electrochemical method for precise and accurate quantification of hydrogen absorption in palladium materials. We demonstrate that conventional chronocoulometry over-reports adsorbed hydrogen due to charge from the accompanying hydrogen oxidation reaction (HOR). We designed and built a bespoke electrochemical flow cell that mitigates the concurrent HOR reaction and consequently provides improved accuracy and reproducibility relative to other existing electrochemical techniques. The efficacy of this technique is demonstrated experimentally for a series of palladium sample types: a 100 nm electron-beam deposited thin film, a 20 μm electrodeposited palladium film, a casting of 21 nm edge-length cubic nanoparticles, and a casting of 27 nm edge-length octahedral nanoparticles. We contend that this method is the most effective for measuring hydrogen uptake in different palladium samples.

Published

2018

28. Layered amorphous silicon as negative electrodes in lithium-ion batteries

Author

Mark N. Obrovac, David J. Dvorak, and Leyi Zhao

Subjects

Amorphous silicon, Void (astronomy), Materials science, Silicon, Renewable Energy, Sustainability and the Environment, Inorganic chemistry, technology, industry, and agriculture, Nanocrystalline silicon, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, Ion, chemistry.chemical_compound, chemistry, Chemical engineering, Volume expansion, Electrode, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, 0210 nano-technology

Abstract

Chemical delithiation is used to prepare bulk quantities of amorphous silicon powder from lithium-silicon compounds. The amorphous silicon materials formed are air and water stable and are found to have layered structures. When cycled in Li-ion half cells, coatings containing layered amorphous silicon are found to have significantly lower volume expansion during lithiation and improved cycling characteristics compared to that of bulk crystalline Si. We suggest chemical delithiation as a convenient method to synthesize bulk quantities of Si powders containing self-organized void spaces that can accommodate volume expansion during lithiation.

Published

2016

29. Evidence for superconductivity in Li-decorated monolayer graphene

Author

Douglas Wong, Giorgio Levy, Christian R. Ast, Michael Schneider, C. N. Veenstra, Carola Straßer, Pinder Dosanjh, Andrea Damascelli, Stiven Forti, Alexander Stöhr, David J. Dvorak, Ulrich Starke, Pascal Nigge, B. Ludbrook, Sergey Zhdanovich, and M. Zonno

Subjects

Superconductivity, Physics, Multidisciplinary, Condensed matter physics, Photoemission spectroscopy, Graphene, Condensed Matter - Superconductivity, Superlattice, FOS: Physical sciences, chemistry.chemical_element, Angle-resolved photoemission spectroscopy, Fermi surface, 3. Good health, law.invention, Superconductivity (cond-mat.supr-con), Condensed Matter::Materials Science, chemistry, law, Condensed Matter::Superconductivity, Pairing, Physical Sciences, Lithium

Abstract

Monolayer graphene exhibits many spectacular electronic properties, with superconductivity being arguably the most notable exception. It was theoretically proposed that superconductivity might be induced by enhancing the electron-phonon coupling through the decoration of graphene with an alkali adatom superlattice [Profeta et al. Nat. Phys. 8, 131-134 (2012)]. While experiments have indeed demonstrated an adatom-induced enhancement of the electron-phonon coupling, superconductivity has never been observed. Using angle-resolved photoemission spectroscopy (ARPES) we show that lithium deposited on graphene at low temperature strongly modifies the phonon density of states, leading to an enhancement of the electron-phonon coupling of up to $\lambda\!\simeq\!0.58$. On part of the graphene-derived $\pi^*$-band Fermi surface, we then observe the opening of a $\Delta\!\simeq\!0.9$ meV temperature-dependent pairing gap. This result suggests for the first time, to our knowledge, that Li-decorated monolayer graphene is indeed superconducting with $T_c\!\simeq\!5.9 K$., Comment: Accepted. A high-resolution version with supplementary material can be found at http://qmlab.ubc.ca/ARPES/PUBLICATIONS/Articles/Graphene_Li.pdf

Published

2015

30. Axial EBIC oscillations at core/shell GaAs/Fe nanowire contacts

Author

Karen L. Kavanagh, David J. Dvorak, Christine Damm, Simon P. Watkins, Mingze Yang, and K. Leistner

Subjects

Materials science, Scanning electron microscope, Mechanical Engineering, Electron beam-induced current, Nanowire, Bioengineering, 02 engineering and technology, General Chemistry, Substrate (electronics), 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, Grain size, 0104 chemical sciences, Mechanics of Materials, Cathode ray, General Materials Science, Electrical and Electronic Engineering, 0210 nano-technology, Spectroscopy, Layer (electronics)

Abstract

Electron beam induced current (EBIC) measurements were carried out in situ in the scanning electron microscope on free-standing GaAs/Fe core-shell nanowires (NWs), isolated from the GaAs substrate via a layer of aluminum oxide. The excess current as a function of the electron beam energy, position on the NW, and scan direction were collected, together with energy dispersive x-ray spectroscopy. A model that included the effects of beam energy and Fe thickness predicted an average collection efficiency of 60%. Small spatial oscillations in the EBIC current were observed, that correlated with the average Fe grain size (30 nm). These oscillations likely originated from lateral variations in the interfacial oxide thickness, affecting the resistance, barrier potentials, and density of minority carrier recombination traps.

Published

2018

31. Regrowth mechanism for oxide isolation of GaAs nanowires

Author

Karen L. Kavanagh, Ali Darbandi, David J. Dvorak, and Simon P. Watkins

Subjects

010302 applied physics, Materials science, Annealing (metallurgy), Mechanical Engineering, Nanowire, Oxide, Nanoparticle, Bioengineering, Nanotechnology, Equivalent oxide thickness, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Thermal expansion, Atomic layer deposition, chemistry.chemical_compound, chemistry, Mechanics of Materials, 0103 physical sciences, General Materials Science, Electrical and Electronic Engineering, Composite material, 0210 nano-technology, Graphene oxide paper

Abstract

Oxide-isolated GaAs nanowires (NWs) were obtained through a lithography-free method in which axial growth of NWs coated in aluminum oxide (Al2O3) is restarted using an annealing step. NWs are grown using the vapor-liquid-solid method and coated in nanometer thin oxide films using atomic layer deposition. Continued growth at the oxide-coated nanoparticle (NP) occurs after the thermally-induced fracture of the oxide during annealing. This oxide fracture is observed to depend on NP diameter, oxide thickness and annealing temperature. A thermal expansion mismatch model for stresses on the oxide shell is put forward to explain these results.

Published

2017