Publications
Surface charge dynamics on air-exposed ferroelectric Pb(Zr,Ti)O3(001) thin films.
Nanoscale, 15(31), 13062–13075.
Functional role of single-atom catalysts in electrocatalytic hydrogen evolution: Current developments and future challenges.
Coordination Chemistry Reviews, 452, 214289.
Deciphering the Influence of Morphology and Crystal Structure on Alkaline Hydrogen Evolution Activity in Polymorphic Cobalt Diselenide
ACS Applied Energy Materials 7 (4), 1550-1560.
Boosting electrochemical hydrogen evolution activity of MoS2 nanosheets via facile decoration of Au overlayer.
International Journal of Hydrogen Energy, 47(99), 41795-41805.
Operando Photoelectron Spectroscopy Analysis of Li6PS5Cl Electrochemical Decomposition Reactions in Solid-State Batteries.
ACS Energy Letters, 9(7), 3492–3500.
Machine learning-assisted equivalent circuit identification for dielectric spectroscopy of polymers.
Electrochimica Acta, 496, 144474.
Electrocatalytic Nitrate and Nitrite Reduction toward Ammonia Using Cu2O Nanocubes: Active Species and Reaction Mechanisms.
Journal Of The American Chemical Society, 146(14), 9665–9678.
Understanding the hydrogen evolution reaction kinetics of electrodeposited nickel‐molybdenum in acidic, near‐neutral, and alkaline conditions.
ChemElectroChem, 8(1), 195-208.
Host, suppressor, and promoter—The roles of Ni and Fe on oxygen evolution reaction activity and stability of NiFe alloy thin films in alkaline media.
ACS Catalysis, 11(16), 10537-10552.
Gas Flow Sputtering of Pt/C Films and their Performance in Electrocatalytic Hydrogen Evolution Reaction.
ChemPhysChem, 24(14), e202200650.
In situ/operando plug-flow fixed-bed cell for synchrotron PXRD and XAFS investigations at high temperature, pressure, controlled gas atmosphere and ultra-fast heating
Journal of Synchrotron Radiation, 31(1), 77-84.
Optimizing Bimetallic Niru@Ti3c2tx Catalysts for Oxygen Evolution: The Impact of Mxene Content on Ru Stability.
SSRN preprint.
Direct observation of the complex S(IV) equilibria at the liquid-vapor interface.
Nature Communications, 15, 8987.
Adsorbate‐Induced Modifications in the Optical Response of the Si(553)–Au Surface.
Physica status solidi (RRL)–Rapid Research Letters, 16(6), 2200002.
Operando Electron Microscopy of Catalysts: The Missing Cornerstone in Heterogeneous Catalysis Research.
Chemical Reviews, 123(23), 13374–13418.
Revealing Catalyst Restructuring and Composition During Nitrate Electroreduction through Correlated Operando Microscopy and Spectroscopy.
Research Square preprint.
Structure Sensitivity and Catalyst Restructuring for CO2 Electro-reduction on Copper.
ChemRxiv.
Hydrogen‐Induced Disproportionation of Samarium‐Cobalt Intermetallics Enabling Promoted Hydrogen Evolution Reaction Activity and Durability in Alkaline Media.
Advanced Functional Materials, 2402699.
Entropy enhanced perovskite oxide ceramic for efficient electrochemical reduction of oxygen to hydrogen peroxide.
Angewandte Chemie, 134(21), e202200086.
The Pivotal Role of s‐, p‐, and f‐block Metals in Water Electrolysis: Status Quo and Perspectives.
Advanced Materials, 34(18), 2108432.
Reviving Oxygen Evolution Electrocatalysis of bulk La–Ni Intermetallics via Gaseous Hydrogen Engineering.
Advanced Materials, 35(11), 2208337.
Structure Sensitivity and Catalyst Restructuring for CO2 Electro-reduction on Copper.
ChemRxiv.
A Facile Molecular Approach to Amorphous Nickel Pnictides and their Reconstruction to Crystalline Potassium-Intercalated γ-NiOOHx Enabling High-Performance Electrocatalytic Water Oxidation and Selective Oxidation of 5-Hydroxymethylfurfural.
Small, 19(33), 2301258.
Facet Dependence of the Oxygen Evolution Reaction on Co3O4, CoFe2O4, and Fe3O4 Epitaxial Film Electrocatalysts.
Journal Of The American Chemical Society, 146(20), 13770–13782.
Comparative study of Co3O4(111), CoFe2O4(111), and Fe3O4(111) thin film electrocatalysts for the oxygen evolution reaction.
Nature Communications, 14(1), 4791.
Surface Resonant Raman Scattering from Cu(110).
Physical Review Letters, 128(21), 216101.
Correlative In Situ Spectro-Microscopy of Supported Single CuO Nanoparticles: Unveiling the Relationships between Morphology and Chemical State during Thermal Reduction.
ACS Nano, 18 (21), 13714–13725.
Electrodeposited Porous Nickel–Copper as a Non-Noble Metal Catalyst for Urea-Assisted Anion Exchange Membrane Electrolysis for Hydrogen Production.
ACS Sustainable Chemistry & Engineering, 12(26), 9908–9921.
Rationalizing the “Anomalous” Electrochemical Stark Shift of CO at Pt(111) Through Vibrational Spectroscopy and Density-Functional Theory Calculations.
ChemRxiv.
In situ UV-Vis spectroscopy study of the water electrooxidation on cobalt oxide catalysts.
ChemRxiv.
First step of the oxygen reduction reaction on Au (111): A computational study of O2 adsorption at the electrified metal/water interface.
ACS Catalysis, 13(18), 12074-12081.
Oxygen Adsorption at the Electrochemical Metal/Water Interface: Au(111) vs Pt(111).
ChemRxiv.
Effect of Iron Doping in Ordered Nickel Oxide Thin Film Catalyst for the Oxygen Evolution Reaction.
ACS Catalysis, 14(18), 14219–14232.
Atomic Insights into the Competitive Edge of Nanosheets Splitting Water.
Journal Of The American Chemical Society, 146(40), 27886–27902.
In situ and operando Raman spectroscopy of semiconducting photoelectrodes and devices for photoelectrochemistry.
Journal of Physics D: Applied Physics, 57(10), 103002.
Mid-infrared laser ellipsometry: a new era beyond FTIR.
Advanced Optical Technologies, 11(3–4), 55–56.
Crosspolarization with imperfect infrared polarizers.
Thin Solid Films, 763, 139560.
Multi-timescale infrared quantum cascade laser ellipsometry.
Optics Letters, 47(11), 2834-2837.
High-sensitivity IR to UV broadband ellipsometry and transmission characterization of high-purity glasses.
Thin Solid Films, 774, 139819.
Updates on hydrogen value chain: A strategic roadmap.
Global Challenges, 8(6), 2300073.
Evolution of Carbonate-Intercalated γ-NiOOH from a Molecularly Derived Nickel Sulfide (Pre)Catalyst for Efficient Water and Selective Organic Oxidation.
Small, 19(16), 2206679.
New Avenues to Chemical Space for Energy Materials by the Molecular Precursor Approach.
Small Science, 3(6), 2200115.
Deciphering the Role of Nickel in Electrochemical Organic Oxidation Reactions.
Advanced Energy Materials, 14(22), 2400696.
Nitridated Nickel Mesh as Industrial Water and Alcohol Oxidation Catalyst: Reconstruction and Iron‐Incorporation Matters.
Advanced Energy Materials, 14(22), 2400696.
One-pot synthesis of iron-doped ceria catalysts for tandem carbon dioxide hydrogenation.
Catalysis Science & Technology, 14, 4174-4186.
Silver Metallization with Controlled Etch Stop using SiOx Layers in Passivating Contacts for Improved Silicon Solar Cell Performance.
Solar RRL, 7(21), 230049.
Recent technological advances in designing electrodes and electrolytes for efficient zinc ion hybrid supercapacitors.
Energy Advances, 2(9),1263-1293.
Role of Fe decoration on the oxygen evolving state of Co3O4 nanocatalysts.
Energy & Environmental Science, 17(5), 2046-2058.
Role of Nanoscale Inhomogeneities in Co2FeO4 Catalysts during the Oxygen Evolution Reaction.
Journal of the American Chemical Society, 144(27), 12007–12019.
Crystal water intercalated interlayer expanded MoS2 nanosheets as a cathode for efficient zinc-ion storage.
Dalton Transactions, 52(36), 12755- 12762.
The pervasive presence of oxygen in ZrC.
Surfaces and Interfaces, 34, 102373.
Intermetallic Cobalt Indium Nanoparticles as Oxygen Evolution Reaction Precatalyst: A Non-Leaching p-Block Element
Small, 20(29), 2309749.
Oxygen Evolution Activity of Amorphous Cobalt Oxyhydroxides: Interconnecting Precatalyst Reconstruction, Long‐Range Order, Buffer-Binding, Morphology, Mass Transport, and Operation Temperature.
Advanced Materials, 34(50), 2207494.
Effect of Surface‐Adsorbed and Intercalated (Oxy)anions on the Oxygen Evolution Reaction.
Angewandte Chemie, 61(38), e202207279.
Why should transition metal chalcogenides be investigated as water splitting precatalysts even though they transform into (oxyhydr) oxides?
Current Opinion in Electrochemistry, 34, 100991.
A rising mismatch between system complexity, characterization, and theory in electrocatalysis: challenges and solutions
Applied Catalysis B: Environmental, 342, 123447.
In‐Liquid Plasma Modified Nickel Foam: NiOOH/NiFeOOH Active Site Multiplication for Electrocatalytic Alcohol, Aldehyde, and Water Oxidation.
Advanced Energy Materials, 12(38), 2202098.
Hyping direct seawater electrolysis hinders electrolyzer development.
Joule, 8(9), 2436-2442.
Active site switching on high entropy phosphides as bifunctional oxygen electrocatalysts for rechargeable/robust Zn-Air battery.
Energy & Environmental Science, 17, 7193-7208.
Exploring mesoscopic mass transport effects on electrocatalytic selectivity.
Nature Catalysis, 7(7), 847–854.
Infrared polarimetry: Anisotropy of polymer nanofibers.
Micro and Nano Engineering, 14, 100116.
Mid‐infrared dual‐comb polarimetry of anisotropic samples.
Natural Sciences, 3(2), e20220056.
Optical monitoring during the electrochemical deposition of organic layers.
Optica Sensing Congress 2023 (AIS, FTS, HISE, Sensors, ES), Technical Digest Series, paper AM1A.1.
Field Manipulation of Band Properties in Infrared Spectra of Thin Films.
Advanced Photonics Research, 5(1), 2300212.
In Situ Coupling of Carbon Dots with Co‐ZIF Nanoarrays Enabling Highly Efficient Oxygen Evolution Electrocatalysis.
Small,19(31), 2206723.
In situ evolution of bulk-active γ-CoOOH with immobilized Gd dopants enabling efficient oxygen evolution electrocatalysis.
Nanoscale, 16, 15629-15639.
Water-soluble nickel and iron salts for hydroxymethylfurfural (HMF) and water oxidation: the simplest precatalysts?
Green Chemistry, 25(21), 8679-8686.
Challenges for Hybrid Water Electrolysis to Replace the Oxygen Evolution Reaction on an Industrial Scale.
Global Challenges, 7(7), 2200242.
Effect of the Synthesis Route and Co Coverage on Co / Ti3C2Tx Materials for the Oxygen Evolution Reaction.
Electrochimica Acta, 490, 144269.
Dynamic Operation of a Heat Exchanger in a Thermally Integrated Photovoltaic Electrolyzer.
Energy Technology, 11(2), 2201081.
Electrochemical Impedance Analysis of Direct Ammonia Fuel Cell Operation and Clamping Effects.
Electrochemical Society Meeting Abstracts, MA2023-02(37), 1799.
X-ray Absorption Near-Edge Structure (XANES) at the O K-Edge of Bulk Co3O4: Experimental and Theoretical Studies.
Nanomaterials, 12(6), 921.
High-performance anion-exchange membrane water electrolysers using NiX (X = Fe,Co,Mn) catalyst-coated membranes with redox-active Ni–O ligands.
Nature Catalysis, 7, 1213–1222.
Electrolyte Selection Toward Efficient Photoelectrochemical Glycerol Oxidation on BiVO 4.
Chemical Science, 15, 10425-10435.
Enhanced Methanol Synthesis from CO2 hydrogenation achieved by tuning the Cu-ZnO interaction in ZnO/Cu2O Nanocube Catalysts supported on ZrO2 and SiO2.
Journal of the American Chemical Society, 146 (12), 8677–8687.
Low Ti Additions to Stabilize Ru‐Ir Electrocatalysts for the Oxygen Evolution Reaction.
ChemElectroChem, 11(4), e202300399.
Detection of Foodborne Pathogens Through Volatile Organic Compounds Sensing via Metal Oxide Gas Sensors.
Advanced Sensor Research, 2400101.
Unraveling surface structures of gallium promoted transition metal catalysts in CO2 hydrogenation.
Nature Communications, 14(1), 4649.
Temperature-Dependent Photoredox Catalysis for CO2 Reduction Coupled with Selective Benzyl Alcohol Oxidation over ZnIn2S4/In2O3 Heterostructure.
Advanced Energy and Sustainability Research, 4 (12), 2300122.
Rationally Designed Laterally-Condensed-Catalysts Deliver Robust Activity and Selectivity for Ethylene Production in Acetylene Hydrogenation.
Nature Communications.
Electrocatalytic reduction of nitrogen oxide species to ammonia.
CHEMJournal.
Phase Reconstruction‐Directed Synthesis of Oxalate‐Functionalized Nickel Hydroxide Electrocatalyst for High‐Yield H2O2 Generation at Industrial Currents.
Advanced Functional Materials, 2412198.
Development of iron‐based single atom materials for general and efficient synthesis of amines.
Angewandte Chemie, 136(37), e202407859.
Achieving Digital Catalysis: Strategies for data acquisition, storage and use.
Angewandte Chemie International Edition, 62(30), e202302971.
Linking Bulk and Surface Structures in Complex Mixed Oxides.
ACS Catalysis, 14(11), 9018–9033.
Adsorbate Configurations in Ni Single-Atom Catalysts during CO2 Electrocatalytic Reduction Unveiled by Operando XAS, XES, and Machine Learning.
Physical Review Letters, 133(22), 228001.
In-Liquid Plasma for Surface Engineering of Cu Electrodes with Incorporated SiO2 Nanoparticles: From Micro to Nano.
Advanced Functional Materials, 32(6), 2107058.
On the secondary promotion effect of Al and Ga on Cu/ZnO methanol synthesis catalysts.
Journal of Catalysis, 439, 115785.
The (In)Stability of Heterostructures During the Oxygen Evolution Reaction
Advanced Energy Materials, 14(33), 2400809.
Nanostructured Intermetallic Nickel Silicide (Pre)Catalyst for Anodic Oxygen Evolution Reaction and Selective Dehydrogenation of Primary Amines.
Advanced Energy Materials, 12(25), 2200269.
Single-Atom Catalysts for Oxygen Evolution Reaction.
In: Kumar, A., Gupta, R.K. (eds) Atomically Precise Electrocatalysts for Electrochemical Energy Applications. Springer, Cham.
In-Liquid Plasma-Mediated Manganese Oxide Electrocatalysts for Quasi-Industrial Water Oxidation and Selective Dehydrogenation.
ACS Nano, 17(14), 14043-14052.
Advancing Catalysis Research through FAIR Data Principles Implemented in a Local Data Infrastructure - A Case Study of an Automated Test Reactor.
ChemRxiv.
Advancing catalysis research through FAIR data principles implemented in a local data infrastructure - A case study of an automated test reactor.
Catalysis Science & Technology, 14(21), 6186-6197.
Nanoscale Electron Transfer Variations at Electrocatalyst–Electrolyte Interfaces Resolved by in Situ Conductive Atomic Force Microscopy.
Journal of the American Chemical Society, 145(9), 5242–5251.
In situ investigation of catalytic interfaces by scanning probe microscopy under electrochemical conditions.
In Encyclopedia of Solid-Liquid Interfaces, 656–680. Elsevier.
In Situ Formation of Platinum‐Carbon Catalysts in Propane Dehydrogenation.
Angewandte Chemie, 63(24), e202319887.
Molecularly imprinted co-polymer for class-selective electrochemical detection of macrolide antibiotics in aqueous media.
Sensors and Actuators B: Chemical, 374, 132768.
Macrolide-Selective Electrochemical Sensor Built from Dual-Functional Molecularly Imprinted Polymer.
SSRN Electronic Journal, 4184565.
Designing active oxides for a durable oxygen evolution reaction.
Nature Synthesis, 2(9), 817–827.
Organic Thin Films Enable Retaining the Oxidation State of Copper Catalysts during CO2 Electroreduction.
ACS Applied Materials & Interfaces, 16(5), 6562–6568.
A Facile Approach to Alumina-Supported Pt Catalysts for the Dehydrogenation of Propane.
Industrial & Engineering Chemistry Research.
Bridging the scales within transport-coupled kinetic models for heterogeneous electrocatalysis.
ChemRxiv preprint.
Preparation and stability of the hexagonal phase of samarium oxide on Ru(0001).
Ultramicroscopy, 250, 113755.
Spectromicroscopic study of the transformation with low energy ions of a hematite thin film into a magnetite/hematite epitaxial bilayer.
Ultramicroscopy, 255, 113855.
Plasma functionalization of silica bilayer polymorphs.
ACS Applied Materials & Interfaces, 14(43), 48609–48618.
In situ investigation of ion exchange membranes reveals that ion transfer in hybrid liquid/gas electrolyzers is mediated by diffusion, not electromigration.
Journal of Materials Chemistry A, 11(25), 13570-13587.
CatLab: Hydrogen and Beyond - Thin-film Catalysts for Sustainable Chemistry with Renewable Electricity.
Bunsen-Magazin, 3, 93–95.
In Situ Detection of Iron in Oxidation States ≥ IV in Cobalt-Iron Oxyhydroxide Reconstructed during Oxygen Evolution Reaction.
Advanced Energy Materials, 13(12), 2203886.
Lithium-Directed Transformation of Amorphous Iridium (Oxy)hydroxides To Produce Active Water Oxidation Catalysts.
Journal of the American Chemical Society, 145(11), 6398- 6409.
In situ genesis of selective adsorption sites by complex catalytic redox dynamics.
Preprint from Research Square.
Metastable nickel–oxygen species modulate rate oscillations during dry reforming of methane.
Nature Catalysis, 7, 161–171.
Quo Vadis Dry Reforming of Methane?-A Review on its Chemical, Environmental, and Industrial Prospects.
Catalysis 12(5), 465.
Exploring dynamic solvation kinetics at electrocatalyst surfaces.
Nature Communications, 15(1), 8204.
Enhancing the Oxygen Evolution Reaction activity of CuCo based Hydroxides with V2CTx MXene.
Journal Of Materials Chemistry A, 12, 24248-24259.
Growth of κ-([Al,In]xGa1-x)2O3 Quantum Wells and Their Potential for Quantum-Well Infrared Photodetectors.
ACS Applied Materials & Interfaces, 15(24), 29535–2954.
Degradation of Phenol via an Advanced Oxidation Process (AOP) with Immobilized Commercial Titanium Dioxide (TiO2).
Photocatalysts Nanomaterials, 13(7), 1249.
Screening of Heterogeneous Photocatalysts for Water Splitting.
Chemie Ingenieur Technik, 94(11), 1739-1746.
Alkaline oxygen evolution: exploring synergy between fcc and hcp cobalt nanoparticles entrapped in N-doped graphene.
Materials Today Chemistry, 23, 100668.
The Berlin Joint Lab for Electrochemical Interfaces, BElChem: A Facility for In situ and Operando NAP-xPS and NAP-HAxPES Studies of Electrochemical Interfaces at BESSY II.
Synchrotron Radiation News, 35(3), 54–60.
Symmetric supercapacitors based on copper–antimony chalcogenides: A trade-off between S and Se.
Ceramics International, 49(2), 1756-1763.
Engineering strategies of metal‐organic frameworks toward advanced batteries.
Battery Energy, 2(3), 20220064.
In situ cell for grazing-incidence x-ray diffraction on thin films in thermal catalysis.
Review Of Scientific Instruments Online/Review Of Scientific Instruments, 95(3), 033904.
Reactor design for thin film catalyst activity characterization.
Chemical Engineering Journal, 477, 146926.
Reversible and Irreversible Cation Intercalation in NiFeOx Oxygen Evolution Catalysts in Alkaline Media.
Journal of Physical Chemistry Letters, 14(2), 545–551.
SR surface enrichment in solid oxide cells – Approaching the limits of EDx analysis by multivariate statistical analysis and simulations.
ChemCatChem, 14(19), e202200300.
Optical Layout and Endstation Concept for the Enhanced Liquid Interface Spectroscopy and Analysis (ELISA) Beamline at BESSY-II.
Synchrotron Radiation News, 35(3), 67–72.
Li+ Cations Activate NiFeOOH for Oxygen Evolution in Sodium and Potassium Hydroxide.
Angewandte Chemie., 63(18), e202318692.
The Chemical and Electronic Properties of Stability-Enhanced, Mixed Ir-TiOx Oxygen Evolution Reaction Catalysts.
ACS Catalysis, 13(23), 15427–15438.
Electronic and Structural Property Comparison of Iridium-Based OER Nanocatalysts Enabled by Operando Ir L3-Edge X-ray Absorption Spectroscopy.
ACS Catalysis, 14(22), 16759–16769.
Trends of Pd3Au(111) Alloy Surface Segregation in Oxygen, Carbon, and Nitrogen Environments.
The Journal of Physical Chemistry C, 127(45), 22060–22066.
Applicability of Atmospheric Pressure Plasma Jet (APPJ) Discharge for the Reduction in Graphene Oxide Films and Synthesis of Carbon Nanomaterials.
C – Journal of Carbon Research, 7(4), 71.
Physics-Based Synthetic Data Model for Automated Segmentation in Catalysis Microscopy.
Chem Rxiv.
Elemental chalcogens acting as metal-free electrocatalysts for effective alkaline and acidic hydrogen evolution reaction.
Catalysis Today, 423, 113917.
Manganese sulfide enables the formation of a highly active β-MnOOH electrocatalyst for effective alkaline water oxidation.
Materials Today Chemistry, 24, 100905.
Insights into the Single Atom and Support Interaction in Electrocatalytic Oxygen Evolution Reaction.
ChemElectroChem, 11(18), e202400159.
Charge-Polarized Selenium Vacancy in Nickel Diselenide Enabling Efficient and Stable Electrocatalytic Conversion of Oxygen to Hydrogen Peroxide.
Advanced Science, 10(4), 2205347.
Insights into the electronic structure of Fe–Ni thin-film catalysts during the oxygen evolution reaction using operando resonant photoelectron spectroscopy.
Journal of Materials Chemistry A, 11(15), 8066–8080.
Operando X-Ray Absorption Spectroscopy of Fe-N-C Catalysts Based on Carbon Black and Biomass-Derived Support Materials for ORR.
Sustainable Energy & Fuels, 8(10), 2309-2320.
Oxidation of Aqueous Phosphorous Acid Electrolyte in Contact with Pt Studied by X-ray Photoemission Spectroscopy.
ACS Applied Materials & Interfaces, 15(44), 51989–51999.
Elucidating the Complex Oxidation Behavior of Aqueous H3PO3 on Pt Electrodes via In Situ Tender X-ray Absorption Near-Edge Structure Spectroscopy at the P K-Edge.
Journal Of The American Chemical Society, 146(11), 7386–7399.
Core-Level Spectroscopy with Hard and Soft X-rays on Phosphorus-Containing Compounds for Energy Conversion and Storage.
The Journal of Physical Chemistry C, 127(42), 20582–20593.
Composition Engineering of Amorphous Nickel Boride Nanoarchitectures Enabling Highly Efficient Electrosynthesis of Hydrogen Peroxide.
Advanced Materials, 34(32), 2202995.
Efficient Alkaline Water Oxidation Electrocatalysis Enabled via the Modulation of Sn‐containing Anions towards NiFe Oxyhydroxide.
ChemCatChem, 16(17), e202400343.
Construction of coherent interface between Cu2O and CeO2 via electrochemical reconstruction for efficient carbon dioxide reduction to methane.
Journal Of Colloid And Interface Science, 673, 60-69.
Spatially and Chemically Resolved Visualization of Fe Incorporation into NiO Octahedra during the Oxygen Evolution Reaction.
Journal of the American Chemical Society, 145(39), 21465–21474.
Understanding Advanced Transition Metal‐based Two Electron Oxygen Reduction Electrocatalysts from the Perspective of Phase Engineering.
Advanced Materials, 36(25), 2400140.
Dynamic piezoelectric response facilitating lead-free ceramic to efficiently electrosynthesize hydrogen peroxide via oxygen reduction.
Electrochimica Acta, 469, 143215.
An Intermetallic CaFe6Ge6 Approach to Unprecedented Ca−Fe−O Electrocatalyst for Efficient Alkaline Oxygen Evolution Reaction.
ChemCatChem, 14(14), e202200293.
Activation of nickel foam through in-liquid plasma-induced phosphorus incorporation for efficient quasi-industrial water oxidation and selective oxygenation of organics.
Applied Catalysis B: Environmental, 324, 122249.
In Situ Reconstruction of Helical Iron Borophosphate Precatalyst toward Durable Industrial Alkaline Water Electrolysis and Selective Oxidation of Alcohols.
Advanced Functional Materials, 33(41), 2303702.
A dynamic piezoelectric effect to promote electrosynthesis of hydrogen peroxide.
Energy & Environmental Science, 16(1), 210-221.
Revealing catalyst restructuring and composition during nitrate electroreduction through correlated operando microscopy and spectroscopy.
Nature Materials.
Synergistic Active Heterostructure Design for Enhanced Two Electron Oxygen Reduction via Chemical and Electrochemical Reconstruction of Heterosulfides.
Angewandte Chemie International Edition, 63(43), e202408508.
Immobilization of oxyanions on the reconstructed heterostructure evolved from a bimetallic oxysulfide for the promotion of oxygen evolution reaction.
Nano-Micro Letters, 15(1), 186.
Key intermediates and Cu active sites for CO2 electroreduction to ethylene and ethanol.
Nature Energy.
Chemical Partitioning at Crystalline Defects in PtAu as a Pathway to Stabilize Electrocatalysts.
arXiv preprint arXiv:2209.13166.
Effect of the Precursor Metal Salt on the Oxygen Evolution Reaction for NiFe Oxide Materials.
ChemElectroChem, 11(17), e202400151.
Polar discontinuity governs surface segregation and interface termination: A case study of LaInO3/BaSnO3.
Physical Review Materials, 8(3), 034602.