| 1 | Deactivation of copper electrocatalysts during CO<sub>2</sub> reduction occurs <i>via</i> dissolution and selective redeposition mechanism | 9.3 | 19 | Citations (PDF) |
| 2 | Iridium nanoparticles for oxygen evolution reaction on carbon and TiO2 supports from a Raman perspective | 9.1 | 10 | Citations (PDF) |
| 3 | Structure–Stability Relationships in Pt-Alloy Nanoparticles Using Identical-Location Four-Dimensional Scanning Transmission Electron Microscopy and Unsupervised Machine Learning | 15.3 | 14 | Citations (PDF) |
| 4 | The role of nanoporosity in oxygen reduction reaction under elevated mass transport: Porous vs core-shell | 6.5 | 1 | Citations (PDF) |
| 5 | Be Aware of Transient Dissolution Processes in Co<sub>3</sub>O<sub>4</sub> Acidic Oxygen Evolution Reaction Electrocatalysts | 15.1 | 50 | Citations (PDF) |
| 6 | The role of high-resolution transmission electron microscopy and aberration corrected scanning transmission electron microscopy in unraveling the structure–property relationships of Pt-based fuel cells electrocatalysts | 6.4 | 18 | Citations (PDF) |
| 7 | Enhancing oxygen evolution functionality through anodization and nitridation of compositionally complex alloy | 3.7 | 2 | Citations (PDF) |
| 8 | Metal–Support Interaction between Titanium Oxynitride and Pt Nanoparticles Enables Efficient Low-Pt-Loaded High-Performance Electrodes at Relevant Oxygen Reduction Reaction Current Densities | 12.9 | 20 | Citations (PDF) |
| 9 | Enhancing oxygen evolution functionality through anodization and nitridation of compositionally complex alloy | 3.7 | 1 | Citations (PDF) |
| 10 | Adjusting the Operational Potential Window as a Tool for Prolonging the Durability of Carbon-Supported Pt-Alloy Nanoparticles as Oxygen Reduction Reaction Electrocatalysts | 12.9 | 15 | Citations (PDF) |
| 11 | Allotrope-dependent activity-stability relationships of molybdenum sulfide hydrogen evolution electrocatalysts | 13.9 | 42 | Citations (PDF) |
| 12 | Ni-MoO2 Composite Coatings Electrodeposited at Porous Ni Substrate as Efficient Alkaline Water Splitting Cathodes | 2.6 | 2 | Citations (PDF) |
| 13 | Fundamental and Practical Aspects of Break‐In/Conditioning of Proton Exchange Membrane Fuel Cells | 6.5 | 6 | Citations (PDF) |
| 14 | Alternative and facile production pathway towards obtaining high surface area PtCo/C intermetallic catalysts for improved PEM fuel cell performance | 4.4 | 15 | Citations (PDF) |
| 15 | Determination of the Electroactive Surface Area of Supported Ir-Based Oxygen Evolution Catalysts by Impedance Spectroscopy: Observed Anomalies with Respect to Catalyst Loading | 3.1 | 15 | Citations (PDF) |
| 16 | Towards electrochemical iridium recycling in acidic media: effect of the presence of organic molecules and chloride ions | 4.4 | 9 | Citations (PDF) |
| 17 | Nanotubular TiO<sub><i>x</i></sub>N<sub><i>y</i></sub>-Supported Ir Single Atoms and Clusters as Thin-Film Electrocatalysts for Oxygen Evolution in Acid Media | 6.8 | 20 | Citations (PDF) |
| 18 | Sustainable CO<sub>2</sub>-Derived Nanoscale Carbon Support to a Platinum Catalyst for Oxygen Reduction Reaction | 5.3 | 16 | Citations (PDF) |
| 19 | “<i>Nano Lab</i>” Advanced Characterization Platform for Studying Electrocatalytic Iridium Nanoparticles Dispersed on TiO<sub><i>x</i></sub>N<sub><i>y</i></sub> Supports Prepared on Ti Transmission Electron Microscopy Grids | 5.3 | 7 | Citations (PDF) |
| 20 | Mechanistic Study of Fast Performance Decay of PtCu Alloy-based Catalyst Layers for Polymer Electrolyte Fuel Cells through Electrochemical Impedance Spectroscopy | 2.9 | 3 | Citations (PDF) |
| 21 | Intrinsic properties of nanoparticulate Ir-based catalysts for oxygen evolution reaction by AC voltammetry | 5.3 | 5 | Citations (PDF) |
| 22 | Periodic anti-phase boundaries and crystal superstructures in PtCu3 nanoparticles as fuel cell electrocatalysts | 5.0 | 5 | Citations (PDF) |
| 23 | Robust SrTiO<sub>3</sub> Passivation of Silicon Photocathode by Reduced Graphene Oxide for Solar Water Splitting | 8.0 | 11 | Citations (PDF) |
| 24 | Impact of the Catalyst Type and Dopant Composition on the Performance of High-Temperature PEM Fuel Cell | 0.0 | 1 | Citations (PDF) |
| 25 | A Deeper Insight into Stability of Pt-Alloy Nanoparticles as Oxygen Reduction Reaction Electrocatalysts | 0.0 | 0 | Citations (PDF) |
| 26 | Suppressing Platinum Electrocatalyst Degradation via a High-Surface-Area Organic Matrix Support | 4.3 | 8 | Citations (PDF) |
| 27 | Inter‐relationships between Oxygen Evolution and Iridium Dissolution Mechanisms | 1.4 | 2 | Citations (PDF) |
| 28 | Inter‐relationships between Oxygen Evolution and Iridium Dissolution Mechanisms | 14.1 | 148 | Citations (PDF) |
| 29 | Understanding the Crucial Significance of the Temperature and Potential Window on the Stability of Carbon Supported Pt-Alloy Nanoparticles as Oxygen Reduction Reaction Electrocatalysts | 12.9 | 70 | Citations (PDF) |
| 30 | Bringing into play automated electron microscopy data processing for understanding nanoparticulate electrocatalysts’ structure–property relationships | 4.4 | 9 | Citations (PDF) |
| 31 | Importance of Chemical Activation and the Effect of Low Operation Voltage on the Performance of Pt-Alloy Fuel Cell Electrocatalysts | 5.4 | 35 | Citations (PDF) |
| 32 | Microstructure and Electrical Conductivity of Electrospun Titanium Oxynitride Carbon Composite Nanofibers | 4.1 | 8 | Citations (PDF) |
| 33 | Atomically-resolved structural changes of ceramic supported nanoparticulate oxygen evolution reaction Ir catalyst | 5.3 | 10 | Citations (PDF) |
| 34 | Graphene-Derived Carbon Support Boosts Proton Exchange Membrane Fuel Cell Catalyst Stability | 12.9 | 34 | Citations (PDF) |
| 35 | Supported Iridium‐based Oxygen Evolution Reaction Electrocatalysts ‐ Recent Developments | 3.5 | 53 | Citations (PDF) |
| 36 | Improving the HER Activity and Stability of Pt Nanoparticles by Titanium Oxynitride Support | 12.9 | 141 | Citations (PDF) |
| 37 | Electrochemically-grown Chloride-free Cu2O nanocubes favorably electroreduce CO2 to Methane: The interplay of appropriate electrochemical protocol | 5.3 | 16 | Citations (PDF) |
| 38 | Stability challenges of carbon-supported Pt-nanoalloys as fuel cell oxygen reduction reaction electrocatalysts | 3.9 | 42 | Citations (PDF) |
| 39 | Iridium Stabilizes Ceramic Titanium Oxynitride Support for Oxygen Evolution Reaction | 12.9 | 14 | Citations (PDF) |
| 40 | Electrochemical Stability and Degradation Mechanisms of Commercial Carbon-Supported Gold Nanoparticles in Acidic Media | 3.1 | 25 | Citations (PDF) |
| 41 | Resolving the nanoparticles' structure-property relationships at the atomic level: a study of Pt-based electrocatalysts | 3.7 | 79 | Citations (PDF) |
| 42 | Reconstruction of Copper Nanoparticles at Electrochemical CO<sub>2</sub> Reduction Reaction Conditions Occurs <i>via</i> Two‐step Dissolution/Redeposition Mechanism | 2.9 | 51 | Citations (PDF) |
| 43 | High-surface-area organic matrix tris(aza)pentacene supported platinum nanostructures as selective electrocatalyst for hydrogen oxidation/evolution reaction and suppressive for oxygen reduction reaction | 9.1 | 6 | Citations (PDF) |
| 44 | Electrocatalytic effects of Pt-based nanoparticles studied with advanced identical location electron microscopy | 0.5 | 0 | Citations (PDF) |
| 45 | Enhancing Iridium Nanoparticles’ Oxygen Evolution Reaction Activity and Stability by Adjusting the Coverage of Titanium Oxynitride Flakes on Reduced Graphene Oxide Nanoribbons’ Support | 4.1 | 15 | Citations (PDF) |
| 46 | Observing, tracking and analysing electrochemically induced atomic-scale structural changes of an individual Pt-Co nanoparticle as a fuel cell electrocatalyst by combining modified floating electrode and identical location electron microscopy | 5.3 | 35 | Citations (PDF) |
| 47 | Sacrificial Cu Layer Mediated the Formation of an Active and Stable Supported Iridium Oxygen Evolution Reaction Electrocatalyst | 12.9 | 28 | Citations (PDF) |
| 48 | Effect of the Morphology of the High-Surface-Area Support on the Performance of the Oxygen-Evolution Reaction for Iridium Nanoparticles | 12.9 | 66 | Citations (PDF) |
| 49 | Electrochemical stability and degradation of commercial Rh/C catalyst in acidic media | 5.3 | 8 | Citations (PDF) |
| 50 | Temperature dependent model of carbon supported platinum fuel cell catalyst degradation | 8.0 | 33 | Citations (PDF) |
| 51 | Toward the Continuous Production of Multigram Quantities of Highly Uniform Supported Metallic Nanoparticles and Their Application for Synthesis of Superior Intermetallic Pt-Alloy ORR Electrocatalysts | 5.4 | 29 | Citations (PDF) |
| 52 | Electrochemical Stability and Degradation of Commercial Pd/C Catalyst in Acidic Media | 3.1 | 35 | Citations (PDF) |
| 53 | Increasing the Oxygen-Evolution Reaction Performance of Nanotubular Titanium Oxynitride-Supported Ir Nanoparticles by a Strong Metal–Support Interaction | 12.9 | 94 | Citations (PDF) |
| 54 | Atomistic Insights into the Stability of Pt Single-Atom Electrocatalysts | 15.1 | 113 | Citations (PDF) |
| 55 | Assembly of Pt Nanoparticles on Graphitized Carbon Nanofibers as Hierarchically Structured Electrodes | 5.3 | 15 | Citations (PDF) |
| 56 | What is the trigger for the hydrogen evolution reaction? – towards electrocatalysis beyond the Sabatier principle | 2.8 | 55 | Citations (PDF) |
| 57 | Stability and Degradation Mechanisms of Copper‐Based Catalysts for Electrochemical CO<sub>2</sub> Reduction | 1.4 | 161 | Citations (PDF) |
| 58 | Stability and Degradation Mechanisms of Copper‐Based Catalysts for Electrochemical CO<sub>2</sub> Reduction | 14.1 | 457 | Citations (PDF) |
| 59 | The Importance of Temperature and Potential Window in Stability Evaluation of Supported Pt-Based Oxygen Reduction Reaction Electrocatalysts in Thin Film Rotating Disc Electrode Setup | 3.1 | 25 | Citations (PDF) |
| 60 | Ir/TiON<sub>x</sub>/C high-performance oxygen evolution reaction nanocomposite electrocatalysts in acidic media: synthesis, characterization and electrochemical benchmarking protocol | 4.8 | 15 | Citations (PDF) |
| 61 | Modified Floating Electrode Apparatus for Advanced Characterization of Oxygen Reduction Reaction Electrocatalysts | 3.1 | 42 | Citations (PDF) |
| 62 | Controlling the radical-induced redox chemistry inside a liquid-cell TEM | 7.2 | 56 | Citations (PDF) |
| 63 | Insights into thermal annealing of highly-active PtCu3/C Oxygen Reduction Reaction electrocatalyst: An in-situ heating transmission Electron microscopy study | 16.2 | 56 | Citations (PDF) |
| 64 | Insight on Single Cell Proton Exchange Membrane Fuel Cell Performance of Pt-Cu/C Cathode | 3.8 | 17 | Citations (PDF) |
| 65 | Towards Stable and Conductive Titanium Oxynitride High‐Surface‐Area Support for Iridium Nanoparticles as Oxygen Evolution Reaction Electrocatalyst | 3.5 | 38 | Citations (PDF) |
| 66 | Synthesis and Advanced Electrochemical Characterization of Multifunctional Electrocatalytic Composite for Unitized Regenerative Fuel Cell | 12.9 | 29 | Citations (PDF) |
| 67 | Active‐Site Imprinting: Preparation of Fe–N–C Catalysts from Zinc Ion–Templated Ionothermal Nitrogen‐Doped Carbons | 22.4 | 81 | Citations (PDF) |
| 68 | A Double‐Passivation Water‐Based Galvanic Displacement Method for Reproducible Gram‐Scale Production of High‐Performance Platinum‐Alloy Electrocatalysts | 1.4 | 18 | Citations (PDF) |
| 69 | A Double‐Passivation Water‐Based Galvanic Displacement Method for Reproducible Gram‐Scale Production of High‐Performance Platinum‐Alloy Electrocatalysts | 14.1 | 36 | Citations (PDF) |
| 70 | Comparison of Pt–Cu/C with Benchmark Pt–Co/C: Metal Dissolution and Their Surface Interactions | 5.4 | 77 | Citations (PDF) |
| 71 | Spot the difference at the nanoscale: identical location electron microscopy in electrocatalysis | 4.4 | 67 | Citations (PDF) |
| 72 | CO-assisted ex-situ chemical activation of Pt-Cu/C oxygen reduction reaction electrocatalyst | 5.3 | 46 | Citations (PDF) |
| 73 | Effect of Particle Size on the Corrosion Behaviour of Gold in the Presence of Chloride Impurities: An EFC-ICP-MS Potentiodynamic Study | 2.6 | 20 | Citations (PDF) |
| 74 | Atomic Scale Insights into Electrochemical Dissolution of Janus Pt–SnO<sub>2</sub> Nanoparticles in the Presence of Ethanol in Acidic Media: An IL-STEM and EFC–ICP–MS Study | 3.1 | 17 | Citations (PDF) |
| 75 | Cutting the Gordian Knot of electrodeposition via controlled cathodic corrosion enabling the production of supported metal nanoparticles below 5 nm | 20.5 | 34 | Citations (PDF) |
| 76 | In situ electrochemical dissolution of platinum and gold in organic-based solvent | 6.6 | 14 | Citations (PDF) |
| 77 | Platinum Dissolution and Redeposition from Pt/C Fuel Cell Electrocatalyst at Potential Cycling | 3.1 | 101 | Citations (PDF) |
| 78 | Solid oxide fuel cells fed with dry ethanol: The effect of a perovskite protective anodic layer containing dispersed Ni-alloy @ FeOx core-shell nanoparticles | 20.5 | 77 | Citations (PDF) |
| 79 | Successful Synthesis of Gold Nanoparticles through Ultrasonic Spray Pyrolysis from a Gold(III) Nitrate Precursor and Their Interaction with a High Electron Beam | 2.6 | 42 | Citations (PDF) |
| 80 | Stability study of silver nanoparticles towards the halide electroreduction | 5.3 | 17 | Citations (PDF) |
| 81 | Corrosion Protection of Platinum-Based Electrocatalyst by Ruthenium Surface Decoration | 5.4 | 6 | Citations (PDF) |
| 82 | Insights into electrochemical dealloying of Cu out of Au-doped Pt-alloy nanoparticles at the sub-nano-scale | 4.7 | 13 | Citations (PDF) |
| 83 | Gold Doping in PtCu<sub>3</sub>/HSAC Nanoparticles and Their Morphological, Structural, and Compositional Changes during Oxygen Reduction Reaction Electrochemical Cycling | 3.5 | 12 | Citations (PDF) |
| 84 | New insights into the stability of a high performance nanostructured catalyst for sustainable water electrolysis | 16.2 | 159 | Citations (PDF) |
| 85 | Importance of non-intrinsic platinum dissolution in Pt/C composite fuel cell catalysts | 2.8 | 50 | Citations (PDF) |
| 86 | Increase of electrodeposited catalyst stability via plasma grown vertically oriented graphene nanoparticle movement restriction | 3.9 | 16 | Citations (PDF) |
| 87 | Electrochemical Dissolution of Iridium and Iridium Oxide Particles in Acidic Media: Transmission Electron Microscopy, Electrochemical Flow Cell Coupled to Inductively Coupled Plasma Mass Spectrometry, and X-ray Absorption Spectroscopy Study | 15.1 | 238 | Citations (PDF) |
| 88 | Atomically Resolved Dealloying of Structurally Ordered Pt Nanoalloy as an Oxygen Reduction Reaction Electrocatalyst | 12.9 | 77 | Citations (PDF) |
| 89 | Potentiodynamic dissolution study of PtRu/C electrocatalyst in the presence of methanol | 5.3 | 43 | Citations (PDF) |
| 90 | Electrochemical in-situ dissolution study of structurally ordered, disordered and gold doped PtCu3 nanoparticles on carbon composites | 8.0 | 34 | Citations (PDF) |
| 91 | Importance and Challenges of Electrochemical <i>in Situ</i> Liquid Cell Electron Microscopy for Energy Conversion Research | 16.7 | 239 | Citations (PDF) |
| 92 | Platinum recycling going green via induced surface potential alteration enabling fast and efficient dissolution | 13.9 | 70 | Citations (PDF) |
| 93 | Structure–Activity–Stability Relationships for Space-Confined Pt<sub><i>x</i></sub>Ni<sub><i>y</i></sub> Nanoparticles in the Oxygen Reduction Reaction | 12.9 | 65 | Citations (PDF) |
| 94 | Multielectrode Teflon electrochemical nanocatalyst investigation system | 1.7 | 0 | Citations (PDF) |
| 95 | Evaluation of Oxygen Reduction Activity of Non-Ideal Pt Based Catalyst Thin Films | 0.5 | 1 | Citations (PDF) |
| 96 | Stability of Dealloyed Porous Pt/Ni Nanoparticles | 12.9 | 129 | Citations (PDF) |
| 97 | New Insights into Corrosion of Ruthenium and Ruthenium Oxide Nanoparticles in Acidic Media | 3.1 | 248 | Citations (PDF) |
| 98 | Dissolution of Platinum in the Operational Range of Fuel Cells | 2.9 | 181 | Citations (PDF) |
| 99 | Activation of carbon-supported catalysts by ozonized acidic solutions for the direct implementation in (electro-)chemical reactors | 3.9 | 14 | Citations (PDF) |
| 100 | SEM method for direct visual tracking of nanoscale morphological changes of platinum based electrocatalysts on fixed locations upon electrochemical or thermal treatments | 2.2 | 36 | Citations (PDF) |
| 101 | New Insight into Platinum Dissolution from Nanoparticulate Platinum‐Based Electrocatalysts Using Highly Sensitive In Situ Concentration Measurements | 3.5 | 125 | Citations (PDF) |
| 102 | A highly active PtCu<sub>3</sub> intermetallic core–shell, multilayered Pt-skin, carbon embedded electrocatalyst produced by a scale-up sol–gel synthesis | 3.9 | 87 | Citations (PDF) |
| 103 | The influence of chloride impurities on Pt/C fuel cell catalyst corrosion | 3.9 | 81 | Citations (PDF) |
| 104 | Effect of ordering of PtCu<sub>3</sub>nanoparticle structure on the activity and stability for the oxygen reduction reaction | 2.8 | 138 | Citations (PDF) |
| 105 | In-situ TEM and Atomic-Resolution STEM Study of Highly Active Partially Ordered Cu3Pt Nanoparticles used as PEM-Fuel Cells Catalyst | 0.5 | 0 | Citations (PDF) |
| 106 | Time Evolution of the Stability and Oxygen Reduction Reaction Activity of PtCu/C Nanoparticles | 3.5 | 32 | Citations (PDF) |
| 107 | Severe accelerated degradation of PEMFC platinum catalyst: A thin film IL-SEM study | 3.9 | 65 | Citations (PDF) |
| 108 | New Pt-skin electrocatalysts for oxygen reduction and methanol oxidation reactions | 3.9 | 40 | Citations (PDF) |
| 109 | Identical Location Scanning Electron Microscopy: A Case Study of Electrochemical Degradation of PtNi Nanoparticles Using a New Nondestructive Method | 3.1 | 71 | Citations (PDF) |
| 110 | Enhanced Oxygen Reduction and Methanol Oxidation Reaction Activities of Partially Ordered PtCu Nanoparticles | 2.2 | 25 | Citations (PDF) |
| 111 | Novel Method for Fast Characterization of High-Surface-Area Electrocatalytic Materials Using a Carbon Fiber Microelectrode | 3.1 | 11 | Citations (PDF) |
| 112 | Kemija na električni pogon (in obratno) | 0.0 | 0 | Citations (PDF) |
| 113 | Reduced graphene oxide as efficient carbon support for Pd-based ethanol oxidation catalysts in alkaline media | 4.7 | 0 | Citations (PDF) |
