Design of Bimetallic 3D-printed Electrocatalysts via Galvanic Replacement to Enhance Energy Conversion Systems

[1]  Jenghan Wang,et al.  Stable Pd-Cu Hydride Catalyst for Efficient Hydrogen Evolution. , 2022, Nano letters.

[2]  M. Pumera,et al.  Fully metallic copper 3D-printed electrodes via sintering for electrocatalytic biosensing , 2021, Applied Materials Today.

[3]  M. Kaya,et al.  Electrodeposition of NiCu bimetal on 3D printed electrodes for hydrogen evolution reactions in alkaline media , 2021, International Journal of Hydrogen Energy.

[4]  M. Pumera,et al.  Versatile Design of Functional Organic-Inorganic 3D-Printed (Opto)Electronic Interfaces with Custom Catalytic Activity. , 2021, Small.

[5]  Dingsheng Wang,et al.  Design concept for electrocatalysts , 2021, Nano Research.

[6]  Zhen Chen,et al.  Alloying effect-induced electron polarization drives nitrate electroreduction to ammonia , 2021, Chem Catalysis.

[7]  M. Pumera,et al.  3D-Printed COVID-19 immunosensors with electronic readout , 2021, Chemical Engineering Journal.

[8]  M. Pumera,et al.  3D Printing Temperature Tailors Electrical and Electrochemical Properties through Changing Inner Distribution of Graphite/Polymer. , 2021, Small.

[9]  M. Pumera,et al.  Green activation using reducing agents of carbon-based 3D printed electrodes: Turning good electrodes to great , 2021 .

[10]  M. Pumera,et al.  Local electrochemical activity of transition metal dichalcogenides and their heterojunctions on 3D-printed nanocarbon surfaces. , 2021, Nanoscale.

[11]  M. Pumera,et al.  MXene-functionalised 3D-printed electrodes for electrochemical capacitors , 2021 .

[12]  M. Pumera,et al.  Chiral 3D‐printed Bioelectrodes , 2021, Advanced Functional Materials.

[13]  B. Jia,et al.  Recent Progress of Vacancy Engineering for Electrochemical Energy Conversion Related Applications , 2020, Advanced Functional Materials.

[14]  Zachary D. Hood,et al.  PdPt-TiO2 nanowires: correlating composition, electronic effects and O-vacancies with activities towards water splitting and oxygen reduction , 2020 .

[15]  S. Kundu,et al.  Investigation on nanostructured Cu-based electrocatalysts for improvising water splitting: a review , 2020 .

[16]  F. Paolucci,et al.  Carbon supported noble metal nanoparticles as efficient catalysts for electrochemical water splitting. , 2020, Nanoscale.

[17]  M. Pumera,et al.  Catalyst coating of 3D printed structures via electrochemical deposition: Case of the transition metal chalcogenide MoSx for hydrogen evolution reaction , 2020 .

[18]  M. Pumera,et al.  Accounts in 3D‐Printed Electrochemical Sensors: Towards Monitoring of Environmental Pollutants , 2020 .

[19]  T. Matsue,et al.  Recent advances in scanning electrochemical microscopic analysis and visualization on lithium-ion battery electrodes , 2020 .

[20]  Martin Pumera,et al.  3D-printed biosensors for electrochemical and optical applications , 2020 .

[21]  Huaping Zhao,et al.  3D Nanostructures for the Next Generation of High‐Performance Nanodevices for Electrochemical Energy Conversion and Storage , 2020, Advanced Energy Materials.

[22]  Lai-fei Cheng,et al.  3D printing of structured electrodes for rechargeable batteries , 2020 .

[23]  Saurav Goel,et al.  Fused deposition modeling-based additive manufacturing (3D printing): techniques for polymer material systems , 2020, Materials Today Chemistry.

[24]  K. Varadarajan,et al.  Microarchitected 3D printed polylactic acid (PLA) nanocomposite scaffolds for biomedical applications. , 2020, Journal of the mechanical behavior of biomedical materials.

[25]  Jiaguo Yu,et al.  3D Graphene‐Based H2‐Production Photocatalyst and Electrocatalyst , 2020, Advanced Energy Materials.

[26]  Martin Pumera,et al.  3D Printing for Electrochemical Energy Applications. , 2020, Chemical reviews.

[27]  Shaojun Guo,et al.  Recent Advances on Water‐Splitting Electrocatalysis Mediated by Noble‐Metal‐Based Nanostructured Materials , 2020, Advanced Energy Materials.

[28]  V. Shestivska,et al.  Copper electroplating of 3D printed composite electrodes , 2020 .

[29]  R. Deivanayagam,et al.  3D Printing of Electrochemical Energy Storage Devices: A Review of Printing Techniques and Electrode/Electrolyte Architectures , 2020 .

[30]  R. Srivastava,et al.  Experimental investigation and optimization of FDM process parameters for material and mechanical strength , 2020 .

[31]  Huakun Liu,et al.  General π-electron-assisted strategy for constructing transition metal single-atom electrocatalysts with bi-functional active sites toward highly efficient water splitting. , 2019, Angewandte Chemie.

[32]  Xiaoming Sun,et al.  Recent progress on earth abundant electrocatalysts for hydrogen evolution reaction (HER) in alkaline medium to achieve efficient water splitting – A review , 2019, Journal of Energy Chemistry.

[33]  Wei Zhang,et al.  Exposing Cu-Rich {110} Active Facets in PtCu nanostars for boosting electrochemical performance toward multiple liquid fuels electrooxidation , 2019, Nano Research.

[34]  W. Robl,et al.  Material contrast studies of conductive thin films on semiconductor substrates using scanning electrochemical microscopy , 2019, Journal of Applied Electrochemistry.

[35]  Z. Wen,et al.  Recent advances in precious metal-free bifunctional catalysts for electrochemical conversion systems , 2019, Journal of Materials Chemistry A.

[36]  Yi Ding,et al.  Bimodal nanoporous Pd3Cu1 alloy with restrained hydrogen evolution for stable and high yield electrochemical nitrogen reduction , 2019, Nano Energy.

[37]  Zengguang Liu,et al.  A critical review of fused deposition modeling 3D printing technology in manufacturing polylactic acid parts , 2019, The International Journal of Advanced Manufacturing Technology.

[38]  M. Armbrüster,et al.  Electrochemical Energy Conversion on Intermetallic Compounds: A Review , 2019, ACS Catalysis.

[39]  Rohaizan Ramlan,et al.  An Overview on 3D Printing Technology: Technological, Materials, and Applications , 2019, Procedia Manufacturing.

[40]  A. Sarkar,et al.  Estimating surface area of copper powder: A comparison between electrochemical, microscopy and laser diffraction methods , 2018, Advanced Powder Technology.

[41]  Martin Pumera,et al.  3D Printed Graphene Electrodes' Electrochemical Activation. , 2018, ACS applied materials & interfaces.

[42]  L. Gu,et al.  Dendritic defect-rich palladium–copper–cobalt nanoalloys as robust multifunctional non-platinum electrocatalysts for fuel cells , 2018, Nature Communications.

[43]  A. Kashani,et al.  Additive manufacturing (3D printing): A review of materials, methods, applications and challenges , 2018, Composites Part B: Engineering.

[44]  Mohd Adzir Mahdi,et al.  Three-Dimensional Printed Electrode and Its Novel Applications in Electronic Devices , 2018, Scientific Reports.

[45]  Martin Pumera,et al.  3D-Printed Graphene/Polylactic Acid Electrodes Promise High Sensitivity in Electroanalysis. , 2018, Analytical chemistry.

[46]  Mireia Baeza,et al.  Trends in electrochemical impedance spectroscopy involving nanocomposite transducers: Characterization, architecture surface and bio-sensing , 2017 .

[47]  Chee Kai Chua,et al.  Emerging 3D‐Printed Electrochemical Energy Storage Devices: A Critical Review , 2017 .

[48]  Nathan S. Lewis,et al.  Machine-Learning Methods Enable Exhaustive Searches for Active Bimetallic Facets and Reveal Active Site Motifs for CO2 Reduction , 2017 .

[49]  Joshua M. Pearce,et al.  Thermal properties of 3-D printed polylactic acid-metal composites , 2017 .

[50]  M. Prato,et al.  Co-axial heterostructures integrating palladium/titanium dioxide with carbon nanotubes for efficient electrocatalytic hydrogen evolution , 2016, Nature Communications.

[51]  Martin Pumera,et al.  3D-printing technologies for electrochemical applications. , 2016, Chemical Society reviews.

[52]  M. Rezaei,et al.  Galvanic replacement of electrodeposited nickel by palladium and investigation of the electrocatalytic activity of synthesized Pd/(Ni) for hydrogen evolution and formic acid oxidation , 2016 .

[53]  Junfeng Zhai,et al.  Pd–Cu/C electrocatalysts synthesized by one-pot polyol reduction toward formic acid oxidation: Structural characterization and electrocatalytic performance , 2015 .

[54]  W. Goddard,et al.  DFT Prediction of Oxygen Reduction Reaction on Palladium–Copper Alloy Surfaces , 2014 .

[55]  J. Raoof,et al.  One-step electroless deposition of Pd/Pt bimetallic microstructures by galvanic replacement on copper substrate and investigation of its performance for the hydrogen evolution reaction , 2013 .

[56]  C. Lefrou,et al.  Analytical expressions for quantitative scanning electrochemical microscopy (SECM). , 2010, Chemphyschem : a European journal of chemical physics and physical chemistry.

[57]  W. Schuhmann,et al.  Alternating current techniques in scanning electrochemical microscopy (AC-SECM). , 2008, The Analyst.

[58]  Jin-Song Hu,et al.  Nanostructured Materials for Electrochemical Energy Conversion and Storage Devices , 2008 .

[59]  W. Schuhmann,et al.  Localised visualisation of O2 consumption and H2O2 formation by means of SECM for the characterisation of fuel cell catalyst activity , 2007 .

[60]  L. Zhuang,et al.  First-principles considerations in the design of Pd-alloy catalysts for oxygen reduction. , 2007, Angewandte Chemie.

[61]  H. Sakata,et al.  Copper (II) oxide as a giant dielectric material , 2006 .

[62]  W. Schuhmann,et al.  Redox competition mode of scanning electrochemical microscopy (RC-SECM) for visualisation of local catalytic activity. , 2006, Physical chemistry chemical physics : PCCP.

[63]  A. Heller,et al.  Scanning electrochemical microscopy. 24. Enzyme ultramicroelectrodes for the measurement of hydrogen peroxide at surfaces. , 1993, Analytical chemistry.

[64]  A. Bard,et al.  Chemical Imaging of Surfaces with the Scanning Electrochemical Microscope , 1991, Science.