Martin Pumera chimiste tchèque
Pumera, Martin, 1974-
Pumera, Martin
VIAF ID: 310618277 (Personal)
Permalink: http://viaf.org/viaf/310618277
Preferred Forms
- 100 0 _ ‡a Martin Pumera ‡c chimiste tchèque
- 100 1 _ ‡a Pumera, Martin
- 100 1 _ ‡a Pumera, Martin
- 100 1 _ ‡a Pumera, Martin ‡d 1974-
-
4xx's: Alternate Name Forms (6)
5xx's: Related Names (1)
Works
Title | Sources |
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Matériaux multifonctionnels à base de liquides ioniques à tâches spécifiques : de l’étude fondamentale à la nouvelle génération de dispositifs électrochimiques et de peau artificielle. | |
Multifunctional materials based on task-specific ionic liquids : from fundamental to next generation of hybrid electrochemical devices and artifical skin | |
Nanomaterials for electrochemical sensing and biosensing, 2014: | |
The reduction of graphene oxide with hydrazine: elucidating its reductive capability based on a reaction-model approach. | |
Refinements to the structure of graphite oxide: absolute quantification of functional groups via selective labelling | |
Relationship between carbon nanotube structure and electrochemical behavior: heterogeneous electron transfer at electrochemically activated carbon nanotubes | |
Remarkable electrochemical properties of electrochemically reduced graphene oxide towards oxygen reduction reaction are caused by residual metal-based impurities | |
Residual metallic impurities within carbon nanotubes play a dominant role in supposedly "metal-free" oxygen reduction reactions. | |
Retraction Note: Air-stable superparamagnetic metal nanoparticles entrapped in graphene oxide matrix | |
Reynolds numbers influence the directionality of self-propelled microjet engines in the 10(-4) regime | |
The Role of the Metal Element in Layered Metal Phosphorus Triselenides upon Their Electrochemical Sensing and Energy Applications | |
Schwarzer Phosphor neu entdeckt: vom Volumenmaterial zu Monoschichten | |
Searching for magnetism in hydrogenated graphene: using highly hydrogenated graphene prepared via Birch reduction of graphite oxides. | |
Selective nitrogen functionalization of graphene by Bucherer-type reaction. | |
Selective removal of hydroxyl groups from graphene oxide | |
Self-Contained Polymer/Metal 3D Printed Electrochemical Platform for Tailored Water Splitting | |
Self-propelled autonomous nanomotors meet microfluidics | |
Self-propelled nanojets via template electrodeposition | |
Semi-conducting single-walled carbon nanotubes are detrimental when compared to metallic single-walled carbon nanotubes for electrochemical applications. | |
Signal transducers and enzyme cofactors are susceptible to oxidation by nanographite impurities in carbon nanotube materials. | |
Simple Synthesis of Fluorinated Graphene: Thermal Exfoliation of Fluorographite. | |
Simultaneous self-exfoliation and autonomous motion of MoS2 particles in water. | |
Single-Channel Microchip for Fast Screening and Detailed Identification of Nitroaromatic Explosives or Organophosphate Nerve Agents | |
Single-, few-, and multilayer graphene not exhibiting significant advantages over graphite microparticles in electroanalysis | |
Smart micro- and nanorobots for water purification | |
Smart Microdevices Laying "Breadcrumbs" to Find the Way Home: Chemotactic Homing TiO2 /Pt Janus Microrobots | |
Smartdust 3D-Printed Graphene-Based Al/Ga Robots for Photocatalytic Degradation of Explosives | |
So-Called “Metal-Free” Oxygen Reduction at Graphene Nanoribbons is in fact Metal Driven | |
Solid-state electrochemistry of graphene oxides: absolute quantification of reducible groups using voltammetry. | |
Spontaneous Coating of Carbon Nanotubes with an Ultrathin Polypyrrole Layer | |
Stacked graphene nanofibers for electrochemical oxidation of DNA bases | |
Stripping Voltammetry with Bismuth Modified Graphite-Epoxy Composite Electrodes | |
The Structural Stability of Graphene Anticorrosion Coating Materials is Compromised at Low Potentials. | |
Structure–Function Dependence on Template-Based Micromotors | |
Structures of inclusion complexes of halogenbenzoic acids and alpha-cyclodextrin based on AM1 calculations | |
Sulfur Doping Induces Strong Ferromagnetic Ordering in Graphene: Effect of Concentration and Substitution Mechanism. | |
Sulfur poisoning of emergent and current electrocatalysts: vulnerability of MoS2, and direct correlation to Pt hydrogen evolution reaction kinetics. | |
Supercapacitors in Motion: Autonomous Microswimmers for Natural-Resource Recovery | |
Surface properties of MoS2 probed by inverse gas chromatography and their impact on electrocatalytic properties. | |
Swarming Aqua Sperm Micromotors for Active Bacterial Biofilms Removal in Confined Spaces | |
Swarming Magnetic Photoactive Microrobots for Dental Implant Biofilm Eradication | |
Synergetic Metals on Carbocatalyst Shungite. | |
Synthesis of Carboxylated-Graphenes by the Kolbe-Schmitt Process. | |
Synthesis of strongly fluorescent graphene quantum dots by cage-opening buckminsterfullerene. | |
Synthetic Nanoarchitectonics of Functional Organic–Inorganic 2D Germanane Heterostructures via Click Chemistry | |
Synthetic routes contaminate graphene materials with a whole spectrum of unanticipated metallic elements | |
Tailoring capacitance of 3D-printed graphene electrodes by carbonisation temperature | |
TaS3 Nanofibers: Layered Trichalcogenide for High-Performance Electronic and Sensing Devices. | |
Thermally reduced graphenes exhibiting a close relationship to amorphous carbon. | |
Thin, High-Flux, Self-Standing, Graphene Oxide Membranes for Efficient Hydrogen Separation from Gas Mixtures. | |
Thiofluorographene-Hydrophilic Graphene Derivative with Semiconducting and Genosensing Properties | |
Thiographene synthesized from fluorographene via xanthogenate with immobilized enzymes for environmental remediation | |
Thrombin aptasensing with inherently electroactive graphene oxide nanoplatelets as labels | |
Tissue cell assisted fabrication of tubular catalytic platinum microengines. | |
Top-Down and Bottom-Up Approaches in Engineering 1 T Phase Molybdenum Disulfide (MoS2 ): Towards Highly Catalytically Active Materials. | |
Towards an Ultrasensitive Method for the Determination of Metal Impurities in Carbon Nanotubes | |
Towards Antimonene and 2D Antimony Telluride through Electrochemical Exfoliation | |
Towards biocompatible nano/microscale machines: self-propelled catalytic nanomotors not exhibiting acute toxicity | |
Towards disposable lab-on-a-chip: poly | |
Towards graphene iodide: iodination of graphite oxide | |
Towards lab-on-a-chip approaches in real analytical domains based on microfluidic chips/electrochemical multi-walled carbon nanotube platforms | |
Towards stoichiometric analogues of graphene: graphane, fluorographene, graphol, graphene acid and others | |
The toxicity of graphene oxides: dependence on the oxidative methods used. | |
Transition metal-depleted graphenes for electrochemical applications via reduction of CO₂ by lithium | |
Transition Metal Oxides for the Oxygen Reduction Reaction: Influence of the Oxidation States of the Metal and its Position on the Periodic Table. | |
Transitional Metal/Chalcogen Dependant Interactions of Hairpin DNA with Transition Metal Dichalcogenides, MX2. | |
Trends in analysis of explosives by microchip electrophoresis and conventional CE. | |
Triazine- and Heptazine-Based Carbon Nitrides: Toxicity | |
Tuning of graphene oxide composition by multiple oxidations for carbon dioxide storage and capture of toxic metals | |
Ultrafast Electrochemical Trigger Drug Delivery Mechanism for Nanographene Micromachines | |
Ultrapure Graphene Is a Poor Electrocatalyst: Definitive Proof of the Key Role of Metallic Impurities in Graphene-Based Electrocatalysis | |
Ultrathin organically modified silica layer coated carbon nanotubes: fabrication, characterization and electrical insulating properties | |
Unconventionally Layered CoTe2 and NiTe2 as Electrocatalysts for Hydrogen Evolution. | |
Universal Method for Large-Scale Synthesis of Layered Transition Metal Dichalcogenides. | |
Unscrolling of multi-walled carbon nanotubes: towards micrometre-scale graphene oxide sheets. | |
Unusual inherent electrochemistry of graphene oxides prepared using permanganate oxidants | |
Uranium- and thorium-doped graphene for efficient oxygen and hydrogen peroxide reduction | |
Valence and oxide impurities in MoS2 and WS2 dramatically change their electrocatalytic activity towards proton reduction | |
Visible-Light-Driven Single-Component BiVO4 Micromotors with the Autonomous Ability for Capturing Microorganisms | |
Voltammetry of carbon nanotubes and graphenes: excitement, disappointment, and reality. | |
Voltammetry of Layered Black Phosphorus: Electrochemistry of Multilayer Phosphorene | |
What amount of metallic impurities in carbon nanotubes is small enough not to dominate their redox properties? | |
Will Any Crap We Put into Graphene Increase Its Electrocatalytic Effect? | |
WSe2 nanoparticles with enhanced hydrogen evolution reaction prepared by bipolar electrochemistry: application in competitive magneto-immunoassay | |
ZnO/ZnO2/Pt Janus Micromotors Propulsion Mode Changes with Size and Interface Structure: Enhanced Nitroaromatic Explosives Degradation under Visible Light | |
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