Her primary areas of study are Graphene, Nanotechnology, Transmission electron microscopy, Chemical physics and High-resolution transmission electron microscopy. Her research in Graphene intersects with topics in Monolayer, Atom, Graphite, Carbon and Electron. Ute Kaiser has researched Nanotechnology in several fields, including Atomic units and Amorphous carbon.
Her Transmission electron microscopy study incorporates themes from Oxide, Analytical chemistry, Crystallite, Thin film and Electronic structure. Her biological study spans a wide range of topics, including Amorphous solid, Bilayer, Tetragonal crystal system and Nucleation. Her research in High-resolution transmission electron microscopy focuses on subjects like Molecular physics, which are connected to Electron beam processing.
Ute Kaiser focuses on Transmission electron microscopy, Graphene, Nanotechnology, Optoelectronics and High-resolution transmission electron microscopy. Ute Kaiser combines subjects such as Chemical physics, Crystallography, Crystal, Molecular physics and Analytical chemistry with her study of Transmission electron microscopy. Her Graphene study combines topics from a wide range of disciplines, such as Atom, Monolayer, Oxide and Carbon.
Ute Kaiser regularly ties together related areas like Graphite in her Nanotechnology studies. Her biological study deals with issues like Sapphire, which deal with fields such as Metalorganic vapour phase epitaxy. Her High-resolution transmission electron microscopy study improves the overall literature in Optics.
Ute Kaiser mainly focuses on Graphene, Transmission electron microscopy, Carbon nanotube, Lithium and Anode. Her studies in Graphene integrate themes in fields like Band gap, Monolayer, Oxide and Permeation. Her Transmission electron microscopy study focuses on High-resolution transmission electron microscopy in particular.
Her research investigates the connection with Carbon nanotube and areas like Molecule which intersect with concerns in Fullerene and Dissociation. Ute Kaiser interconnects Electrolyte, Electrode, Cathode and Doping in the investigation of issues within Lithium. Graphene nanoribbons is a subfield of Nanotechnology that Ute Kaiser tackles.
Her scientific interests lie mostly in Transmission electron microscopy, Anode, Graphene, Cathode and Crystallinity. Her Transmission electron microscopy research is multidisciplinary, relying on both Computational physics, Scattering, Phase contrast microscopy and Electron, Cathode ray. The various areas that she examines in her Graphene study include Monolayer, Chemical vapor deposition and Graphite.
In Chemical vapor deposition, Ute Kaiser works on issues like Transition metal, which are connected to High-resolution transmission electron microscopy and Vanadium. Her Crystallinity research incorporates themes from Thin film, Nanotechnology, Polymerization, Polymer and Porphyrin. The Dna nanostructures research Ute Kaiser does as part of her general Nanotechnology study is frequently linked to other disciplines of science, such as Structural biology, therefore creating a link between diverse domains of science.
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Atomic Structure of Reduced Graphene Oxide
Cristina Gómez-Navarro;Cristina Gómez-Navarro;Jannik C. Meyer;Ravi S. Sundaram;Andrey Chuvilin.
Nano Letters (2010)
Two-dimensional transition metal dichalcogenides under electron irradiation: defect production and doping.
Hannu-Pekka Komsa;Jani Kotakoski;Jani Kotakoski;Simon Kurasch;Ossi Lehtinen.
Physical Review Letters (2012)
From point defects in graphene to two-dimensional amorphous carbon.
J. Kotakoski;A. V. Krasheninnikov;A. V. Krasheninnikov;U. Kaiser;J. C. Meyer.
Physical Review Letters (2011)
Square ice in graphene nanocapillaries
G Algara-Siller;O Lehtinen;F C Wang;Rahul Raveendran Nair.
Selective sputtering and atomic resolution imaging of atomically thin boron nitride membranes.
Jannik C. Meyer;Andrey Chuvilin;Gerardo Algara-Siller;Johannes Biskupek.
Nano Letters (2009)
High surface area crystalline titanium dioxide: potential and limits in electrochemical energy storage and catalysis
Thomas Maro Fröschl;U Hörmann;P Kubiak;G Kucerova.
Chemical Society Reviews (2012)
Triazine‐Based Graphitic Carbon Nitride: a Two‐Dimensional Semiconductor
Gerardo Algara-Siller;Nikolai Severin;Samantha Y. Chong;Torbjorn Bjorkman.
Angewandte Chemie (2014)
Accurate measurement of electron beam induced displacement cross sections for single-layer graphene.
Jannik C. Meyer;Jannik C. Meyer;Franz Eder;Simon Kurasch;Viera Skakalova;Viera Skakalova.
Physical Review Letters (2012)
3D imaging of nanomaterials by discrete tomography.
K.J. Batenburg;S. Bals;J. Sijbers;C. Kübel.
Direct transformation of graphene to fullerene
Andrey Chuvilin;Andrey Chuvilin;Ute Kaiser;Elena Bichoutskaia;Nicholas A. Besley.
Nature Chemistry (2010)
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