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Speaker-Vladimir Falko

Vladimir Falko
The University of Manchester, UK
Vladimir Falko is Director of the National Graphene Institute and Professor of Condensed Matter Theory at the University of Manchester. His career started with the PhD at the Institute for Solid State Physics RAS, followed by postdoctoral experience at Max-Planck-Institute in Stuttgart and Oxford University, and 19 years of service at Lancaster University. Falkowas responsible formany advances in the theory of localisation and quantum transport in mesoscopic systems,andhe made substantial contributions towards understanding of electronic and optical properties of graphene, including discovery of bilayer graphene.His current research interests include modelling of graphene-based electronic and optoelectronic systems and development of theories of electronic and optical properties of various atomically thin two-dimensional crystals and their heterostructures. His career has been marked by Humboldt Fellowship, EPSC Advanced Fellowship, ERC Advanced Investigator and Synergy Grants, and Royal Society Wolfson Foundation Research Merit Award.Falko played a pivotal role in building up the European research community in graphene and two-dimensional materials by setting the ‘Graphene Week’ conference series and by being one of the organisers and leaders of the European Graphene Flagship Project. From 2014, he is the founding Editor-in-Chief of the IoP Journal ‘2D Materials’ (with 2016 IF of 9.6).
Title:Ballistic electronic devices based on hBN-encapsulated graphene
SymposiumPlenary Lectures
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Abstract

The talk will review the extremes electronic properties of graphene (G) encapsulated between layers of hexagonal boron nitride (hBN) and device concepts enabled by the high quality of this material. Encapsulation in hBN enables us to achieve a micron-length collision-less propagation of electrons in graphene, whereas technology of making low-resistance edge-contacts with normal and superconducting opens ways to manufacture ballistic electronic devices: electronic lenses and focusing beam splitters, as well as superconducting proximity effect transistors and interferometers. Moreover, electrostatic gating of hBN-G-hBN structures permits to open a large and spatially modulated band gap in bilayer graphene, hence offering new routes towards creating quantum wires, dots, and their various circuits. We shall discuss vertical tunnelling in hBN-G-hBN-G-hBNtunnelling field effect transistors with highly aligned graphene electrodes, where we were able to show resonance tunnelling of ballistic electrons. We shall also discuss extreme physics realised in the highly aligned G-hBN heterostructures, where the long mean free path of carriers enables one to observe the formation of minibands due moiré superlattice determined by the incommensurability of G and hBN crystals, which in strong magnetic field takes the extreme form of a fractal spectrum of Brown-Zak magnetic minibands (also known as Hofstadter’s butterfly).

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Abstract: Minyang Lu

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Media: Liping Wang

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