Theory of bilayer graphene spectroscopy

Author(s)

    • Mucha-Kruczyński, Marcin

Bibliographic Information

Theory of bilayer graphene spectroscopy

Marcin Mucha-Kruczyński

(Springer theses : recognizing outstanding Ph. D. research)

Springer, c2013

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"Doctoral thesis accepted by the University of Lancaster, UK"

Includes bibliographical references and index

Description and Table of Contents

Description

This thesis presents the theory of three key elements of optical spectroscopy of the electronic excitations in bilayer graphene: angle-resolved photoemission spectroscopy (ARPES), visible range Raman spectroscopy, and far-infrared (FIR) magneto-spectroscopy. Bilayer graphene (BLG) is an atomic two-dimensional crystal consisting of two honeycomb monolayers of carbon, arranged according to Bernal stacking. The unperturbed BLG has a unique band structure, which features chiral states of electrons with a characteristic Berry phase of 2$\pi$, and it has versatile properties which can be controlled by an externally applied transverse electric field and strain. It is shown in this work how ARPES of BLG can be used to obtain direct information about the chirality of electron states in the crystal. The author goes on to describe the influence of the interlayer asymmetry, which opens a gap in BLG, on ARPES and on FIR spectra in a strong magnetic field. Finally, he presents a comprehensive theory of inelastic Raman scattering resulting in the electron-hole excitations in bilayer graphene, at zero and quantizing magnetic fields. This predicts their polarization properties and peculiar selection rules in terms of the inter-Landau-level transitions.

Table of Contents

The Tight-Binding Approach and the Resulting Electronic Structure.- Angle-Resolved Photoemission Spectroscopy.- Magneto-Optical Spectroscopy.- Electronic Raman Spectroscopy.

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