Chaotic Dirac Billiard in Graphene Quantum Dots
- 18 April 2008
- journal article
- other
- Published by American Association for the Advancement of Science (AAAS) in Science
- Vol. 320 (5874), 356-358
- https://doi.org/10.1126/science.1154663
Abstract
The exceptional electronic properties of graphene, with its charge carriers mimicking relativistic quantum particles and its formidable potential in various applications, have ensured a rapid growth of interest in this new material. We report on electron transport in quantum dot devices carved entirely from graphene. At large sizes (>100 nanometers), they behave as conventional single-electron transistors, exhibiting periodic Coulomb blockade peaks. For quantum dots smaller than 100 nanometers, the peaks become strongly nonperiodic, indicating a major contribution of quantum confinement. Random peak spacing and its statistics are well described by the theory of chaotic neutrino billiards. Short constrictions of only a few nanometers in width remain conductive and reveal a confinement gap of up to 0.5 electron volt, demonstrating the possibility of molecular-scale electronics based on graphene.This publication has 25 references indexed in Scilit:
- Quasiparticle Energies and Band Gaps in Graphene NanoribbonsPhysical Review Letters, 2007
- Coulomb Blockade in Graphene NanoribbonsPhysical Review Letters, 2007
- Phase-Coherent Transport in Graphene Quantum BilliardsScience, 2007
- Energy Band-Gap Engineering of Graphene NanoribbonsPhysical Review Letters, 2007
- The rise of grapheneNature Materials, 2007
- Quantum Dots in GraphenePhysical Review Letters, 2007
- Electronic Structure and Stability of Semiconducting Graphene NanoribbonsNano Letters, 2006
- Half-metallic graphene nanoribbonsNature, 2006
- Coulomb Oscillations and Hall Effect in Quasi-2D Graphite Quantum DotsNano Letters, 2005
- Mesoscopic Fluctuations in the Ground State Energy of Disordered Quantum DotsPhysical Review Letters, 1996