|![[Search]](https://talks.cam.ac.uk/images/search.gif?1209136071)
|![[A-Z Index]](https://talks.cam.ac.uk/images/az.gif?1209136071)
|![[Contact]](https://talks.cam.ac.uk/images/contact.gif?1209136071)
||![[University of Cambridge]](https://talks.cam.ac.uk/images/identifier2.gif?1209136071){kind=small} |
COOKIES: By using this website you agree that we can place Google Analytics Cookies on your device for performance monitoring. | ![[Talks.cam]](https://talks.cam.ac.uk/images/talkslogosmall.gif?1209136071) |
University of Cambridge > Talks.cam > Theory of Condensed Matter > Tuning the Electronic Phases of Graphene Nanoribbons
Tuning the Electronic Phases of Graphene NanoribbonsAdd to your list(s) Download to your calendar using vCal
If you have a question about this talk, please contact Bo Peng. Graphene nanoribbons (GNRs) are a fascinating class of quasi-one-dimensional semiconductors consisting of nanometer-wide strips of hexagonally bonded carbon atoms [1]. Recent advancements in fabrication techniques enabled the realization of atomically precise GNRs with diverse edge geometries, widths, and complex nanoarchitectures [2]. In this talk, I will present graphene nanoribbons as a promising platform for controlling and manipulating unconventional electronic phases, drawing from both ab initio and model Hamiltonian calculations. First, I will explore the emergence of topological phases in armchair-edged nanoribbons induced by lattice deformations [3]. Second, I will demonstrate the formation of half-semi metallic phases in zigzag-edged nanoribbons upon incorporation into a lateral heterostructure [4, 5]. Third, I will discuss the development of ultra-flat bands and π-electron magnetism in chevron-edged graphene nanoribbons under an external electric field [6]. These findings may open new possibilities for engineering quantum phases in one-dimensional crystals, with potential applications in spintronics and related device concepts. [1] O. V. Yazyev, Account of Chemical Research 46, 2319 (2013). [2] A. Narita, K. Müllen, Advanced Materials 32, 2001893 (2020). [3] N. V. Tepliakov, J, Lischner, E. Kaxiras, A. A. Mostofi, M. Pizzochero, Physical Review Letters 130, 026401 (2023). [4] N. V. Tepliakov, R. Ma, J. Lischner, E. Kaxiras, A. A. Mostofi, M. Pizzochero, Nano Letters 23, 6698 (2024). [5] M. Pizzochero, N. V. Tepliakov, J. Lischner, A. A. Mostofi, E. Kaxiras, Nano Letters 24, 6521 (2024). [6] R. Ma, N. V. Tepliakov, A. A. Mostofi, M. Pizzochero, in preparation. This talk is part of the Theory of Condensed Matter series. This talk is included in these lists:
Note that ex-directory lists are not shown. |
Other listsld636 China Research Seminar Series Centre for Neuroscience in EducationOther talksBulk deviations for the simple random walk Cambridge RNA Club - IN PERSON Engineering large, multipurpose microprocessor specifications (using the x86-64 architecture as a case study) Simple and multiple linear regression Coproduction of Mathematical Models Introductions |
Thursday 31 October 2024, 14:00-15:30