What is it about?
It deals with theoretical studies aimed at new organic materials to develop more efficient miniaturized computers and nanoscale electronic devices. Zigzzag Phagraphene Nanoribbon are candidates for new applications in molecular electronics.
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Photo by Terry Vlisidis on Unsplash
Why is it important?
This study makes it possible to find new physical phenomena at the quantum level that are not dealt with at the classical level. Our findings show that electronic devices can be used as resonant tunnel diode (RTD), transistors, among others.
Perspectives
Writing this article was a great pleasure as it has co-authors with whom I have had long standing collaborations and others that started with this article as is the case Y.-P. Wang, and H.-P. Cheng. I highlight new calculations and codes to new devices design in the area of information technology, telecommunications, electronics, among other areas. I hope this article makes what people might think is a boring, slightly area. More than anything else, and if nothing else, I hope you find this article thought-provoking.
Prof. Dr. Carlos Alberto Brito da Silva Jr.
Universidade Federal do Para
Read the Original
This page is a summary of: Topological insulator-metal transition and molecular electronics device based on zigzag phagraphene nanoribbon, Journal of Applied Physics, August 2018, American Institute of Physics,
DOI: 10.1063/1.5029845.
You can read the full text:
Resources
Electronic transport in zigzag PhaGraphene NanoRibbon doped with boron and nitrogen
ZZPGNR doped with B and N.
Transitions in electrical behavior of Molecular Devices based on 1-D and 2-D graphene-phagraphene-graphene hybrid heterojunctions
Heterojunction GNR and PGNR.
Electronic transport and its inelastic effects for a doped phagraphene device
Electronic transport and inelastic effects for the B and N doped phagraphene device
Contributors
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