download0 view987
twitter facebook

공공누리This item is licensed Korea Open Government License

dc.contributor.author
류훈
dc.date.accessioned
2019-08-28T07:41:28Z
dc.date.available
2019-08-28T07:41:28Z
dc.date.issued
2014-10-08
dc.identifier.issn
1613-6810
dc.identifier.uri
https://repository.kisti.re.kr/handle/10580/14258
dc.description.abstract
A detailed theoretical study of the electronic and transport properties of a single atom transistor, where a single phosphorus atom is embedded within a single crystal transistor architecture, is presented. Using a recently reported deterministic single-atom transistor as a reference, the electronic structure of the device is represented atomistically with a tight-binding model, and the channel modulation is simulated self-consistently with a Thomas-Fermi method. The multi-scale modeling approach used allows confirmation of the charging energy of the one-electron donor charge state and explains how the electrostatic environments of the device electrodes affects the donor confinement potential and hence extent in gate voltage of the two-electron charge state. Importantly, whilst devices are relatively insensitive to dopant ordering in the highly doped leads, a ∼1% variation of the charging energy is observed when a dopant is moved just one lattice spacing within the device. The multi-scale modeling method presented here lays a strong foundation for the understanding of single-atom device structures: essential for both classical and quantum information processing.
dc.language
eng
dc.relation.ispartofseries
Small
dc.title
A Tight-Binding Study of Single-Atom Transistors
dc.subject.keyword
Quantum Computer
dc.subject.keyword
Si-P nanocomposite
dc.subject.keyword
Nanoelectronics
dc.subject.keyword
Atomistic Modeling
Appears in Collections:
7. KISTI 연구성과 > 학술지 발표논문
Files in This Item:
There are no files associated with this item.

Browse