Single-atom transistor: Difference between revisions

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Line 1: A '''single-atom transistor''' is a device that can open and close an [[electrical circuit]] by the controlled and reversible repositioning of one single [[atom]]. The single-atom transistor was invented and first demonstrated in ~~2004~~2002 by ~~Prof~~Dr. ~~Thomas~~Fangqing ~~Schimmel~~Xie ~~and~~in ~~his~~Prof. ~~team~~Thomas ofSchimmel's ~~scientists~~Group at the [[Karlsruhe Institute of Technology]] (former University of Karlsruhe).<ref>{{cite journal \| last1=Xie \| first1=F.-Q. \| last2=Nittler \| first2=L. \| last3=Obermair \| first3=Ch. \| last4=Schimmel \| first4=Th. \| title=Gate-Controlled Atomic Quantum Switch \| journal=Physical Review Letters \| publisher=American Physical Society (APS) \| volume=93 \| issue=12 \| date=2004-09-15 \| issn=0031-9007 \| doi=10.1103/physrevlett.93.128303 \| page=128303\| pmid=15447312 \| bibcode=2004PhRvL..93l8303X }}</ref> By means of a small electrical voltage applied to a control [[electrode]], the so-called ''gate electrode'', a single silver atom is reversibly moved in and out of a tiny junction, in this way closing and opening an electrical contact. Therefore, the single-atom transistor works as an atomic [[switch]] or atomic [[relay]], where the switchable atom opens and closes the gap between two tiny electrodes called ''source'' and ''drain''.<ref>{{cite journal \| last1=Xie \| first1=Fang-Qing \| last2=Obermair \| first2=Christian \| last3=Schimmel \| first3=Thomas \| title=Switching an electrical current with atoms: the reproducible operation of a multi-atom relay \| journal=Solid State Communications \| publisher=Elsevier BV \| volume=132 \| issue=7 \| year=2004 \| issn=0038-1098 \| doi=10.1016/j.ssc.2004.08.024 \| pages=437–442\| bibcode=2004SSCom.132..437X }}</ref><ref>{{cite journal \| last1=Xie \| first1=F.-Q. \| last2=Maul \| first2=R. \| last3=Augenstein \| first3=A. \| last4=Obermair \| first4=Ch. \| last5=Starikov \| first5=E. B. \| last6=Schön \| first6=G. \| last7=Schimmel \| first7=Th. \| last8=Wenzel \| first8=W. \|display-authors=5\| title=Independently Switchable Atomic Quantum Transistors by Reversible Contact Reconstruction \| journal=Nano Letters \| volume=8 \| issue=12 \| date=2008-12-10 \| issn=1530-6984 \| doi=10.1021/nl802438c \| pages=4493–4497\| pmid=19367974 \| arxiv=0904.0904 \| bibcode=2008NanoL...8.4493X \| s2cid=5191373 }}</ref><ref>{{cite journal \| last1=Obermair \| first1=Ch. \| last2=Xie \| first2=F.-Q. \| last3=Schimmel \| first3=Th. \| title=The Single-Atom Transistor: perspectives for quantum electronics on the atomic-scale \| journal=Europhysics News \| publisher=EDP Sciences \| volume=41 \| issue=4 \| year=2010 \| issn=0531-7479 \| doi=10.1051/epn/2010403 \| pages=25–28\| bibcode=2010ENews..41d..25O \| doi-access=free \| url=https://www.europhysicsnews.org/10.1051/epn/2010403/pdf }}</ref> The single-atom transistor opens perspectives for the development of future atomic-scale logics and quantum electronics. At the same time, the device of the Karlsruhe team of researchers marks the lower limit of [[miniaturization]], as feature sizes smaller than one atom cannot be produced [[Nanolithography\|lithographically]]. The device represents a quantum transistor, the conductance of the source-drain channel being defined by the rules of [[quantum mechanics]]. It can be operated at room temperature and at ambient conditions, i.e. neither cooling nor vacuum are required.<ref>{{cite journal \| last1=Xie \| first1=Fangqing \| last2=Maul \| first2=Robert \| last3=Obermair \| first3=Christian \| last4=Wenzel \| first4=Wolfgang \| last5=Schön \| first5=Gerd \| last6=Schimmel \| first6=Thomas \| title=Multilevel Atomic-Scale Transistors Based on Metallic Quantum Point Contacts \| journal=Advanced Materials \| publisher=Wiley \| volume=22 \| issue=18 \| date=2010-02-01 \| issn=0935-9648 \| doi=10.1002/adma.200902953 \| pages=2033–2036\| pmid=20544888 \| bibcode=2010AdM....22.2033X \| s2cid=28378720 \| url=https://publikationen.bibliothek.kit.edu/1000018062/150079259 }}</ref> Few atom transistors have been developed at [[Waseda University]] and at Italian CNR by Takahiro Shinada and Enrico Prati, who observed the ~~Anderson-Mott~~Anderson–Mott transition{{clarification needed\|date=July 2023}} in miniature by employing arrays of only two, four and six individually implanted [[Arsenic\|As]] or [[Phosphorus\|P]] atoms.<ref>{{cite journal \| last1=Prati \| first1=Enrico \| last2=Hori \| first2=Masahiro \| last3=Guagliardo \| first3=Filippo \| last4=Ferrari \| first4=Giorgio \| last5=Shinada \| first5=Takahiro \| title=Anderson–Mott transition in arrays of a few dopant atoms in a silicon transistor \| journal=Nature Nanotechnology \| publisher=Springer Science and Business Media LLC \| volume=7 \| issue=7 \| year=2012 \| issn=1748-3387 \| doi=10.1038/nnano.2012.94 \| pages=443–447\| pmid=22751223 \| bibcode=2012NatNa...7..443P }}</ref> == See also ==