Hauptseite > Publikationsdatenbank > Quantum transport through MoS 2 constrictions defined by photodoping > print

001     877733
005     20210130005234.0
024 7 _ |a 10.1088/1361-648X/aabbb8
|2 doi
024 7 _ |a 0953-8984
|2 ISSN
024 7 _ |a 1361-648X
|2 ISSN
024 7 _ |a 2128/25168
|2 Handle
024 7 _ |a pmid:29620021
|2 pmid
024 7 _ |a WOS:000430508800001
|2 WOS
037 _ _ |a FZJ-2020-02431
082 _ _ |a 530
100 1 _ |a Epping, Alexander
|0 P:(DE-HGF)0
|b 0
245 _ _ |a Quantum transport through MoS 2 constrictions defined by photodoping
260 _ _ |a Bristol
|c 2018
|b IOP Publ.
336 7 _ |a article
|2 DRIVER
336 7 _ |a Output Types/Journal article
|2 DataCite
336 7 _ |a Journal Article
|b journal
|m journal
|0 PUB:(DE-HGF)16
|s 1593434760_16069
|2 PUB:(DE-HGF)
336 7 _ |a ARTICLE
|2 BibTeX
336 7 _ |a JOURNAL_ARTICLE
|2 ORCID
336 7 _ |a Journal Article
|0 0
|2 EndNote
520 _ _ |a We present a device scheme to explore mesoscopic transport through molybdenum disulfide (MoS2) constrictions using photodoping. The devices are based on van-der-Waals heterostructures where few-layer MoS2 flakes are partially encapsulated by hexagonal boron nitride (hBN) and covered by a few-layer graphene flake to fabricate electrical contacts. Since the as-fabricated devices are insulating at low temperatures, we use photo-induced remote doping in the hBN substrate to create free charge carriers in the MoS2 layer. On top of the device, we place additional metal structures, which define the shape of the constriction and act as shadow masks during photodoping of the underlying MoS2/hBN heterostructure. Low temperature two- and four-terminal transport measurements show evidence of quantum confinement effects.
536 _ _ |a 521 - Controlling Electron Charge-Based Phenomena (POF3-521)
|0 G:(DE-HGF)POF3-521
|c POF3-521
|f POF III
|x 0
588 _ _ |a Dataset connected to CrossRef
700 1 _ |a Banszerus, Luca
|0 P:(DE-HGF)0
|b 1
700 1 _ |a Güttinger, Johannes
|0 P:(DE-HGF)0
|b 2
700 1 _ |a Krückeberg, Luisa
|0 P:(DE-HGF)0
|b 3
700 1 _ |a Watanabe, Kenji
|0 P:(DE-HGF)0
|b 4
700 1 _ |a Taniguchi, Takashi
|0 P:(DE-HGF)0
|b 5
700 1 _ |a Hassler, Fabian
|0 P:(DE-HGF)0
|b 6
700 1 _ |a Beschoten, Bernd
|0 P:(DE-Juel1)178028
|b 7
|u fzj
700 1 _ |a Stampfer, Christoph
|0 P:(DE-Juel1)180322
|b 8
|e Corresponding author
773 _ _ |a 10.1088/1361-648X/aabbb8
|g Vol. 30, no. 20, p. 205001 -
|0 PERI:(DE-600)1472968-4
|n 20
|p 205001 -
|t Journal of physics / Condensed matter Condensed matter
|v 30
|y 2018
|x 1361-648X
856 4 _ |u https://juser.fz-juelich.de/record/877733/files/Epping_2018_J._Phys.%20_Condens._Matter_30_205001-1.pdf
856 4 _ |y Published on 2018-04-20. Available in OpenAccess from 2019-04-20.
|u https://juser.fz-juelich.de/record/877733/files/1612.01118.pdf
856 4 _ |x pdfa
|u https://juser.fz-juelich.de/record/877733/files/Epping_2018_J._Phys.%20_Condens._Matter_30_205001-1.pdf?subformat=pdfa
856 4 _ |y Published on 2018-04-20. Available in OpenAccess from 2019-04-20.
|x pdfa
|u https://juser.fz-juelich.de/record/877733/files/1612.01118.pdf?subformat=pdfa
909 C O |o oai:juser.fz-juelich.de:877733
|p openaire
|p open_access
|p VDB
|p driver
|p dnbdelivery
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 0
|6 P:(DE-HGF)0
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 1
|6 P:(DE-HGF)0
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 2
|6 P:(DE-HGF)0
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 3
|6 P:(DE-HGF)0
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 6
|6 P:(DE-HGF)0
910 1 _ |a Forschungszentrum Jülich
|0 I:(DE-588b)5008462-8
|k FZJ
|b 7
|6 P:(DE-Juel1)178028
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 7
|6 P:(DE-Juel1)178028
910 1 _ |a Forschungszentrum Jülich
|0 I:(DE-588b)5008462-8
|k FZJ
|b 8
|6 P:(DE-Juel1)180322
910 1 _ |a RWTH Aachen
|0 I:(DE-588b)36225-6
|k RWTH
|b 8
|6 P:(DE-Juel1)180322
913 1 _ |a DE-HGF
|b Key Technologies
|l Future Information Technology - Fundamentals, Novel Concepts and Energy Efficiency (FIT)
|1 G:(DE-HGF)POF3-520
|0 G:(DE-HGF)POF3-521
|2 G:(DE-HGF)POF3-500
|v Controlling Electron Charge-Based Phenomena
|x 0
|4 G:(DE-HGF)POF
|3 G:(DE-HGF)POF3
914 1 _ |y 2020
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0200
|2 StatID
|b SCOPUS
|d 2020-02-27
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0160
|2 StatID
|b Essential Science Indicators
|d 2020-02-27
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1230
|2 StatID
|b Current Contents - Electronics and Telecommunications Collection
|d 2020-02-27
915 _ _ |a Embargoed OpenAccess
|0 StatID:(DE-HGF)0530
|2 StatID
915 _ _ |a JCR
|0 StatID:(DE-HGF)0100
|2 StatID
|b J PHYS-CONDENS MAT : 2018
|d 2020-02-27
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0150
|2 StatID
|b Web of Science Core Collection
|d 2020-02-27
915 _ _ |a WoS
|0 StatID:(DE-HGF)0110
|2 StatID
|b Science Citation Index
|d 2020-02-27
915 _ _ |a WoS
|0 StatID:(DE-HGF)0111
|2 StatID
|b Science Citation Index Expanded
|d 2020-02-27
915 _ _ |a IF < 5
|0 StatID:(DE-HGF)9900
|2 StatID
|d 2020-02-27
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)1150
|2 StatID
|b Current Contents - Physical, Chemical and Earth Sciences
|d 2020-02-27
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0310
|2 StatID
|b NCBI Molecular Biology Database
|d 2020-02-27
915 _ _ |a National-Konsortium
|0 StatID:(DE-HGF)0430
|2 StatID
|d 2020-02-27
|w ger
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0300
|2 StatID
|b Medline
|d 2020-02-27
915 _ _ |a Nationallizenz
|0 StatID:(DE-HGF)0420
|2 StatID
|d 2020-02-27
|w ger
915 _ _ |a DBCoverage
|0 StatID:(DE-HGF)0199
|2 StatID
|b Clarivate Analytics Master Journal List
|d 2020-02-27
920 _ _ |l yes
920 1 _ |0 I:(DE-Juel1)PGI-9-20110106
|k PGI-9
|l Halbleiter-Nanoelektronik
|x 0
920 1 _ |0 I:(DE-82)080009_20140620
|k JARA-FIT
|l JARA-FIT
|x 1
980 _ _ |a journal
980 _ _ |a VDB
980 _ _ |a UNRESTRICTED
980 _ _ |a I:(DE-Juel1)PGI-9-20110106
980 _ _ |a I:(DE-82)080009_20140620
980 1 _ |a FullTexts

LibraryCollectionCLSMajorCLSMinorLanguageAuthor
Marc 21