SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2965920703> ?p ?o ?g. }

Showing items 1 to 100 of ±141 with 100 items per page.

W2965920703 abstract "Diamond has attracted attention as a next-generation semiconductor because of its various exceptional properties such as a wide bandgap and high breakdown electric field. Diamond field effect transistors, for example, have been extensively investigated for high-power and high-frequency electronic applications. The quality of their charge transport (i.e., mobility), however, has been limited due to charged impurities near the diamond surface. Here, we fabricate diamond field effect transistors by using a monocrystalline hexagonal boron nitride as a gate dielectric. The resulting high mobility of charge carriers allows us to observe quantum oscillations in both the longitudinal and Hall resistivities. The oscillations provide important information on the fundamental properties of the charge carriers, such as effective mass, lifetime, and dimensionality. Our results indicate the presence of a high-quality two-dimensional hole gas at the diamond surface and thus pave the way for studies of quantum transport in diamond and the development of low-loss and high-speed devices." @default.
W2965920703 created "2019-08-13" @default.
W2965920703 creator A5000840019 @default.
W2965920703 creator A5008622317 @default.
W2965920703 creator A5014093944 @default.
W2965920703 creator A5026955482 @default.
W2965920703 creator A5028662742 @default.
W2965920703 creator A5042413175 @default.
W2965920703 creator A5054217094 @default.
W2965920703 creator A5068387205 @default.
W2965920703 creator A5074765603 @default.
W2965920703 creator A5077642160 @default.
W2965920703 date "2019-12-02" @default.
W2965920703 modified "2023-10-03" @default.
W2965920703 title "Quantum oscillations in diamond field-effect transistors with a <mml:math xmlns:mml=http://www.w3.org/1998/Math/MathML><mml:mi>h</mml:mi></mml:math> -BN gate dielectric" @default.
W2965920703 cites W1509724473 @default.
W2965920703 cites W1971230586 @default.
W2965920703 cites W1975960230 @default.
W2965920703 cites W1982888897 @default.
W2965920703 cites W1995608178 @default.
W2965920703 cites W1997280286 @default.
W2965920703 cites W2009064711 @default.
W2965920703 cites W2010704195 @default.
W2965920703 cites W2012248136 @default.
W2965920703 cites W2022324641 @default.
W2965920703 cites W2032463864 @default.
W2965920703 cites W2036320910 @default.
W2965920703 cites W2043463741 @default.
W2965920703 cites W2054552883 @default.
W2965920703 cites W2056165949 @default.
W2965920703 cites W2058122340 @default.
W2965920703 cites W2059982427 @default.
W2965920703 cites W2061032025 @default.
W2965920703 cites W2071998162 @default.
W2965920703 cites W2073165689 @default.
W2965920703 cites W2075919721 @default.
W2965920703 cites W2081375043 @default.
W2965920703 cites W2081426085 @default.
W2965920703 cites W2104411397 @default.
W2965920703 cites W2106097631 @default.
W2965920703 cites W2113363720 @default.
W2965920703 cites W2137799406 @default.
W2965920703 cites W2170539287 @default.
W2965920703 cites W2321492218 @default.
W2965920703 cites W2329295808 @default.
W2965920703 cites W2333592972 @default.
W2965920703 cites W2517149915 @default.
W2965920703 cites W2563489608 @default.
W2965920703 cites W2607325924 @default.
W2965920703 cites W2615453867 @default.
W2965920703 cites W2754579470 @default.
W2965920703 cites W2760278298 @default.
W2965920703 cites W2767136750 @default.
W2965920703 cites W2801124635 @default.
W2965920703 cites W2902331442 @default.
W2965920703 cites W2914367231 @default.
W2965920703 cites W2923913439 @default.
W2965920703 cites W3098529492 @default.
W2965920703 cites W3103739384 @default.
W2965920703 cites W3104314840 @default.
W2965920703 cites W3104593987 @default.
W2965920703 cites W388025755 @default.
W2965920703 doi "https://doi.org/10.1103/physrevmaterials.3.121601" @default.
W2965920703 hasPublicationYear "2019" @default.
W2965920703 type Work @default.
W2965920703 sameAs 2965920703 @default.
W2965920703 citedByCount "15" @default.
W2965920703 countsByYear W29659207032020 @default.
W2965920703 countsByYear W29659207032021 @default.
W2965920703 countsByYear W29659207032022 @default.
W2965920703 countsByYear W29659207032023 @default.
W2965920703 crossrefType "journal-article" @default.
W2965920703 hasAuthorship W2965920703A5000840019 @default.
W2965920703 hasAuthorship W2965920703A5008622317 @default.
W2965920703 hasAuthorship W2965920703A5014093944 @default.
W2965920703 hasAuthorship W2965920703A5026955482 @default.
W2965920703 hasAuthorship W2965920703A5028662742 @default.
W2965920703 hasAuthorship W2965920703A5042413175 @default.
W2965920703 hasAuthorship W2965920703A5054217094 @default.
W2965920703 hasAuthorship W2965920703A5068387205 @default.
W2965920703 hasAuthorship W2965920703A5074765603 @default.
W2965920703 hasAuthorship W2965920703A5077642160 @default.
W2965920703 hasBestOaLocation W29659207032 @default.
W2965920703 hasConcept C104232198 @default.
W2965920703 hasConcept C106782819 @default.
W2965920703 hasConcept C108225325 @default.
W2965920703 hasConcept C121332964 @default.
W2965920703 hasConcept C133386390 @default.
W2965920703 hasConcept C145598152 @default.
W2965920703 hasConcept C159985019 @default.
W2965920703 hasConcept C165801399 @default.
W2965920703 hasConcept C166972891 @default.
W2965920703 hasConcept C172385210 @default.
W2965920703 hasConcept C179764930 @default.
W2965920703 hasConcept C188082385 @default.
W2965920703 hasConcept C192562407 @default.
W2965920703 hasConcept C26873012 @default.
W2965920703 hasConcept C2776921476 @default.
W2965920703 hasConcept C49040817 @default.
W2965920703 hasConcept C60799052 @default.