Title :
Fabrication and Study of Large-Area QHE Devices Based on Epitaxial Graphene
Author :
Novikov, Sergei ; Lebedeva, Natalia ; Pierz, Klaus ; Satrapinski, Alexandre
Author_Institution :
Dept. of Micro & Nanosci., Aalto Univ., Espoo, Finland
Abstract :
Quantum Hall effect (QHE) devices based on epitaxial graphene films grown on SiC were fabricated and studied for development of the QHE resistance standard. The graphene-metal contacting area in the Hall devices has been improved and fabricated using a double metallization process. The tested devices had an initial carrier concentration of (0.6-10) · ~1011 cm-2 and showed half-integer QHE at a relatively low (3 T) magnetic field. The application of the photochemical gating method and annealing of the sample provides a convenient way for tuning the carrier density to the optimum value. Precision measurements of the quantum Hall resistance in graphene and GaAs devices at moderate magnetic field strengths (≤7 T) showed a relative agreement within ·10-9.
Keywords :
Hall effect devices; carrier density; electric resistance measurement; electrical contacts; graphene; magnetic annealing; metallisation; photochemistry; quantum Hall effect; silicon compounds; thin film devices; wide band gap semiconductors; C; QHE resistance standard; SiC; annealing; carrier density tuning; double metallization process; epitaxial graphene film; graphene-metal contacting area; half-integer QHE; initial carrier concentration; large-area QHE device; magnetic flux density 3 T; photochemical gating method; quantum Hall effect device; quantum Hall resistance measurement; Charge carrier density; Current measurement; Electrical resistance measurement; Epitaxial growth; Fabrication; Graphene; Resistance; Contact resistance; epitaxial graphene; graphene fabrication; precision measurement; quantum Hall effect (QHE); quantum Hall effect (QHE).;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
DOI :
10.1109/TIM.2014.2385131
