Two-Terminal and Multi-Terminal Designs for Next-Generation Quantized Hall Resistance Standards: Contact Material and Geometry

Abstract: In this paper, we show that quantum Hall resistance measurements using two terminals may be as precise as four-terminal measurements when applying superconducting split contacts. The described sample designs eliminate resistance contributions of terminals and contacts such that the size and complexity of next-generation quantized Hall resistance devices can be significantly improved.

“…Here, the bridge was implemented using a prototype quantum Hall array resistance standard (QHARS) composed of three multiple-series and parallel interconnected graphene Hall bars. To reduce the effect of contact resistances, split contacts are applied as described in [4]. Furthermore, the array elements use superconducting interconnections that do not have ohmic resistance and do not suffer from magnetoresistance.…”

“…In figures 3(b) and (c), the sample characterization by confocal laser scanning microscopy [21] shows the NbTiN interconnections and Longitudinal resistance/Ω split contacts as well as the structured monolayer graphene Hall bar. The graphene growth process that applies a combination of face-to-graphite (FTG) and polymerassisted sublimation growth (PASG), and the device fabrications process are thoroughly described in previous works [4,7,22,23]. For charge carrier density control, the graphene was functionalized with Cr(CO) 3 after device fabrication in a purpose-built deposition chamber [24].…”

“…The measurements of R H and R xx for both of these devices (U 1 and U 3 ) are asymmetric with respect to the magnetic field direction, with a plateau starting around B = ±3 T. When the magnetic field direction is positive, both the elements exhibit the typical behaviour of R H and R xx . Instead, when the magnetic field is reversed, the behaviour of R xx and R H is atypical for both elements due to the different current paths caused by the position of the measurement terminals and the multiple-connections between the devices [4]. the measurement is obtained by comparing the Hall resistances with a room-temperature 100 Ω resistance standard (Electro Scientific Industries ESI SR102 ‡) calibrated against a GaAs QHR with a binary cryogenic current comparator (BCCC) bridge [25].…”

“…In [3] we introduced the design of a direct current (DC) quantum Hall Kelvin bridge for the direct calibration of standard resistors. Here we present a bridge-on-a-chip implementation: the core is an integrated circuit composed of three quantum Hall effect (QHE) elements fabricated using epitaxial graphene on a SiC substrate and interconnected by a NbTiN superconducting wiring layer [4,5]. Each QHE element of the chip constitutes an arm of a Kelvin bridge; the fourth arm is given by the resistor under calibration.…”

Implementation of a graphene quantum Hall Kelvin bridge-on-a-chip for resistance calibrations

“…Here, the bridge was implemented using a prototype quantum Hall array resistance standard (QHARS) composed of three multiple-series and parallel interconnected graphene Hall bars. To reduce the effect of contact resistances, split contacts are applied as described in [4]. Furthermore, the array elements use superconducting interconnections that do not have ohmic resistance and do not suffer from magnetoresistance.…”

“…In figures 3(b) and (c), the sample characterization by confocal laser scanning microscopy [21] shows the NbTiN interconnections and Longitudinal resistance/Ω split contacts as well as the structured monolayer graphene Hall bar. The graphene growth process that applies a combination of face-to-graphite (FTG) and polymerassisted sublimation growth (PASG), and the device fabrications process are thoroughly described in previous works [4,7,22,23]. For charge carrier density control, the graphene was functionalized with Cr(CO) 3 after device fabrication in a purpose-built deposition chamber [24].…”

“…The measurements of R H and R xx for both of these devices (U 1 and U 3 ) are asymmetric with respect to the magnetic field direction, with a plateau starting around B = ±3 T. When the magnetic field direction is positive, both the elements exhibit the typical behaviour of R H and R xx . Instead, when the magnetic field is reversed, the behaviour of R xx and R H is atypical for both elements due to the different current paths caused by the position of the measurement terminals and the multiple-connections between the devices [4]. the measurement is obtained by comparing the Hall resistances with a room-temperature 100 Ω resistance standard (Electro Scientific Industries ESI SR102 ‡) calibrated against a GaAs QHR with a binary cryogenic current comparator (BCCC) bridge [25].…”

“…In [3] we introduced the design of a direct current (DC) quantum Hall Kelvin bridge for the direct calibration of standard resistors. Here we present a bridge-on-a-chip implementation: the core is an integrated circuit composed of three quantum Hall effect (QHE) elements fabricated using epitaxial graphene on a SiC substrate and interconnected by a NbTiN superconducting wiring layer [4,5]. Each QHE element of the chip constitutes an arm of a Kelvin bridge; the fourth arm is given by the resistor under calibration.…”

Implementation of a graphene quantum Hall Kelvin bridge-on-a-chip for resistance calibrations

“…Joining graphene QHE and the QHARS principle [41,42,43] can be the next step to achieve simple, reliable, economic and easy to operate quantum resistance standards suitable for operation in an industrial calibration center.…”

A quantum ampere

Record‐High Responsivity and High Detectivity Broadband Photodetectors Based on Upconversion/Gold/Prussian‐Blue Nanocomposite