Hybrid metal-semiconductor quantum dots for analog quantum simulation of Kondo lattice models : quantum point contacts in the integer quantum Hall regime
ORAL
Abstract
InAs quantum wells have recently offered the possibility of designing hybrid metal-semiconductor quantum dots with higher charging energies, for probing quantum criticality over a larger energy range. We demonstrate a key building block for hybrid metal-semiconductor dots in InAs, quantum point contacts at high field in the integer quantum hall regime, building on the demonstration of such point contacts at low field in [1]. Quantum point contacts allow for tunable transmission of quantum Hall edge modes within mesoscopic devices, a key requirement for analog quantum simulation of quantum critical points [2]. We present transport data showing quantized QPC plateaus at high fields for such quantum point contacts. Additionally, we characterize the formation of potential disorder-induced quantum dots within the point contact constriction and the ability to screen such dots using an additional gate.
- Hsueh, C.L., Sriram, P. et al. Phys. Rev. B 105, 195303 (2022).
Pouse, W., Peeters, L., et al. Nat. Phys. 19, 492–499 (2023).
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Presenters
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Karna Morey
Stanford University
Authors
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Karna Morey
Stanford University
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Praveen Sriram
Stanford University
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Connie L Hsueh
Stanford University
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Tiantian Wang
Purdue University, Purdue
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Candice Thomas
Purdue University, Purdue
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Geoffrey C Gardner
Purdue University, Purdue
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Marc Kastner
Stanford Institute for Materials & Energy Sciences, Stanford University, Stanford University
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Michael James Manfra
Purdue University
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David Goldhaber-Gordon
Stanford Institute for Materials & Energy Sciences, Stanford University, Stanford University, Department of Physics, Stanford University