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Quantum-Dot Single-Electron Transistors as Thermoelectric Quantum Detectors at Terahertz Frequencies

Mahdi Asgari, Dominique Coquillat, Guido Menichetti, Valentina Zannier, Nina Diakonova, W. Knap, Lucia Sorba, Leonardo Viti, Miriam S. Vitiello

2021Nano Letters35 citationsDOIOpen Access PDF

Abstract

Low-dimensional nanosystems are promising candidates for manipulating, controlling, and capturing photons with large sensitivities and low noise. If quantum engineered to tailor the energy of the localized electrons across the desired frequency range, they can allow devising of efficient quantum sensors across any frequency domain. Here, we exploit the rich few-electron physics to develop millimeter-wave nanodetectors employing as a sensing element an InAs/InAs0.3P0.7 quantum-dot nanowire, embedded in a single-electron transistor. Once irradiated with light, the deeply localized quantum element exhibits an extra electromotive force driven by the photothermoelectric effect, which is exploited to efficiently sense radiation at 0.6 THz with a noise equivalent power <8 pWHz–1/2 and almost zero dark current. The achieved results open intriguing perspectives for quantum key distributions, quantum communications, and quantum cryptography at terahertz frequencies.

Topics & Concepts

PhysicsQuantum dotTerahertz radiationQuantum point contactElectronNanowireNoise (video)OptoelectronicsQuantum sensorPhotonQuantumQuantum computerQuantum wellQuantum networkOpticsQuantum mechanicsComputer scienceArtificial intelligenceImage (mathematics)LaserQuantum and electron transport phenomenaTerahertz technology and applicationsSuperconducting and THz Device Technology
Quantum-Dot Single-Electron Transistors as Thermoelectric Quantum Detectors at Terahertz Frequencies | Litcius