Dual-Port Reflectometry Technique: Charge identification in nanoscaled single-electron transistors

Orlov, Alexei O.; Fay, Patrick; Snider, Gregory L.; Jehl, X.; Barraud, S.; Sanquer, M.

doi:10.1109/mnano.2015.2409411

Cited by 2 publications

(2 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The confinement by trench isolation or dielectrics is also very ben eficial for density and integration compared to electrostatic confinement which requires too many gates per bit. Finally the very good coupling of our quantum dots with their control gate enables radiofrequency reflectometry on gates to be used as efficient detectors for fast qubit readout [45,[84][85][86][87].…”

Section: Opportunities and Challenges Of A Fully Cmos Integrated Quan...mentioning

confidence: 99%

Single donor electronics and quantum functionalities with advanced CMOS technology

Jehl

Niquet

Sanquer

2016

J. Phys.: Condens. Matter

Self Cite

View full text Add to dashboard Cite

Recent progresses in quantum dots technology allow fundamental studies of single donors in various semiconductor nanostructures. For the prospect of applications figures of merits such as scalability, tunability, and operation at relatively large temperature are of prime importance. Beyond the case of actual dopant atoms in a host crystal, similar arguments hold for small enough quantum dots which behave as artificial atoms, for instance for single spin control and manipulation. In this context, this experimental review focuses on the silicon-on-insulator devices produced within microelectronics facilities with only very minor modifications to the current industrial CMOS process and tools. This is required for scalability and enabled by shallow trench or mesa isolation. It also paves the way for real integration with conventional circuits, as illustrated by a nanoscale device coupled to a CMOS circuit producing a radio-frequency drive on-chip. At the device level we emphasize the central role of electrostatics in etched silicon nanowire transistors, which allows to understand the characteristics in the full range from zero to room temperature.

show abstract

Section: Opportunities and Challenges Of A Fully Cmos Integrated Quan...mentioning

confidence: 99%

Single donor electronics and quantum functionalities with advanced CMOS technology

Jehl

Niquet

Sanquer

2016

J. Phys.: Condens. Matter

Self Cite

View full text Add to dashboard Cite

show abstract

“…Two lumped-element resonators, S 1 and S 2 , are connected to G 1 and G 2 , respectively. Each resonator is composed of a surface-mount inductor (nominal inductances: L 1 = 270 nH and L 2 = 390 nH for S 1 and S 2 , respectively) and the parasitic capacitance C p at the corresponding gate [7][8][9]25 [see Fig. 1b)].…”

mentioning

confidence: 99%

Level Spectrum and Charge Relaxation in a Silicon Double Quantum Dot Probed by Dual-Gate Reflectometry

et al. 2017

Self Cite

View full text Add to dashboard Cite

We report on dual-gate reflectometry in a metaloxide-semiconductor double-gate silicon transistor operating at low temperature as a double quantum dot device. The reflectometry setup consists of two radio-frequency resonators respectively connected to the two gate electrodes. By simultaneously measuring their dispersive responses, we obtain the complete charge stability diagram of the device. Electron transitions between the two quantum dots and between each quantum dot and either the source or the drain contact are detected through phase shifts in the reflected radio-frequency signals. At finite bias, reflectometry allows probing charge transitions to excited quantum-dot states, * To whom correspondence should be addressed † Université thereby enabling direct access to the energy level spectra of the quantum dots. Interestingly, we find that in the presence of electron transport across the two dots the reflectometry signatures of interdot transitions display a dip-peak structure containing quantitative information on the charge relaxation rates in the double quantum dot.Keywords: dispersive readout, reflectometry, double quantum dot, charge relaxation, highfrequency resonator, silicon.Integration of charge sensors for the readout of quantum bits (qubits) is one of the necessary ingredients for the realization of scalable semiconductor quantum computers. 1 In most qubits developed so far in silicon, like electron or nuclear spins in quantum dots and single atoms, 2-4 charge 5 or hybrid spin-charge states, 6 qubit readout has been performed with the aid of quantum point contacts (QPCs) or single-electron transistors (SETs). These charge-sensitive devices, however, involve a significant overhead in terms of gates and contact leads, posing an issue for scalability towards many-qubit architectures. Gate-coupled radio-frequency (RF) reflectome-1 arXiv:1610.03657v2 [cond-mat.mes-hall]

show abstract

Dual-Port Reflectometry Technique: Charge identification in nanoscaled single-electron transistors

Cited by 2 publications

References 27 publications

Single donor electronics and quantum functionalities with advanced CMOS technology

Single donor electronics and quantum functionalities with advanced CMOS technology

Level Spectrum and Charge Relaxation in a Silicon Double Quantum Dot Probed by Dual-Gate Reflectometry

Contact Info

Product

Resources

About