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1. Gatemon qubit on a germanium quantum-well heterostructure

Author

Kiyooka, Elyjah, Tangchingchai, Chotivut, Noirot, Leo, Leblanc, Axel, Brun, Boris, Zihlmann, Simon, Maurand, Romain, Schmitt, Vivien, Dumur, Étienne, Hartmann, Jean-Michel, Lefloch, Francois, and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Gatemons are superconducting qubits similar to transmons except that the Josephson element consists of a gate-tunable semiconducting weak link. Here, we report the realization of a gatemon device obtained by fabricating a microwave circuit in aluminium on a SiGe heterostructure embedding a Ge quantum well. Owing to the superconducting proximity effect, the high-mobility two-dimensional hole gas confined in this well provides a gate-tunable superconducting weak link between two Al contacts. We perform Rabi oscillation and Ramsey interference measurements, demonstrate the gate-voltage dependence of the qubit frequency, and measure the qubit anharmonicity. The reported proof-of-concept reproduces the results of a very recent work [Sagi et al., Nat. Commun. 15, 6400 (2024)] using similar SiGe heterostructures thereby validating a novel platform for the development of gatemons and parity-protected $\cos(2\phi)$ qubits.

Published
2024

2. Parametric longitudinal coupling of a semiconductor charge qubit and a RF resonator

Author

Champain, Victor, Zihlmann, Simon, Chessari, Alessandro, Bertrand, Benoit, Niebojewski, Heimanu, Dumur, Etienne, Jehl, Xavier, Schmitt, Vivien, Brun, Boris, Winkelmann, Clemens, Niquet, Yann-Michel, Filippone, Michele, De Franceschi, Silvano, and Maurand, Romain

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

In this study, we provide a full experimental characterization of the parametric longitudinal coupling between a CMOS charge qubit and an off-chip RF resonator. Following Corrigan et al, Phys. Rev. Applied 20, 064005 (2023), we activate parametric longitudinal coupling by driving the charge qubit at the resonator frequency. Managing the crosstalk between the drive applied to the qubit and the resonator allows for the systematic study of the dependence of the longitudinal and dispersive charge-photon couplings on the qubit-resonator detuning and the applied drive. Our experimental estimations of the charge-photon couplings are perfectly reproduced by theoretical simple formulas, without relying on any fitting parameter. We go further by showing a parametric displacement of the resonator's steady state, conditional on the qubit state, and the insensitivity of the longitudinal coupling constant on the photon population of the resonator. Our results open to the exploration of the photon-mediated longitudinal readout and coupling of multiple and distant spins, with long coherent times, in hybrid CMOS cQED architectures., Comment: 11 pages, 12 figures

Published
2024

3. Gate- and flux-tunable sin(2$\varphi$) Josephson element with proximitized Ge-based junctions

Author

Leblanc, Axel, Tangchingchai, Chotivut, Momtaz, Zahra Sadre, Kiyooka, Elyjah, Hartmann, Jean-Michel, Gustavo, Frederic, Thomassin, Jean-Luc, Brun, Boris, Schmitt, Vivien, Zihlmann, Simon, Maurand, Romain, Dumur, Etienne, De Franceschi, Silvano, and Lefloch, Francois

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Hybrid superconductor-semiconductor Josephson field-effect transistors (JoFETs) function as Josephson junctions with a gate-tunable critical current. Additionally, they can feature a non-sinusoidal current-phase relation (CPR) containing multiple harmonics of the superconducting phase difference, a so-far underutilized property. In this work, we exploit this multi-harmonicity to create a Josephson circuit element with an almost perfectly $\pi$-periodic CPR, indicative of a largely dominant charge-4e supercurrent transport. Such a Josephson element was recently proposed as the basic building block of a protected superconducting qubit. Here, it is realized using a superconducting quantum interference device (SQUID) with low-inductance aluminum arms and two nominally identical JoFETs. The latter are fabricated from a SiGe/Ge/SiGe quantum-well heterostructure embedding a high-mobility two-dimensional hole gas. By carefully adjusting the JoFET gate voltages and finely tuning the magnetic flux through the SQUID close to half a flux quantum, we achieve a regime where the $\sin(2\varphi)$ component accounts for more than \SI{95}{\percent} of the total supercurrent. This result demonstrates a new promising route for the realization of superconducting qubits with enhanced coherence properties.

Published
2024

4. Mitigating variability in epitaxial-heterostructure-based spin-qubit devices by optimizing gate layout

Author

Martinez, Biel, de Franceschi, Silvano, and Niquet, Yann-Michel

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The scalability of spin qubit devices is conditioned by qubit-to-qubit variability. Disorder in the host materials indeed affects the wave functions of the confined carriers, which leads to variations in their charge and spin properties. Charge disorder in the amorphous oxides is particularly detrimental owing to its long-range influence. Here we analyze the effects of charge traps at the semiconductor/oxide interface, which are generally believed to play a dominant role in variability. We consider multiple random distributions of these interface traps and numerically calculate their impact on the chemical potentials, detuning and tunnel coupling of two adjacent quantum dots in SiGe heterostructure. Our results highlight the beneficial screening effect of the metal gates. The surface of the heterostructure shall, therefore, be covered as much as possible by the gates in order to limit variability. We propose an alternative layout with tip-shaped gates that maximizes the coverage of the semiconductor/oxide interface and outperforms the usual planar layout in some regimes. This highlights the importance of design in the management of device-to-device variability.

Published
2024

5. Real-time milli-Kelvin thermometry in a semiconductor qubit architecture

Author

Champain, Victor, Schmitt, Vivien, Bertrand, Benoit, Niebojewski, Heimanu, Maurand, Romain, Jehl, Xavier, Winkelmann, Clemens, De Franceschi, Silvano, and Brun, Boris

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report local time-resolved thermometry in a silicon nanowire quantum dot device designed to host a linear array of spin qubits. Using two alternative measurement schemes based on rf reflectometry, we are able to probe either local electron or phonon temperatures with $\mu$s-scale time resolution and a noise equivalent temperature of $3$ $\rm mK/\sqrt{\rm Hz}$. Following the application of short microwave pulses, causing local periodic heating, time-dependent thermometry can track the dynamics of thermal excitation and relaxation, revealing clearly different characteristic time scales. This work opens important prospects to investigate the out-of-equilibrium thermal properties of semiconductor quantum electronic devices operating at very low temperature. In particular, it may provide a powerful handle to understand heating effects recently observed in semiconductor spin-qubit systems., Comment: 7 pages 4 figures (supp. mat. 6 pages and 5 figures)

Published
2023
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6. Quantum dynamics for energetic advantage in a charge-based classical full-adder

Author

Moutinho, João P., Pezzutto, Marco, Pratapsi, Sagar, da Silva, Francisco Ferreira, De Franceschi, Silvano, Bose, Sougato, Costa, António T., and Omar, Yasser

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

We present a proposal for a one-bit full-adder to process classical information based on the quantum reversible dynamics of a triple quantum dot system. The device works via the repeated execution of a Fredkin gate implemented through the dynamics of a single time-independent Hamiltonian. Our proposal uses realistic parameter values and could be implemented on currently available quantum dot architectures. We compare the estimated energy requirements for operating our full-adder with those of well-known fully classical devices, and argue that our proposal may provide a consistently better energy efficiency. Our work serves as a proof of principle for the development of energy-efficient information technologies operating through coherent quantum dynamics., Comment: V2: Minor updates. -- Keywords: energy-efficient computing, quantum dynamics, quantum gates, semiconductor quantum dots, quantum technologies

Published
2022
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7. Strong coupling between a photon and a hole spin in silicon

Author

Yu, Cécile X., Zihlmann, Simon, Abadillo-Uriel, José C., Michal, Vincent P., Rambal, Nils, Niebojewski, Heimanu, Bedecarrats, Thomas, Vinet, Maud, Dumur, Etienne, Filippone, Michele, Bertrand, Benoit, De Franceschi, Silvano, Niquet, Yann-Michel, and Maurand, Romain

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

Spins in semiconductor quantum dots constitute a promising platform for scalable quantum information processing. Coupling them strongly to the photonic modes of superconducting microwave resonators would enable fast non-demolition readout and long-range, on-chip connectivity, well beyond nearest-neighbor quantum interactions. Here we demonstrate strong coupling between a microwave photon in a superconducting resonator and a hole spin in a silicon-based double quantum dot issued from a foundry-compatible MOS fabrication process. By leveraging the strong spin-orbit interaction intrinsically present in the valence band of silicon, we achieve a spin-photon coupling rate as high as 330~MHz largely exceeding the combined spin-photon decoherence rate. This result, together with the recently demonstrated long coherence of hole spins in silicon, opens a new realistic pathway to the development of circuit quantum electrodynamics with spins in semiconductor quantum dots., Comment: 7 pages, 4 figures of main text, 19 pages, 12 figures of supplementary material

Published
2022
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8. Spin-valley coupling anisotropy and noise in CMOS quantum dots

Author

Spence, Cameron, Paz, Bruna Cardoso, Klemt, Bernhard, Chanrion, Emmanuel, Niegemann, David J., Jadot, Baptiste, Thiney, Vivien, Bertrand, Benoit, Niebojewski, Heimanu, Mortemousque, Pierre-André, Jehl, Xavier, Maurand, Romain, De Franceschi, Silvano, Vinet, Maud, Balestro, Franck, Bäuerle, Christopher, Niquet, Yann-Michel, Meunier, Tristan, and Urdampilleta, Matias

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

One of the main advantages of silicon spin qubits over other solid-state qubits is their inherent scalability and compatibility with the 300 mm CMOS fabrication technology that is already widely used in the semiconductor industry, whilst maintaining high readout and gate fidelities. We demonstrate detection of a single electron spin using energy-selective readout in a CMOS-fabricated nanowire device with an integrated charge detector. We measure a valley splitting of 0.3 meV and 0.16 meV in two similar devices. The anisotropy of the spin-valley mixing is measured and shown to follow the dependence expected from the symmetry of the local confinement, indicating low disorder in the region of the quantum dot. Finally the charge noise in the spin-valley coupling regime is investigated and found to induce fluctuations in the qubit energy in the range of $0.6GHz/\sqrt{Hz}$., Comment: 4 figures

Published
2021

9. Strong coupling between a photon and a hole spin in silicon

Author

Yu, Cécile X., Zihlmann, Simon, Abadillo-Uriel, José C., Michal, Vincent P., Rambal, Nils, Niebojewski, Heimanu, Bedecarrats, Thomas, Vinet, Maud, Dumur, Étienne, Filippone, Michele, Bertrand, Benoit, De Franceschi, Silvano, Niquet, Yann-Michel, and Maurand, Romain

Published
2023
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10. The 2021 Quantum Materials Roadmap

Author

Giustino, Feliciano, Lee, Jin Hong, Trier, Felix, Bibes, Manuel, Winter, Stephen M, Valentí, Roser, Son, Young-Woo, Taillefer, Louis, Heil, Christoph, Figueroa, Adriana I., Plaçais, Bernard, Wu, QuanSheng, Yazyev, Oleg V., Bakkers, Erik P. A. M., Nygård, Jesper, Forn-Diaz, Pol, De Franceschi, Silvano, McIver, J. W., Torres, L. E. F. Foa, Low, Tony, Kumar, Anshuman, Galceran, Regina, Valenzuela, Sergio O., Costache, Marius V., Manchon, Aurélien, Kim, Eun-Ah, Schleder, Gabriel R, Fazzio, Adalberto, and Roche, Stephan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity, Quantum Physics
Abstract

In recent years, the notion of Quantum Materials has emerged as a powerful unifying concept across diverse fields of science and engineering, from condensed-matter and cold atom physics to materials science and quantum computing. Beyond traditional quantum materials such as unconventional superconductors, heavy fermions, and multiferroics, the field has significantly expanded to encompass topological quantum matter, two-dimensional materials and their van der Waals heterostructures, Moire materials, Floquet time crystals, as well as materials and devices for quantum computation with Majorana fermions. In this Roadmap collection we aim to capture a snapshot of the most recent developments in the field, and to identify outstanding challenges and emerging opportunities. The format of the Roadmap, whereby experts in each discipline share their viewpoint and articulate their vision for quantum materials, reflects the dynamic and multifaceted nature of this research area, and is meant to encourage exchanges and discussions across traditional disciplinary boundaries. It is our hope that this collective vision will contribute to sparking new fascinating questions and activities at the intersection of materials science, condensed matter physics, device engineering, and quantum information, and to shaping a clearer landscape of quantum materials science as a new frontier of interdisciplinary scientific inquiry., Comment: 93 pages, 27 figures

Published
2021
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11. Dispersively probed microwave spectroscopy of a silicon hole double quantum dot

Author

Ezzouch, Rami, Zihlmann, Simon, Michal, Vincent P., Li, Jing, Aprá, Agostino, Bertrand, Benoit, Hutin, Louis, Vinet, Maud, Urdampilleta, Matias, Meunier, Tristan, Jehl, Xavier, Niquet, Yann-Michel, Sanquer, Marc, De Franceschi, Silvano, and Maurand, Romain

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Owing to ever increasing gate fidelities and to a potential transferability to industrial CMOS technology, silicon spin qubits have become a compelling option in the strive for quantum computation. In a scalable architecture, each spin qubit will have to be finely tuned and its operating conditions accurately determined. In this prospect, spectroscopic tools compatible with a scalable device layout are of primary importance. Here we report a two-tone spectroscopy technique providing access to the spin-dependent energy-level spectrum of a hole double quantum dot defined in a split-gate silicon device. A first GHz-frequency tone drives electric-dipole spin resonance enabled by the valence-band spin-orbit coupling. A second lower-frequency tone (approximately 500 MHz) allows for dispersive readout via rf-gate reflectometry. We compare the measured dispersive response to the linear response calculated in an extended Jaynes-Cummings model and we obtain characteristic parameters such as g-factors and tunnel/spin-orbit couplings for both even and odd occupation.

Published
2020
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12. Semiconductor Qubits In Practice

Author

Chatterjee, Anasua, Stevenson, Paul, De Franceschi, Silvano, Morello, Andrea, de Leon, Nathalie, and Kuemmeth, Ferdinand

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

In recent years semiconducting qubits have undergone a remarkable evolution, making great strides in overcoming decoherence as well as in prospects for scalability, and have become one of the leading contenders for the development of large-scale quantum circuits. In this Review we describe the current state of the art in semiconductor charge and spin qubits based on gate-controlled semiconductor quantum dots, shallow dopants, and color centers in wide band gap materials. We frame the relative strengths of the different semiconductor qubit implementations in the context of quantum simulations, computing, sensing and networks. By highlighting the status and future perspectives of the basic types of semiconductor qubits, this Review aims to serve as a technical introduction for non-specialists as well as a forward-looking reference for scientists intending to work in this field., Comment: Review article, feedback welcome, 27 pages, 5 figures

Published
2020
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13. The germanium quantum information route

Author

Scappucci, Giordano, Kloeffel, Christoph, Zwanenburg, Floris A., Loss, Daniel, Myronov, Maksym, Zhang, Jian-Jun, De Franceschi, Silvano, Katsaros, Georgios, and Veldhorst, Menno

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

In the worldwide endeavor for disruptive quantum technologies, germanium is emerging as a versatile material to realize devices capable of encoding, processing, or transmitting quantum information. These devices leverage special properties of the germanium valence-band states, commonly known as holes, such as their inherently strong spin-orbit coupling and the ability to host superconducting pairing correlations. In this Review, we initially introduce the physics of holes in low-dimensional germanium structures with key insights from a theoretical perspective. We then examine the material science progress underpinning germanium-based planar heterostructures and nanowires. We review the most significant experimental results demonstrating key building blocks for quantum technology, such as an electrically driven universal quantum gate set with spin qubits in quantum dots and superconductor-semiconductor devices for hybrid quantum systems. We conclude by identifying the most promising prospects toward scalable quantum information processing.

Published
2020
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14. Charge detection in an array of CMOS quantum dots

Author

Chanrion, Emmanuel, Niegemann, David J., Bertrand, Benoit, Spence, Cameron, Jadot, Baptiste, Li, Jing, Mortemousque, Pierre-André, Hutin, Louis, Maurand, Romain, Jehl, Xavier, Sanquer, Marc, De Franceschi, Silvano, Bäuerle, Christopher, Balestro, Franck, Niquet, Yann-Michel, Vinet, Maud, Meunier, Tristan, and Urdampilleta, Matias

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The recent development of arrays of quantum dots in semiconductor nanostructures highlights the progress of quantum devices toward large scale. However, how to realize such arrays on a scalable platform such as silicon is still an open question. One of the main challenge resides in the detection of charges within the array. It is a prerequisite functionality to initialize a desired charge state and readout spins through spin-to-charge conversion mechanisms. In this paper, we use two methods based on either a single-lead charge detector, or a reprogrammable single electron transistor. Thanks to these methods, we study the charge dynamics and sensitivity by performing single shot detection of the charge. Finally, we can probe the charge stability at any node of a linear array and assess the Coulomb disorder in the structure. We find an electrochemical potential fluctuation induced by charge noise comparable to that reported in other silicon quantum dots., Comment: 10 pages, 6 figures

Published
2020
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16. All-Electrical Control of an Electron Spin/Valley Quantum Bit in SOI CMOS Technology

Author

Bourdet, Léo, Hutin, Louis, Bertrand, Benoit, Corna, Andrea, Bohuslavskyi, Heorhii, Amisse, Anthony, Crippa, Alessandro, Maurand, Romain, Barraud, Sylvain, Urdampilleta, Matias, Bäuerle, Christopher, Meunier, Tristan, Sanquer, Marc, Jehl, Xavier, De Franceschi, Silvano, Niquet, Yann-Michel, and Vinet, Maud

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We fabricated Quantum Dot (QD) devices using a standard SOI CMOS process flow, and demonstrated that the spin of confined electrons could be controlled via a local electrical-field excitation, owing to inter-valley spin-orbit coupling. We discuss that modulating the confinement geometry via an additional electrode may enable switching a quantum bit (qubit) between an electrically-addressable valley configuration and a protected spin configuration. This proposed scheme bears relevance to improve the trade-off between fast operations and slow decoherence for quantum computing on a Si qubit platform. Finally, we evoke the impact of process-induced variability on the operating bias range., Comment: arXiv admin note: substantial text overlap with arXiv:1912.09806

Published
2019
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17. Germanium quantum well Josephson field effect transistors and interferometers

Author

Vigneau, Florian, Mizokuchi, Raisei, Zanuz, Dante Colao, Huang, XuHai, Tan, Susheng, Maurand, Romain, Frolov, Sergey, Sammak, Amir, Scappucci, Giordano, Lefloch, François, and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics, Quantum Physics
Abstract

Hybrid superconductor-semiconductor structures attract increasing attention owing to a variety of potential applications in quantum computing devices. They can serve to the realization of topological superconducting systems, as well as gate-tunable superconducting quantum bits. Here we combine a SiGe/Ge/SiGe quantum-well heterostructure hosting high-mobility two-dimensional holes and aluminum superconducting leads to realize prototypical hybrid devices, such as Josephson field-effect transistors (JoFETs) and superconducting quantum interference devices (SQUIDs). We observe gate-controlled supercurrent transport with Ge channels as long as one micrometer and estimate the induced superconducting gap from tunnel spectroscopy measurements in superconducting point-contact devices. Transmission electron microscopy reveals the diffusion of Ge into the aluminum contacts, whereas no aluminum is detected in the Ge channel.

Published
2018
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18. Characterization and Modeling of 28-nm FDSOI CMOS Technology down to Cryogenic Temperatures

Author

Beckers, Arnout, Jazaeri, Farzan, Bohuslavskyi, Heorhii, Hutin, Louis, De Franceschi, Silvano, and Enz, Christian

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

This paper presents an extensive characterization and modeling of a commercial 28-nm FDSOI CMOS process operating down to cryogenic temperatures. The important cryogenic phenomena influencing this technology are discussed. The low-temperature transfer characteristics including body-biasing are modeled over a wide temperature range (room temperature down to 4.2\,K) using the design-oriented simplified-EKV model. The trends of the free-carrier mobilities versus temperature in long and short-narrow devices are extracted from dc measurements down to 1.4\,K and 4.2\,K respectively, using a recently-proposed method based on the output conductance. A cryogenic-temperature-induced mobility degradation is observed on long pMOS, leading to a maximum hole mobility around 77\,K. This work sets the stage for preparing industrial design kits with physics-based cryogenic compact models, a prerequisite for the successful co-integration of FDSOI CMOS circuits with silicon qubits operating at deep-cryogenic temperatures.

Published
2018
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19. Gate-Based High Fidelity Spin Read-out in a CMOS Device

Author

Urdampilleta, Matias, Niegemann, David J., Chanrion, Emmanuel, Jadot, Baptiste, Spence, Cameron, Mortemousque, Pierre-André, Bäuerle, 1 Christopher, Hutin, Louis, Bertrand, Benoit, Barraud, Sylvain, Maurand, Romain, Sanquer, Marc, Jehl, Xavier, De Franceschi, Silvano, Vinet, Maud, and Meunier, Tristan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The engineering of electron spin qubits in a compact unit cell embedding all quantum functionalities is mandatory for large scale integration. In particular, the development of a high-fidelity and scalable spin readout method remains an open challenge. Here we demonstrate high-fidelity and robust spin readout based on gate reflectometry in a CMOS device comprising one qubit dot and one ancillary dot coupled to an electron reservoir to perform readout. This scalable method allows us to read out a spin with a fidelity above 99% for 1 ms integration time. To achieve such fidelity, we exploit a latched spin blockade mechanism that requires electron exchange between the ancillary dot and the reservoir. We show that the demonstrated high read-out fidelity is fully preserved up to 0.5 K. This results holds particular relevance for the future co-integration of spin qubits and classical control electronics., Comment: 6 pages, 4 figures

Published
2018

20. Design-oriented Modeling of 28 nm FDSOI CMOS Technology down to 4.2 K for Quantum Computing

Author

Beckers, Arnout, Jazaeri, Farzan, Bohuslavskyi, Heorhii, Hutin, Louis, De Franceschi, Silvano, and Enz, Christian

Subjects
Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics
Abstract

In this paper a commercial 28-nm FDSOI CMOS technology is characterized and modeled from room temperature down to 4.2 K. Here we explain the influence of incomplete ionization and interface traps on this technology starting from the fundamental device physics. We then illustrate how these phenomena can be accounted for in circuit device-models. We find that the design-oriented simplified EKV model can accurately predict the impact of the temperature reduction on the transfer characteristics, back-gate sensitivity, and transconductance efficiency. The presented results aim at extending industry-standard compact models to cryogenic temperatures for the design of cryo- CMOS circuits implemented in a 28 nm FDSOI technology., Comment: 2018 Joint International EUROSOI Workshop and International Conference on Ultimate Integration on Silicon (EUROSOI-ULIS)

Published
2018
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23. Electrical spin driving by $g$-matrix modulation in spin-orbit qubits

Author

Crippa, Alessandro, Maurand, Romain, Bourdet, Léo, Kotekar-Patil, Dharmraj, Amisse, Anthony, Jehl, Xavier, Sanquer, Marc, Laviéville, Romain, Bohuslavskyi, Heorhii, Hutin, Louis, Barraud, Sylvain, Vinet, Maud, Niquet, Yann-Michel, and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In a semiconductor spin qubit with sizable spin-orbit coupling, coherent spin rotations can be driven by a resonant gate-voltage modulation. Recently, we have exploited this opportunity in the experimental demonstration of a hole spin qubit in a silicon device. Here we investigate the underlying physical mechanisms by measuring the full angular dependence of the Rabi frequency as well as the gate-voltage dependence and anisotropy of the hole $g$-factors. We show that a $g$-matrix formalism can simultaneously capture and discriminate the contributions of two mechanisms so far independently discussed in the literature: one associated with the modulation of the $g$ factors, and measurable by Zeeman energy spectroscopy, the other not. Our approach has a general validity and can be applied to the analysis of other types of spin-orbit qubits., Comment: Letter format (4 pages, 4 figures). Detailed theory in Supplemenatl Material

Published
2017
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24. Electrically driven electron spin resonance mediated by spin-valley-orbit coupling in a silicon quantum dot

Author

Corna, Andrea, Bourdet, Léo, Maurand, Romain, Crippa, Alessandro, Kotekar-Patil, Dharmraj, Bohuslavskyi, Heorhii, Lavieville, Romain, Hutin, Louis, Barraud, Sylvain, Jehl, Xavier, Vinet, Maud, De Franceschi, Silvano, Niquet, Yann-Michel, and Sanquer, Marc

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The ability to manipulate electron spins with voltage-dependent electric fields is key to the operation of quantum spintronics devices, such as spin-based semiconductor qubits. A natural approach to electrical spin control exploits the spin-orbit coupling (SOC) inherently present in all materials. So far, this approach could not be applied to electrons in silicon, due to their extremely weak SOC. Here we report an experimental realization of electrically driven electron-spin resonance in a silicon-on-insulator (SOI) nanowire quantum dot device. The underlying driving mechanism results from an interplay between SOC and the multi-valley structure of the silicon conduction band, which is enhanced in the investigated nanowire geometry. We present a simple model capturing the essential physics and use tight-binding simulations for a more quantitative analysis. We discuss the relevance of our findings to the development of compact and scalable electron-spin qubits in silicon.

Published
2017
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27. Level spectrum and charge relaxation in a silicon double quantum dot probed by dual-gate reflectometry

Author

Crippa, Alessandro, Maurand, Romain, Kotekar-Patil, Dharmraj, Corna, Andrea, Bohuslavskyi, Heorhii, Orlov, Alexei O., Fay, Patrick, Laviéville, Romain, Barraud, Silvain, Vinet, Maud, Sanquer, Marc, De Franceschi, Silvano, and Jehl, Xavier

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on dual-gate reflectometry in a metal-oxide-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 response, we obtain the complete charge stability diagram of the device. Charge 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 thereby enabling direct access to the energy level spectra of the quantum dots. Interestingly, we find that in the presence of charge 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., Comment: 7 pages, 4 figures

Published
2016
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28. Scaling of sub-gap excitations in a superconductor-semiconductor nanowire quantum dot

Author

Lee, Eduardo J. H., Jiang, Xiaocheng, Zitko, Rok, Aguado, Ramon, Lieber, Charles M., and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A quantum dot coupled to a superconducting contact provides a tunable artificial analogue of a magnetic atom in a superconductor, a paradigmatic quantum impurity problem. We realize such a system with an InAs semiconductor nanowire contacted by an Al-based superconducting electrode. We use an additional normal-type contact as weakly coupled tunnel probe to perform tunneling spectroscopy measurements of the elementary sub-gap excitations, known as Andreev bound states or Yu-Shiba-Rusinov states. We demonstrate that the energy of these states, $\zeta$, scales with the ratio between the Kondo temperature, $T_K$, and the superconducting gap, $\Delta$. $\zeta$ vanishes for $T_K/\Delta \approx 0.6$, denoting a quantum phase transition between spin singlet and doublet ground states. By further leveraging the gate control over the quantum dot parameters, we determine the singlet-doublet phase boundary in the stability diagram of the system. Our experimental results show remarkable quantitative agreement with numerical renormalization group calculations., Comment: 5 pages, 5 figures

Published
2016
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29. Pauli Blockade in a Few-Hole PMOS Double Quantum Dot limited by Spin-Orbit Interaction

Author

Bohuslavskyi, Heorhii, Kotekar-Patil, Dharmraj, Maurand, Romain, Corna, Andrea, Barraud, Sylvain, Bourdet, Leo, Hutin, Louis, Niquet, Yann-Michel, Jehl, Xavier, De Franceschi, Silvano, Vinet, Maud, and Sanquer, Marc

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on hole compact double quantum dots fabricated using conventional CMOS technology. We provide evidence of Pauli spin blockade in the few hole regime which is relevant to spin qubit implementations. A current dip is observed around zero magnetic field, in agreement with the expected behavior for the case of strong spin-orbit. We deduce an intradot spin relaxation rate $\approx$120\,kHz for the first holes, an important step towards a robust hole spin-orbit qubit.

Published
2016
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31. PtSi Clustering In Silicon Probed by Transport Spectroscopy

Author

Mongillo, Massimo, Spathis, Panayotis, Katsaros, Georgios, Rurali, Riccardo, Cartoixa, Xavier, Gentile, Pascal, and de Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Metal silicides formed by means of thermal annealing processes are employed as contact materials in microelectronics. Control of the structure of silicide/silicon interfaces becomes a critical issue when the device characteristic size is reduced below a few tens of nanometers. Here we report on silicide clustering occurring within the channel of PtSi/Si/PtSi Schottky barrier transistors. This phenomenon is investigated through atomistic simulations and low-temperature resonant tunneling spectroscopy. Our results provide evidence for the segregation of a PtSi cluster with a diameter of a few nanometers from the silicide contact. The cluster acts as metallic quantum dot giving rise to distinct signatures of quantum transport through its discrete energy states.

Published
2014
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32. Control of the ionization state of 3 single donor atoms in silicon

Author

Voisin, Benoit, Cobian, Manuel, Jehl, Xavier, Niquet, Yann-Michel, Delerue, Christophe, De Franceschi, Silvano, and Sanquer, Marc

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

By varying the gate and substrate voltage in a short silicon-on-insulator trigate field effect transistor we control the ionization state of three arsenic donors. We obtain a good quantitative agreement between 3D electrostatic simulation and experiment for the control voltage at which the ionization takes place. It allows us observing the three doubly occupied states As- at strong electric field in the presence of nearby source-drain electrodes., Comment: 18 pages, 5 figures, submitted to Physical Review B

Published
2014
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33. When matter and information merge into “Quantum”

Author

Cervera-Lierta, Alba [0000-0002-8835-2910], de Franceschi, Silvano [0000-0002-1347-9693], Díez Muiño, Ricardo [0000-0001-8593-0327], García Ripoll, Juan José [0000-0001-8993-4624], Levi-Yeyati, Alfredo [0000-0001-5668-6636], Platero, Gloria [0000-0001-8610-0675], Roche, Stephan [0000-0003-0323-4665], Aguado, Ramón, Cervera-Lierta, Alba, Correia, Antonio, de Franceschi, Silvano, Díez Muiño, Ricardo, García Ripoll, Juan José, Levi-Yeyati, Alfredo, Platero, Gloria, Roche, Stephan, Sánchez-Portal, Daniel, Cervera-Lierta, Alba [0000-0002-8835-2910], de Franceschi, Silvano [0000-0002-1347-9693], Díez Muiño, Ricardo [0000-0001-8593-0327], García Ripoll, Juan José [0000-0001-8993-4624], Levi-Yeyati, Alfredo [0000-0001-5668-6636], Platero, Gloria [0000-0001-8610-0675], Roche, Stephan [0000-0003-0323-4665], Aguado, Ramón, Cervera-Lierta, Alba, Correia, Antonio, de Franceschi, Silvano, Díez Muiño, Ricardo, García Ripoll, Juan José, Levi-Yeyati, Alfredo, Platero, Gloria, Roche, Stephan, and Sánchez-Portal, Daniel

Abstract

Despite only being its 3rd edition, the QUANTUM MATTER international conference & expo (QUANTUMatter) has already become a reference event for communities involved in the study of quantum materials, quantum information and quantum technologies at large. This article reports on this meeting, which took place in Madrid, in June 2023, with 420 participants and keynote speakers from all areas of quantum technologies and quantum materials.

Published
2023

34. Spin-resolved Andreev levels and parity crossings in hybrid superconductor-semiconductor nanostructures

Author

Lee, Eduardo J. H., Jiang, Xiaocheng, Houzet, Manuel, Aguado, Ramon, Lieber, Charles M., and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The hybrid combination of superconductors and low-dimensional semiconductors offers a versatile ground for novel device concepts, such as sources of spin-entangled electrons, nanoscale superconducting magnetometers, or recently proposed qubits based on topologically protected Majorana fermions. The underlying physics behind such hybrid devices ultimately rely on the magnetic properties of sub-gap excitations, known as Andreev levels. Here we report the Zeeman effect on the Andreev levels of a semiconductor nanowire quantum dot (QD) strongly coupled to a conventional superconductor. The combination of the large QD g-factor with the large superconductor critical magnetic field allows spin degeneracy to be lifted without suppressing superconductivity. We show that a Zeeman-split Andreev level crossing the Fermi energy signals a quantum phase transition in the ground state of the superconductivity-induced QD, denoting a change in the fermionic parity of the system. This transition manifests itself as a zero-bias conductance anomaly appearing at a finite magnetic field, with properties that resemble those expected for Majorana fermions in a topological superconductor. Although the herein reported zero-bias anomalies do not hold any relation with topological superconductivity, the observed parity transitions can be regarded as precursors of Majorana modes in the long-wire limit., Comment: 16 pages, 9 figures

Published
2013
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36. Multifunctional Devices and Logic Gates With Undoped Silicon Nanowires

Author

Mongillo, Massimo, Spathis, Panayotis, Katsaros, Georgios, Gentile, Pascal, and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on the electronic transport properties of multiple-gate devices fabricated from undoped silicon nanowires. Understanding and control of the relevant transport mechanisms was achieved by means of local electrostatic gating and temperature dependent measurements. The roles of the source/drain contacts and of the silicon channel could be independently evaluated and tuned. Wrap gates surrounding the silicide-silicon contact interfaces were proved to be effective in inducing a full suppression of the contact Schottky barriers, thereby enabling carrier injection down to liquid-helium temperature. By independently tuning the effective Schottky barrier heights, a variety of reconfigurable device functionalities could be obtained. In particular, the same nanowire device could be configured to work as a Schottky barrier transistor, a Schottky diode or a p-n diode with tunable polarities. This versatility was eventually exploited to realize a NAND logic gate with gain well above one., Comment: 6 pages, 5 figures

Published
2012
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37. Monolithic growth of ultra-thin Ge nanowires on Si(001)

Author

Zhang, Jianjun, Katsaros, Georgios, Montalenti, Francesco, Scopece, Daniele, Rezaev, Roman O., Mickel, Christine, Rellinghaus, Bernd, Miglio, Leo, De Franceschi, Silvano, Rastelli, Armando, and Schmidt, Oliver G.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Self-assembled Ge wires with a height of only 3 unit cells and a length of up to 2 micrometers were grown on Si(001) by means of a catalyst-free method based on molecular beam epitaxy. The wires grow horizontally along either the [100] or the [010] direction. On atomically flat surfaces, they exhibit a highly uniform, triangular cross section. A simple thermodynamic model accounts for the existence of a preferential base width for longitudinal expansion, in quantitative agreement with the experimental findings. Despite the absence of intentional doping, first transistor-type devices made from single wires show low-resistive electrical contacts and single hole transport at sub-Kelvin temperatures. In view of their exceptionally small and self-defined cross section, these Ge wires hold promise for the realization of hole systems with exotic properties and provide a new development route for silicon-based nanoelectronics., Comment: 23 pages, 5 figures

Published
2012
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38. Zero-bias anomaly in a nanowire quantum dot coupled to superconductors

Author

Lee, Eduardo J. H., Jiang, Xiaocheng, Aguado, Ramon, Katsaros, Giorgos, Lieber, Charles M., and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We studied the low-energy states of spin-1/2 quantum dots defined in InAs/InP nanowires and coupled to aluminium superconducting leads. By varying the superconducting gap, \Delta, with a magnetic field, B, we investigated the transition from strong coupling, \Delta << T_{K}, to weak coupling, \Delta >> T_{K}, where T_{K} is the Kondo temperature. Below the critical field, we observe a persisting zero-bias Kondo resonance that vanishes only for low B or higher temperatures, leaving the room to more robust sub-gap structures at bias voltages between \Delta and 2\Delta. For strong and approximately symmetric tunnel couplings, a Josephson supercurrent is observed in addition to the Kondo peak. We ascribe the coexistence of a Kondo resonance and a superconducting gap to a significant density of intra-gap quasiparticle states, and the finite-bias sub-gap structures to tunneling through Shiba states. Our results, supported by numerical calculations, own relevance also in relation to tunnel-spectroscopy experiments aiming at the observation of Majorana fermions in hybrid nanostructures., Comment: 11 pages, 7 figures

Published
2012
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39. Joule-assisted silicidation for short-channel silicon nanowire devices

Author

Mongillo, Massimo, Spathis, Panayotis, Katsaros, Georgios, Gentile, Pascal, Sanquer, Marc, and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report on a technique enabling electrical control of the contact silicidation process in silicon nanowire devices. Undoped silicon nanowires were contacted by pairs of nickel electrodes and each contact was selectively silicided by means of the Joule effect. By a realtime monitoring of the nanowire electrical resistance during the contact silicidation process we were able to fabricate nickel-silicide/silicon/nickel- silicide devices with controlled silicon channel length down to 8 nm., Comment: 6 pages, 4 figures

Published
2011
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40. Andreev reflection versus Coulomb blockade in hybrid semiconductor nanowire devices

Author

Doh, Yong-Joo, De Franceschi, Silvano, Bakkers, Erik P. A. M., and Kouwenhoven, Leo P.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Semiconductor nanowires provide promising low-dimensional systems for the study of quantum transport phenomena in combination with superconductivity. Here we investigate the competition between the Coulomb blockade effect, Andreev reflection, and quantum interference, in InAs and InP nanowires connected to aluminum-based superconducting electrodes. We compare three limiting cases depending on the tunnel coupling strength and the characteristic Coulomb interaction energy. For weak coupling and large charging energy, negative differential conductance is observed as a direct consequence of the BCS density of states in the leads. For intermediate coupling and charging energy smaller than the superconducting gap, the current-voltage characteristic is dominated by Andreev reflection and Coulomb blockade produces an effect only near zero bias. For almost ideal contact transparencies and negligible charging energy, we observe universal conductance fluctuations whose amplitude is enhanced due to Andreev reflection at the contacts., Comment: 13 pages, 5 figures

Published
2008
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41. Quantum Interference Effects in InAs Semiconductor Nanowires

Author

Doh, Yong-Joo, Roest, Aarnoud L., Bakkers, Erik P. A. M., De Franceschi, Silvano, and Kouwenhoven, Leo P.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

We report quantum interference effects in InAs semiconductor nanowires strongly coupled to superconducting electrodes. In the normal state, universal conductance fluctuations are investigated as a function of magnetic field, temperature, bias and gate voltage. The results are found to be in good agreement with theoretical predictions for weakly disordered one-dimensional conductors. In the superconducting state, the fluctuation amplitude is enhanced by a factor up to ~ 1.6, which is attributed to a doubling of charge transport via Andreev reflection. At a temperature of 4.2 K, well above the Thouless temperature, conductance fluctuations are almost entirely suppressed, and the nanowire conductance exhibits anomalous quantization in steps of e^{2}/h., Comment: 9 pages, 3 figures

Published
2007
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42. Supercurrent reversal in quantum dots

Author

van Dam, Jorden A., Nazarov, Yuli V., Bakkers, Erik P. A. M., De Franceschi, Silvano, and Kouwenhoven, Leo P.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

When two superconductors become electrically connected by a weak link a zero-resistance supercurrent can flow. This supercurrent is carried by Cooper pairs of electrons with a combined charge of twice the elementary charge, e. The 2e charge quantum is clearly visible in the height of Shapiro steps in Josephson junctions under microwave irradiation and in the magnetic flux periodicity of h/2e in superconducting quantum interference devices. Several different materials have been used to weakly couple superconductors, such as tunnel barriers, normal metals, or semiconductors. Here, we study supercurrents through a quantum dot created in a semiconductor nanowire by local electrostatic gating. Due to strong Coulomb interaction, electrons only tunnel one-by-one through the discrete energy levels of the quantum dot. This nevertheless can yield a supercurrent when subsequent tunnel events are coherent. These quantum coherent tunnelling processes can result in either a positive or a negative supercurrent, i.e. in a normal or a pi-junction, respectively. We demonstrate that the supercurrent reverses sign by adding a single electron spin to the quantum dot. When excited states of the quantum dot are involved in transport, the supercurrent sign also depends on the character of the orbital wavefunctions.

Published
2006
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43. Tunable Supercurrent Through Semiconductor Nanowires

Author

Doh, Yong-Joo, van Dam, Jorden A., Roest, Aarnoud L., Bakkers, Erik P. A. M., Kouwenhoven, Leo P., and De Franceschi, Silvano

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Nanoscale superconductor-semiconductor hybrid devices are assembled from InAs semiconductor nanowires individually contacted by aluminum-based superconductor electrodes. Below 1 K, the high transparency of the contacts gives rise to proximity-induced superconductivity. The nanowires form superconducting weak links operating as mesoscopic Josephson junctions with electrically tunable coupling. The supercurrent can be switched on/off by a gate voltage acting on the electron density in the nanowire. A variation in gate voltage induces universal fluctuations in the normal-state conductance which are clearly correlated to critical current fluctuations. The ac Josephson effect gives rise to Shapiro steps in the voltage-current characteristic under microwave irradiation., Comment: 9 pages, 3 figures

Published
2005
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44. Orbital Kondo effect in carbon nanotubes

Author

Jarillo-Herrero, Pablo, Kong, Jing, van der Zant, Herre S. J., Dekker, Cees, Kouwenhoven, Leo P., and De Franceschi, Silvano

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons
Abstract

Progress in the fabrication of nanometer-scale electronic devices is opening new opportunities to uncover the deepest aspects of the Kondo effect, one of the paradigmatic phenomena in the physics of strongly correlated electrons. Artificial single-impurity Kondo systems have been realized in various nanostructures, including semiconductor quantum dots, carbon nanotubes and individual molecules. The Kondo effect is usually regarded as a spin-related phenomenon, namely the coherent exchange of the spin between a localized state and a Fermi sea of electrons. In principle, however, the role of the spin could be replaced by other degrees of freedom, such as an orbital quantum number. Here we demonstrate that the unique electronic structure of carbon nanotubes enables the observation of a purely orbital Kondo effect. We use a magnetic field to tune spin-polarized states into orbital degeneracy and conclude that the orbital quantum number is conserved during tunneling. When orbital and spin degeneracies are simultaneously present, we observe a strongly enhanced Kondo effect, with a multiple splitting of the Kondo resonance at finite field and predicted to obey a so-called SU(4) symmetry., Comment: 26 pages, including 4+2 figures

Published
2005
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45. Gate-based high fidelity spin readout in a CMOS device

Author

Urdampilleta, Matias, Niegemann, David J., Chanrion, Emmanuel, Jadot, Baptiste, Spence, Cameron, Mortemousque, Pierre-André, Bäuerle, Christopher, Hutin, Louis, Bertrand, Benoit, Barraud, Sylvain, Maurand, Romain, Sanquer, Marc, Jehl, Xavier, De Franceschi, Silvano, Vinet, Maud, and Meunier, Tristan

Published
2019
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46. Suppression of the Kondo Effect in a Quantum Dot by Microwave Radiation

Author

Elzerman, Jeroen M., De Franceschi, Silvano, Goldhaber-Gordon, David, van der Wiel, Wilfred G., and Kouwenhoven, Leo P.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons
Abstract

We have studied the influence of microwave radiation on the transport properties of a semiconductor quantum dot in the Kondo regime. In the entire frequency range tested (10--50 GHz), the Kondo resonance vanishes by increasing the microwave power. This suppression of the Kondo resonance shows an unexpected scaling behavior. No evidence for photon-sideband formation is found. The comparison with temperature-dependence measurements indicates that radiation-induced spin dephasing plays an important role in the suppression of the Kondo effect., Comment: 15 pages

Published
1999

47. Epitaxy of Group-IV Semiconductors for Quantum Electronics

Author

Hartmann, Jean-Michel, primary, Bernier, Nicolas, additional, Pierre, Francois, additional, Barnes, Jean-Paul, additional, Mazzocchi, Vincent, additional, Krawczyk, Julia, additional, Lima, Gabriel, additional, Kiyooka, Elyjah, additional, and De Franceschi, Silvano, additional

Published
2023
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49. Andreev reflection in Si-engineered Al/InGaAs hybrid junctions

Author

De Franceschi, Silvano, Giazotto, Francesco, Beltram, Fabio, Sorba, Lucia, Lazzarino, Marco, and Franciosi, Alfonso

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Andreev-reflection dominated transport is demonstrated in Al/n-In0.38Ga0.62As superconductor-semiconductor junctions grown by molecular beam epitaxy on GaAs(001). High junction transparency was achieved in low-doped devices by exploiting Si interface bilayers to suppress the native Schottky barrier. It is argued that this technique is ideally suited for the fabrication of ballistic transport hybrid microstructures., Comment: 9 REVTEX pages + 3 postscript figures, to be published in APL 73, (28dec98)

Published
1998
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