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142 results on '"Zumbühl D."'

1. Charge-sensing of a Ge/Si core/shell nanowire double quantum dot using a high-impedance superconducting resonator

Author

Ungerer, J. H., Kwon, P. Chevalier, Patlatiuk, T., Ridderbos, J., Kononov, A., Sarmah, D., Bakkers, E. P. A. M., Zumbühl, D., and Schönenberger, C.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Spin qubits in germanium are a promising contender for scalable quantum computers. Reading out of the spin and charge configuration of quantum dots formed in Ge/Si core/shell nanowires is typically performed by measuring the current through the nanowire. Here, we demonstrate a more versatile approach on investigating the charge configuration of these quantum dots. We employ a high-impedance, magnetic-field resilient superconducting resonator based on NbTiN and couple it to a double quantum dot in a Ge/Si nanowire. This allows us to dispersively detect charging effects, even in the regime where the nanowire is fully pinched off and no direct current is present. Furthermore, by increasing the electro-chemical potential far beyond the nanowire pinch-off, we observe indications for depleting the last hole in the quantum dot by using the second quantum dot as a charge sensor. This work opens the door for dispersive readout and future spin-photon coupling in this system.

Published
2022
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2. Bridging the reality gap in quantum devices with physics-aware machine learning

Author

Craig, D. L., Moon, H., Fedele, F., Lennon, D. T., Van Straaten, B., Vigneau, F., Camenzind, L. C., Zumbühl, D. M., Briggs, G. A. D., Osborne, M. A., Sejdinovic, D., and Ares, N.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Machine Learning
Abstract

The discrepancies between reality and simulation impede the optimisation and scalability of solid-state quantum devices. Disorder induced by the unpredictable distribution of material defects is one of the major contributions to the reality gap. We bridge this gap using physics-aware machine learning, in particular, using an approach combining a physical model, deep learning, Gaussian random field, and Bayesian inference. This approach has enabled us to infer the disorder potential of a nanoscale electronic device from electron transport data. This inference is validated by verifying the algorithm's predictions about the gate voltage values required for a laterally-defined quantum dot device in AlGaAs/GaAs to produce current features corresponding to a double quantum dot regime.

Published
2021
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3. Cross-architecture Tuning of Silicon and SiGe-based Quantum Devices Using Machine Learning

Author

Severin, B., Lennon, D. T., Camenzind, L. C., Vigneau, F., Fedele, F., Jirovec, D., Ballabio, A., Chrastina, D., Isella, G., de Kruijf, M., Carballido, M. J., Svab, S., Kuhlmann, A. V., Braakman, F. R., Geyer, S., Froning, F. N. M., Moon, H., Osborne, M. A., Sejdinovic, D., Katsaros, G., Zumbühl, D. M., Briggs, G. A. D., and Ares, N.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Machine Learning, Quantum Physics
Abstract

The potential of Si and SiGe-based devices for the scaling of quantum circuits is tainted by device variability. Each device needs to be tuned to operation conditions. We give a key step towards tackling this variability with an algorithm that, without modification, is capable of tuning a 4-gate Si FinFET, a 5-gate GeSi nanowire and a 7-gate SiGe heterostructure double quantum dot device from scratch. We achieve tuning times of 30, 10, and 92 minutes, respectively. The algorithm also provides insight into the parameter space landscape for each of these devices. These results show that overarching solutions for the tuning of quantum devices are enabled by machine learning.

Published
2021
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4. Deep Reinforcement Learning for Efficient Measurement of Quantum Devices

Author

Nguyen, V., Orbell, S. B., Lennon, D. T., Moon, H., Vigneau, F., Camenzind, L. C., Yu, L., Zumbühl, D. M., Briggs, G. A. D., Osborne, M. A., Sejdinovic, D., and Ares, N.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Machine Learning, Quantum Physics
Abstract

Deep reinforcement learning is an emerging machine learning approach which can teach a computer to learn from their actions and rewards similar to the way humans learn from experience. It offers many advantages in automating decision processes to navigate large parameter spaces. This paper proposes a novel approach to the efficient measurement of quantum devices based on deep reinforcement learning. We focus on double quantum dot devices, demonstrating the fully automatic identification of specific transport features called bias triangles. Measurements targeting these features are difficult to automate, since bias triangles are found in otherwise featureless regions of the parameter space. Our algorithm identifies bias triangles in a mean time of less than 30 minutes, and sometimes as little as 1 minute. This approach, based on dueling deep Q-networks, can be adapted to a broad range of devices and target transport features. This is a crucial demonstration of the utility of deep reinforcement learning for decision making in the measurement and operation of quantum devices.

Published
2020
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5. Strong spin-orbit interaction and $g$-factor renormalization of hole spins in Ge/Si nanowire quantum dots

Author

Froning, F. N. M., Rančić, M. J., Hetényi, B., Bosco, S., Rehmann, M. K., Li, A., Bakkers, E. P. A. M., Zwanenburg, F. A., Loss, D., Zumbühl, D. M., and Braakman, F. R.

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

The spin-orbit interaction lies at the heart of quantum computation with spin qubits, research on topologically non-trivial states, and various applications in spintronics. Hole spins in Ge/Si core/shell nanowires experience a spin-orbit interaction that has been predicted to be both strong and electrically tunable, making them a particularly promising platform for research in these fields. We experimentally determine the strength of spin-orbit interaction of hole spins confined to a double quantum dot in a Ge/Si nanowire by measuring spin-mixing transitions inside a regime of spin-blockaded transport. We find a remarkably short spin-orbit length of $\sim$65 nm, comparable to the quantum dot length and the interdot distance. We additionally observe a large orbital effect of the applied magnetic field on the hole states, resulting in a large magnetic field dependence of the spin-mixing transition energies. Strikingly, together with these orbital effects, the strong spin-orbit interaction causes a significant enhancement of the $g$-factor with magnetic field.The large spin-orbit interaction strength demonstrated is consistent with the predicted direct Rashba spin-orbit interaction in this material system and is expected to enable ultrafast Rabi oscillations of spin qubits and efficient qubit-qubit interactions, as well as provide a platform suitable for studying Majorana zero modes.

Published
2020
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6. Ultrafast Hole Spin Qubit with Gate-Tunable Spin-Orbit Switch

Author

Froning, F. N. M., Camenzind, L. C., van der Molen, O. A. H., Li, A., Bakkers, E. P. A. M., Zumbühl, D. M., and Braakman, F. R.

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

A key challenge in quantum computation is the implementation of fast and local qubit control while simultaneously maintaining coherence. Qubits based on hole spins offer, through their strong spin-orbit interaction, a way to implement fast quantum gates. Strikingly, for hole spins in one-dimensional germanium and silicon devices, the spin-orbit interaction has been predicted to be exceptionally strong yet highly tunable with gate voltages. Such electrical control would make it possible to switch on demand between qubit idling and manipulation modes. Here, we demonstrate ultrafast and universal quantum control of a hole spin qubit in a germanium/silicon core/shell nanowire, with Rabi frequencies of several hundreds of megahertz, corresponding to spin-flipping times as short as ~1 ns - a new record for a single-spin qubit. Next, we show a large degree of electrical control over the Rabi frequency, Zeeman energy, and coherence time - thus implementing a switch toggling from a rapid qubit manipulation mode to a more coherent idling mode. We identify an exceptionally strong but gate-tunable spin-orbit interaction as the underlying mechanism, with a short associated spin-orbit length that can be tuned over a large range down to 3 nm for holes of heavy-hole mass. Our work demonstrates a spin-orbit qubit switch and establishes hole spin qubits defined in one-dimensional germanium/silicon nanostructures as a fast and highly tunable platform for quantum computation.

Published
2020
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7. Edge State Wave Functions from Momentum-Conserving Tunneling Spectroscopy

Author

Patlatiuk, T., Scheller, C. P., Hill, D., Tserkovnyak, Y., Egues, J. C., Barak, G., Yacoby, A., Pfeiffer, L. N., West, K. W., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We perform momentum-conserving tunneling spectroscopy using a GaAs cleaved-edge overgrowth quantum wire to investigate adjacent quantum Hall edge states. We use the lowest five wire modes with their distinct wave functions to probe each edge state and apply magnetic fields to modify the wave functions and their overlap. This reveals an intricate and rich tunneling conductance fan structure which is succinctly different for each of the wire modes. We self-consistently solve the Poisson-Schr\"odinger equations to simulate the spectroscopy, reproducing the striking fans in great detail, thus confirming the calculations. Further, the model predicts hybridization between wire states and Landau levels, which is also confirmed experimentally. This establishes momentum-conserving tunneling spectroscopy as a powerful technique to probe edge state wave functions., Comment: 5 pages, 5 figures

Published
2020
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8. Progress in cooling nanoelectronic devices to ultra-low temperatures

Author

Jones, A. T., Scheller, C. P., Prance, J. R., Kalyoncu, Y. B., Zumbühl, D. M., and Haley, R. P.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Here we review recent progress in cooling micro/nanoelectronic devices significantly below 10 mK. A number of groups worldwide are working to produce sub-millikelvin on-chip electron temperatures, motivated by the possibility of observing new physical effects and improving the performance of quantum technologies, sensors and metrological standards. The challenge is a longstanding one, with the lowest reported on-chip electron temperature having remained around 4 mK for more than 15 years. This is despite the fact that microkelvin temperatures have been accessible in bulk materials since the mid 20th century. In this review we describe progress made in the last five years using new cooling techniques. Developments have been driven by improvements in the understanding of nanoscale physics, material properties and heat flow in electronic devices at ultralow temperatures, and have involved collaboration between universities and institutes, physicists and engineers. We hope that this review will serve as a summary of the current state-of-the-art, and provide a roadmap for future developments. We focus on techniques that have shown, in experiment, the potential to reach sub-millikelvin electron temperatures. In particular, we focus on on-chip demagnetisation refrigeration. Multiple groups have used this technique to reach temperatures around 1 mK, with a current lowest temperature below 0.5 mK., Comment: 19 Pages, 13 Figures, 1 Table

Published
2020
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9. Quantum device fine-tuning using unsupervised embedding learning

Author

van Esbroeck, N. M., Lennon, D. T., Moon, H., Nguyen, V., Vigneau, F., Camenzind, L. C., Yu, L., Zumbühl, D. M., Briggs, G. A. D., Sejdinovic, D., and Ares, N.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Machine Learning, Quantum Physics
Abstract

Quantum devices with a large number of gate electrodes allow for precise control of device parameters. This capability is hard to fully exploit due to the complex dependence of these parameters on applied gate voltages. We experimentally demonstrate an algorithm capable of fine-tuning several device parameters at once. The algorithm acquires a measurement and assigns it a score using a variational auto-encoder. Gate voltage settings are set to optimise this score in real-time in an unsupervised fashion. We report fine-tuning times of a double quantum dot device within approximately 40 min.

Published
2020
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10. Machine learning enables completely automatic tuning of a quantum device faster than human experts

Author

Moon, H., Lennon, D. T., Kirkpatrick, J., van Esbroeck, N. M., Camenzind, L. C., Yu, Liuqi, Vigneau, F., Zumbühl, D. M., Briggs, G. A. D., Osborne, M. A, Sejdinovic, D., Laird, E. A., and Ares, N.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Machine Learning, Quantum Physics
Abstract

Device variability is a bottleneck for the scalability of semiconductor quantum devices. Increasing device control comes at the cost of a large parameter space that has to be explored in order to find the optimal operating conditions. We demonstrate a statistical tuning algorithm that navigates this entire parameter space, using just a few modelling assumptions, in the search for specific electron transport features. We focused on gate-defined quantum dot devices, demonstrating fully automated tuning of two different devices to double quantum dot regimes in an up to eight-dimensional gate voltage space. We considered a parameter space defined by the maximum range of each gate voltage in these devices, demonstrating expected tuning in under 70 minutes. This performance exceeded a human benchmark, although we recognise that there is room for improvement in the performance of both humans and machines. Our approach is approximately 180 times faster than a pure random search of the parameter space, and it is readily applicable to different material systems and device architectures. With an efficient navigation of the gate voltage space we are able to give a quantitative measurement of device variability, from one device to another and after a thermal cycle of a device. This is a key demonstration of the use of machine learning techniques to explore and optimise the parameter space of quantum devices and overcome the challenge of device variability.

Published
2020
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11. Efficiently measuring a quantum device using machine learning

Author

Lennon, D. T., Moon, H., Camenzind, L. C., Yu, Liuqi, Zumbühl, D. M., Briggs, G. A. D., Osborne, M. A., Laird, E. A., and Ares, N.

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Machine Learning
Abstract

Scalable quantum technologies will present challenges for characterizing and tuning quantum devices. This is a time-consuming activity, and as the size of quantum systems increases, this task will become intractable without the aid of automation. We present measurements on a quantum dot device performed by a machine learning algorithm. The algorithm selects the most informative measurements to perform next using information theory and a probabilistic deep-generative model, the latter capable of generating multiple full-resolution reconstructions from scattered partial measurements. We demonstrate, for two different measurement configurations, that the algorithm outperforms standard grid scan techniques, reducing the number of measurements required by up to 4 times and the measurement time by 3.7 times. Our contribution goes beyond the use of machine learning for data search and analysis, and instead presents the use of algorithms to automate measurement. This work lays the foundation for automated control of large quantum circuits.

Published
2018
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12. Radio-frequency reflectometry of a quantum dot using an ultra-low-noise SQUID amplifier

Author

Schupp, F. J., Vigneau, F., Wen, Y., Mavalankar, A., Griffiths, J., Jones, G. A. C., Farrer, I., Ritchie, D. A., Smith, C. G., Camenzind, L. C., Yu, L., Zumbühl, D. M., Briggs, G. A. D., Ares, N., and Laird, E. A.

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

Fault-tolerant spin-based quantum computers will require fast and accurate qubit readout. This can be achieved using radio-frequency reflectometry given sufficient sensitivity to the change in quantum capacitance associated with the qubit states. Here, we demonstrate a 23-fold improvement in capacitance sensitivity by supplementing a cryogenic semiconductor amplifier with a SQUID preamplifier. The SQUID amplifier operates at a frequency near 200 MHz and achieves a noise temperature below 600 mK when integrated into a reflectometry circuit, which is within a factor 120 of the quantum limit. It enables a record sensitivity to capacitance of 0.07 aF/\sqrt{Hz}. The setup is used to acquire charge stability diagrams of a gate-defined double quantum dot in a short time with a signal-to-noise ration of about 38 in 1 microsecond of integration time.

Published
2018
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13. Single, double, and triple quantum dots in Ge/Si nanowires

Author

Froning, F. N. M., Rehmann, M. K., Ridderbos, J., Brauns, M., Zwanenburg, F. A., Li, A., Bakkers, E. P. A. M., Zumbühl, D. M., and Braakman, F. R.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report highly tunable control of holes in Ge/Si core/shell nanowires (NWs). We demonstrate the ability to create single quantum dots (QDs) of various sizes, with low hole occupation numbers and clearly observable excited states. For the smallest dot size we observe indications of single-hole occupation. Moreover, we create double and triple tunnel-coupled quantum dot arrays. In the double quantum dot configuration we observe Pauli spin blockade (PSB). These results open the way to perform hole spin qubit experiments in these devices.

Published
2018
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14. On-and-off chip cooling of a Coulomb blockade thermometer down to 2.8 mK

Author

Palma, M., Scheller, C. P., Maradan, D., Feshchenko, A. V., Meschke, M., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become very small, thus creating a pronounced sensitivity to heat leaks. Here, we overcome these difficulties by using adiabatic demagnetization of \emph{both} the electronic leads \emph{and} the large metallic islands of a Coulomb blockade thermometer. This reduces the external heat leak through the leads and also provides on-chip refrigeration, together cooling the thermometer down to 2.8$\pm$0.1 mK. We present a thermal model which gives a good qualitative account and suggests that the main limitation is heating due to pulse tube vibrations. With better decoupling, temperatures below 1 mK should be within reach, thus opening the door for microkelvin nanoelectronics., Comment: 4 pages, 3 color figures

Published
2017
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15. Cross-architecture Tuning of Silicon and SiGe-based Quantum Devices Using Machine Learning

Author

Severin, B., primary, Lennon, D. T., additional, Camenzind, L. C., additional, Vigneau, F., additional, Fedele, F., additional, Jirovec, D., additional, Ballabio, A., additional, Chrastina, D., additional, Isella, G., additional, Kruijf, M., additional, Carballido, M. J., additional, Svab, S., additional, Kuhlmann, A. V., additional, Braakman, F. R., additional, Geyer, S., additional, Froning, F. N. M., additional, Moon, H., additional, Osborne, M. A., additional, Sejdinovic, D., additional, Katsaros, G., additional, Zumbühl, D. M., additional, Briggs, G. A. D., additional, and Ares, N., additional

Published
2024
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16. Intrinsic Metastabilities in the Charge Configuration of a Double Quantum Dot

Author

Biesinger, D. E. F., Scheller, C. P., Braunecker, B., Zimmerman, J., Gossard, A. C., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report a thermally activated metastability in a GaAs double quantum dot exhibiting real-time charge switching in diamond shaped regions of the charge stability diagram. Accidental charge traps and sensor back action are excluded as the origin of the switching. We present an extension of the canonical double dot theory based on an intrinsic, thermal electron exchange process through the reservoirs, giving excellent agreement with the experiment. The electron spin is randomized by the exchange process, thus facilitating fast, gate-controlled spin initialization. At the same time, this process sets an intrinsic upper limit to the spin relaxation time., Comment: 4 pages, 5 figures (color)

Published
2015
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17. Tunnel-Junction Thermometry Down to Millikelvin Temperatures

Author

Feshchenko, A. V., Casparis, L., Khaymovich, I. M., Maradan, D., Saira, O. -P., Palma, M., Meschke, M., Pekola, J. P., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present a simple on-chip electronic thermometer with the potential to operate down to 1 mK. It is based on transport through a single normal-metal - superconductor tunnel junction with rapidly widening leads. The current through the junction is determined by the temperature of the normal electrode that is efficiently thermalized to the phonon bath, and it is virtually insensitive to the temperature of the superconductor, even when the latter is relatively far from equilibrium. We demonstrate here the operation of the device down to 7 mK and present a systematic thermal analysis., Comment: 9 pages, 6 figures

Published
2015
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18. Cross-architecture tuning of silicon and SiGe-based quantum devices using machine learning.

Author

Severin, B., Lennon, D. T., Camenzind, L. C., Vigneau, F., Fedele, F., Jirovec, D., Ballabio, A., Chrastina, D., Isella, G., de Kruijf, M., Carballido, M. J., Svab, S., Kuhlmann, A. V., Geyer, S., Froning, F. N. M., Moon, H., Osborne, M. A., Sejdinovic, D., Katsaros, G., and Zumbühl, D. M.

Subjects
NANOWIRE devices, MACHINE learning, QUANTUM dot devices, QUANTUM dots
Abstract

The potential of Si and SiGe-based devices for the scaling of quantum circuits is tainted by device variability. Each device needs to be tuned to operation conditions and each device realisation requires a different tuning protocol. We demonstrate that it is possible to automate the tuning of a 4-gate Si FinFET, a 5-gate GeSi nanowire and a 7-gate Ge/SiGe heterostructure double quantum dot device from scratch with the same algorithm. We achieve tuning times of 30, 10, and 92 min, respectively. The algorithm also provides insight into the parameter space landscape for each of these devices, allowing for the characterization of the regions where double quantum dot regimes are found. These results show that overarching solutions for the tuning of quantum devices are enabled by machine learning. [ABSTRACT FROM AUTHOR]

Published
2024
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19. Prospects of silicide contacts for silicon quantum electronic devices.

Author

Tsoukalas, K., Schupp, F., Sommer, L., Bouquet, I., Mergenthaler, M., Paredes, S., Vico Triviño, N., Luisier, M., Salis, G., Harvey-Collard, P., Zumbühl, D., and Fuhrer, A.

Subjects
ELECTRONIC equipment, PLATINUM, SCHOTTKY barrier, QUANTUM dots, SILICON, METAL oxide semiconductor field-effect transistors, LOW temperatures
Abstract

Metal contacts in semiconductor quantum electronic devices can offer advantages over doped contacts, primarily due to their reduced fabrication complexity and lower temperature requirements during processing. Some metals can also facilitate ambipolar device operation or form superconducting contacts. Furthermore, a sharp metal–semiconductor interface allows for contact placement in close proximity to the active device area avoiding damage caused by dopant implantation. However, in the case of gate-defined quantum dots in intrinsic silicon, the formation of a Schottky barrier at the silicon–metal interface can lead to large, nonlinear contact resistances at cryogenic temperatures. We investigate this issue by examining hole transport through metal oxide-semiconductor transistors with platinum silicide contacts on intrinsic silicon substrates. We extract the contact and channel resistances as a function of temperature and improve the cryogenic conductance of the device by more than an order of magnitude by implementing meander-shaped contacts. In addition, we observe signatures of enhanced transport through localized defect states, which we attribute to platinum clusters in the depletion region of the Schottky contacts that form during the silicidation process. These results showcase the prospects of silicide contacts in the context of cryogenic quantum devices and address associated challenges. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Hybrid Quantum Dot-2D Electron Gas Devices for Coherent Optoelectronics

Author

Dettwiler, F., Fallahi, P., Scholz, D., Reiger, E., Schuh, D., Badolato, A., Wegscheider, W., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present an inverted GaAs 2D electron gas with self-assembled InAs quantum dots in close proximity, with the goal of combining quantum transport with quantum optics experiments. We have grown and characterized several wafers -- using transport, AFM and optics -- finding narrow-linewidth optical dots and high-mobility, single subband 2D gases. Despite being buried 500 nm below the surface, the dots are clearly visible on AFM scans, allowing precise localization and paving the way towards a hybrid quantum system integrating optical dots with surface gate-defined nanostructures in the 2D gas., Comment: 4 pages, 5 figures (color)

Published
2014

22. Silver-Epoxy Microwave Filters and Thermalizers for Millikelvin Experiments

Author

Scheller, C. P., Heizmann, S., Bedner, K., Giss, D., Meschke, M., Zumbühl, D. M., Zimmerman, J. D., and Gossard, A. C.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present Silver-epoxy filters combining excellent microwave attenuation with efficient wire thermalization, suitable for low temperature quantum transport experiments. Upon minimizing parasitic capacitances, the attenuation reaches >100 dB above ~150 MHz and - when capacitors are added - already above ~30 MHz. We measure the device electron temperature with a GaAs quantum dot and demonstrate excellent filter performance. Upon improving the sample holder and adding a second filtering stage, we obtain electron temperatures as low as 7.5 +/- 0.2 mK in metallic Coulomb blockade thermometers., Comment: 4 pages, 4 figures (color), plus supplementary information 3 pages, 1 figure (color) as ancillary arXiv pdf (SOM.pdf)

Published
2014
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23. Electrical spin protection and manipulation via gate-locked spin-orbit fields

Author

Dettwiler, F., Fu, J., Mack, S., Weigele, P. J., Egues, J. C., Awschalom, D. D., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The spin-orbit (SO) interaction couples electron spin and momentum via a relativistic, effective magnetic field. While conveniently facilitating coherent spin manipulation in semiconductors, the SO interaction also inherently causes spin relaxation. A unique situation arises when the Rashba and Dresselhaus SO fields are matched, strongly protecting spins from relaxation, as recently demonstrated. Quantum computation and spintronics devices such as the paradigmatic spin transistor could vastly benefit if such spin protection could be expanded from a single point into a broad range accessible with in-situ gate-control, making possible tunable SO rotations under protection from relaxation. Here, we demonstrate broad, independent control of all relevant SO fields in GaAs quantum wells, allowing us to tune the Rashba and Dresselhaus SO fields while keeping both locked to each other using gate voltages. Thus, we can electrically control and simultaneously protect the spin. Our experiments employ quantum interference corrections to electrical conductivity as a sensitive probe of SO coupling. Finally, we combine transport data with numerical SO simulations to precisely quantify all SO terms., Comment: 5 pages, 4 figures (color), plus supplementary information 18 pages, 8 figures (color) as ancillary arXiv pdf

Published
2014

24. GaAs Quantum Dot Thermometry Using Direct Transport and Charge Sensing

Author

Maradan, D., Casparis, L., Liu, T. -M., Biesinger, D. E. F., Scheller, C. P., Zumbühl, D. M., Zimmerman, J., and Gossard, A. C.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present measurements of the electron temperature using gate defined quantum dots formed in a GaAs 2D electron gas in both direct transport and charge sensing mode. Decent agreement with the refrigerator temperature was observed over a broad range of temperatures down to 10 mK. Upon cooling nuclear demagnetization stages integrated into the sample wires below 1 mK, the device electron temperature saturates, remaining close to 10 mK. The extreme sensitivity of the thermometer to its environment as well as electronic noise complicates temperature measurements but could potentially provide further insight into the device characteristics. We discuss thermal coupling mechanisms, address possible reasons for the temperature saturation and delineate the prospects of further reducing the device electron temperature., Comment: 8 pages, 3 (color) figures

Published
2014
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26. Transport spectroscopy of disordered graphene quantum dots etched into a single graphene flake

Author

Kölbl, D. and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present transport measurements on quantum dots of sizes 45, 60 and 80 nm etched with an Ar/O2-plasma into a single graphene sheet, allowing a size comparison avoiding effects from different graphene flakes. The transport gaps and addition energies increase with decreasing dot size, as expected, and display a strong correlation, suggesting the same physical origin for both, i.e. disorder-induced localization in presence of a small confinement gap. Gate capacitance measurements indicate that the dot charges are located in the narrow device region as intended. A dominant role of disorder is further substantiated by the gate dependence and the magnetic field behavior, allowing only approximate identification of the electron-hole crossover and spin filling sequences. Finally, we extract a g-factor consistent with g=2 within the error bars., Comment: 5 pages, 4 (color) figures

Published
2013

27. Evidence for Helical Nuclear Spin Order in GaAs Quantum Wires

Author

Scheller, C. P., Liu, T. -M., Barak, G., Yacoby, A., Pfeiffer, L. N., West, K. W., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present transport measurements of cleaved edge overgrowth GaAs quantum wires. The conductance of the first mode reaches 2 e^2/h at high temperatures T > 10 K, as expected. As T is lowered, the conductance is gradually reduced to 1 e^2/h, becoming T-independent at T < 0.1 K, while the device cools far below 0.1 K. This behavior is seen in several wires, is independent of density, and not altered by moderate magnetic fields B. The conductance reduction by a factor of two suggests lifting of the electron spin degeneracy in absence of B. Our results are consistent with theoretical predictions for helical nuclear magnetism in the Luttinger liquid regime., Comment: 5 pages, 4 figures (color)

Published
2013
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28. Evidence for Disorder Induced Delocalization in Graphite

Author

Casparis, L., Fuhrer, A., Hug, D., Kölbl, D., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Disordered Systems and Neural Networks
Abstract

We present electrical transport measurements in natural graphite and highly ordered pyrolytic graphite (HOPG), comparing macroscopic samples with exfoliated, nanofabricated specimens of nanometer thickness. The latter exhibit a very large c-axis resistivity $\rho_c$ -- much larger than expected from simple band theory -- and non-monotonic temperature dependence, similar to macroscopic HOPG, but in stark contrast to macroscopic natural graphite. A recent model of disorder-induced delocalization is consistent with our transport data. Furthermore, Micro-Raman spectroscopy reveals clearly reduced disorder in exfoliated samples and HOPG, as expected within the model -- therefore presenting further evidence for a novel paradigm of electronic transport in graphite., Comment: 5 pages, 4 figures (color)

Published
2013

29. Breakdown of the Korringa Law of Nuclear Spin Relaxation in Metallic GaAs

Author

Kölbl, D., Zumbühl, D. M., Fuhrer, A., Salis, G., and Alvarado, S. F.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Disordered Systems and Neural Networks
Abstract

We present nuclear spin relaxation measurements in GaAs epilayers using a new pump-probe technique in all-electrical, lateral spin-valve devices. The measured T1 times agree very well with NMR data available for T > 1 K. However, the nuclear spin relaxation rate clearly deviates from the well-established Korringa law expected in metallic samples and follows a sub-linear temperature dependence 1/T1 ~ T^0.6 for 0.1 K < T < 10 K. Further, we investigate nuclear spin inhomogeneities., Comment: 5 pages, 4 (color) figures. arXiv admin note: text overlap with arXiv:1109.6332

Published
2012
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30. The Nuclear Spin Environment in Lateral GaAs Spin Valves

Author

Kölbl, D., Zumbühl, D. M., Fuhrer, A., Salis, G., and Alvarado, S. F.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The spin degree of freedom in solids offers opportunities beyond charge-based electronics and is actively investigated for both spintronics and quantum computation. However, the interplay of these spins with their native environment can give rise to detrimental effects such as spin relaxation and decoherence. Here, we use an all-electrical, lateral GaAs spin valve to manipulate and investigate the inherent nuclear spin system. Hanle satellites are used to determine the nuclear spin relaxation rates for the previously unexplored temperature range down to 100 mK, giving T1 times as long as 3 hours. Despite metallic temperature dependence of resistivity, the observed relaxation rates show a sub-linear temperature dependence. This contrasts the Korringa relaxation mechanism observed in metals but is not inconsistent with hyperfine-mediated relaxation in a disordered, interacting conductor not far from the metal-insulator transition. We discuss possible relaxation mechanisms and further investigate inhomogeneities in the nuclear spin polarization., Comment: 6 pages, 4 (color) figures, Fig 1 reloaded on 111001

Published
2011

31. Method for Cooling Nanostructures to Microkelvin Temperatures

Author

Clark, A. C., Schwarzwälder, K. K., Bandi, T., Maradan, D., and Zumbühl, D. M.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We propose a new scheme aimed at cooling nanostructures to microkelvin temperatures, based on the well established technique of adiabatic nuclear demagnetization: we attach each device measurement lead to an individual nuclear refrigerator, allowing efficient thermal contact to a microkelvin bath. On a prototype consisting of a parallel network of nuclear refrigerators, temperatures of $\sim 1\,$mK simultaneously on ten measurement leads have been reached upon demagnetization, thus completing the first steps toward ultracold nanostructures., Comment: 4 pages, 3 (color) figures

Published
2010
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34. Charge-sensing of a Ge/Si core/shell nanowire double quantum dot using a high-impedance superconducting resonator

Author

Ungerer, J. H. (author), Chevalier Kwon, P. (author), Patlatiuk, T. (author), Ridderbos, J. (author), Kononov, A. (author), Sarmah, D. (author), Bakkers, E.P.A.M. (author), Zumbühl, D. (author), Schönenberger, C. (author), Ungerer, J. H. (author), Chevalier Kwon, P. (author), Patlatiuk, T. (author), Ridderbos, J. (author), Kononov, A. (author), Sarmah, D. (author), Bakkers, E.P.A.M. (author), Zumbühl, D. (author), and Schönenberger, C. (author)

Abstract

Spin qubits in germanium are a promising contender for scalable quantum computers. Reading out of the spin and charge configuration of quantum dots formed in Ge/Si core/shell nanowires is typically performed by measuring the current through the nanowire. Here, we demonstrate a more versatile approach on investigating the charge configuration of these quantum dots. We employ a high-impedance, magnetic-field resilient superconducting resonator based on NbTiN and couple it to a double quantum dot in a Ge/Si nanowire. This allows us to dispersively detect charging effects, even in the regime where the nanowire is fully pinched off and no direct current is present. Furthermore, by increasing the electro-chemical potential far beyond the nanowire pinch-off, we observe indications for depleting the last hole in the quantum dot by using the second quantum dot as a charge sensor. This work opens the door for dispersive readout and future spin-photon coupling in this system., QN/Bakkers Lab

Published
2023
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36. Sensitive radiofrequency readout of quantum dots using an ultra-low-noise SQUID amplifier.

Author

Schupp, F. J., Vigneau, F., Wen, Y., Mavalankar, A., Griffiths, J., Jones, G. A. C., Farrer, I., Ritchie, D. A., Smith, C. G., Camenzind, L. C., Yu, L., Zumbühl, D. M., Briggs, G. A. D., Ares, N., and Laird, E. A.

Subjects
SQUIDS, QUANTUM computers, INTEGRATING circuits, ELECTRIC capacity, SEMICONDUCTORS, QUANTUM computing, QUANTUM dots
Abstract

Fault-tolerant spin-based quantum computers will require fast and accurate qubit read out. This can be achieved using radiofrequency reflectometry given sufficient sensitivity to the change in quantum capacitance associated with the qubit states. Here, we demonstrate a 23-fold improvement in capacitance sensitivity by supplementing a cryogenic semiconductor amplifier with a SQUID preamplifier. The SQUID amplifier operates at a frequency near 200 MHz and achieves a noise temperature below 600 mK when integrated into a reflectometry circuit, which is within a factor 120 of the quantum limit. It enables a record sensitivity to capacitance of 0.07 aF / Hz . The setup is used to acquire charge stability diagrams of a gate-defined double quantum dot in a short time with a signal-to-noise ration of about 38 in 1 μ s of integration time. [ABSTRACT FROM AUTHOR]

Published
2020
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40. Publisher's Note: "Prospects of silicide contacts for silicon quantum electronic devices" [Appl. Phys. Lett. 125, 013501 (2024)].

Author

Tsoukalas, K., Schupp, F., Sommer, L., Bouquet, I., Mergenthaler, M., Paredes, S., Triviño, N. Vico, Luisier, M., Salis, G., Harvey-Collard, P., Zumbühl, D., and Fuhrer, A.

Subjects
SILICIDES, SILICON, ELECTRONIC equipment, INTERNET publishing
Abstract

This article was originally published online on 2 July 2024 with errors to the affiliation links for the eighth, tenth, and eleventh authors. All affiliation links are correct as they appear above.All online versions of this article were corrected on 10 July 2024.By K. Tsoukalas; F. Schupp; L. Sommer; I. Bouquet; M. Mergenthaler; S. Paredes; N. Vico Triviño; M. Luisier; G. Salis; P. Harvey-Collard; D. Zumbühl and A. FuhrerReported by Author; Author; Author; Author; Author; Author; Author; Author; Author; Author; Author; Author [Extracted from the article]

Published
2024
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41. Erratum: “Sensitive radiofrequency readout of quantum dots using an ultra-low-noise SQUID amplifier” [J. Appl. Phys. 127, 244503 (2020)]

Author

Schupp, F. J., primary, Vigneau, F., additional, Wen, Y., additional, Mavalankar, A., additional, Griffiths, J., additional, Jones, G. A. C., additional, Farrer, I., additional, Ritchie, D. A., additional, Smith, C. G., additional, Camenzind, L. C., additional, Yu, L., additional, Zumbühl, D. M., additional, Briggs, G. A. D., additional, Ares, N., additional, and Laird, E. A., additional

Published
2020
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44. Machine learning enables completely automatic tuning of a quantum device faster than human experts

Author

Moon, H., primary, Lennon, D. T., additional, Kirkpatrick, J., additional, van Esbroeck, N. M., additional, Camenzind, L. C., additional, Yu, Liuqi, additional, Vigneau, F., additional, Zumbühl, D. M., additional, Briggs, G. A. D., additional, Osborne, M. A., additional, Sejdinovic, D., additional, Laird, E. A., additional, and Ares, N., additional

Published
2020
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46. GaAs Quantum Dot Thermometry Using Direct Transport and Charge Sensing

Author

Maradan, D., Casparis, L., Liu, T.-M, Biesinger, D., Scheller, C., Zumbühl, D., Zimmerman, J., Gossard, A., Maradan, D., Casparis, L., Liu, T.-M, Biesinger, D., Scheller, C., Zumbühl, D., Zimmerman, J., and Gossard, A.

Abstract

We present measurements of the electron temperature using gate-defined quantum dots formed in a GaAs 2D electron gas in both direct transport and charge sensing mode. Decent agreement with the refrigerator temperature was observed over a broad range of temperatures down to 10mK. Upon cooling nuclear demagnetization stages integrated into the sample wires below 1mK, the device electron temperature saturates, remaining close to 10mK. The extreme sensitivity of the thermometer to its environment as well as electronic noise complicates temperature measurements but could potentially provide further insight into the device characteristics. We discuss thermal coupling mechanisms, address possible reasons for the temperature saturation and delineate the prospects of further reducing the device electron temperature.

Published
2019

47. Single, double, and triple quantum dots in Ge/Si nanowires

Author

Froning, F. N.M. (author), Rehmann, M. K. (author), Ridderbos, J. (author), Brauns, M. (author), Zwanenburg, F. A. (author), Li, A. (author), Bakkers, E.P.A.M. (author), Zumbühl, D. M. (author), Braakman, F. R. (author), Froning, F. N.M. (author), Rehmann, M. K. (author), Ridderbos, J. (author), Brauns, M. (author), Zwanenburg, F. A. (author), Li, A. (author), Bakkers, E.P.A.M. (author), Zumbühl, D. M. (author), and Braakman, F. R. (author)

Abstract

We report highly tunable control of holes in Ge/Si core/shell nanowires. We demonstrate the ability to create single quantum dots of various sizes, with low hole occupation numbers and clearly observable excited states. For the smallest dot size, we observe indications of single-hole occupation. Moreover, we create double and triple tunnel-coupled quantum dot arrays. In the double quantum dot configuration, we observe Pauli spin blockade. These results open the way to perform hole spin qubit experiments in these devices., QN/Bakkers Lab

Published
2018
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