Your search keyword '"Sandesh S. Kalantre"' showing total 5 results

1. Josephson detection of time-reversal symmetry broken superconductivity in SnTe nanowires

Author

Ming-Tso Wei, Christie J. Trimble, Pengzi Liu, N. F. Q. Yuan, James R. Williams, Sandesh S. Kalantre, Yan Zhu, L. Fu, Hyeuk Jin Han, Judy J. Cha, and Myung-Geun Han

Subjects

Josephson effect, Superconductivity, Physics, Condensed matter physics, Supercurrent, Nanowire, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Ferroelectricity, Symmetry (physics), Electronic, Optical and Magnetic Materials, Magnetic field, T-symmetry, Condensed Matter::Superconductivity, 0103 physical sciences, TA401-492, Atomic physics. Constitution and properties of matter, 010306 general physics, 0210 nano-technology, Materials of engineering and construction. Mechanics of materials, QC170-197

Abstract

A Josephson junction (JJ) couples the supercurrent flowing between two weakly linked superconductors to the phase difference between them via a current-phase relation (CPR). While a sinusoidal CPR is expected for conventional junctions with insulating weak links, devices made from some exotic materials may give rise to unconventional CPRs and unusual Josephson effects. In this work, we present such a case: we investigate the proximity-induced superconductivity in SnTe nanowires by incorporating them as weak links in JJs and observe a deviation from the standard CPR. We report on indications of an unexpected breaking of time-reversal symmetry in these devices, detailing the unconventional characteristics that reveal this behavior. These include an asymmetric critical current in the DC Josephson effect, a prominent second harmonic in the AC Josephson effect, and a magnetic diffraction pattern with a minimum in critical current at zero magnetic field. The analysis examines how multiband effects and the experimentally visualized ferroelectric domain walls give rise to this behavior, giving insight into the Josephson effect in materials that possess ferroelectricity and/or multiband superconductivity.

Published

2021

2. Ray-based framework for state identification in quantum dot devices

Author

Mark A. Eriksson, Justyna P. Zwolak, Jacob M. Taylor, Evan MacQuarrie, Samuel F. Neyens, Thomas McJunkin, and Sandesh S. Kalantre

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Computer science, FOS: Physical sciences, 02 engineering and technology, 01 natural sciences, Measurement cost, Article, Machine Learning (cs.LG), 0103 physical sciences, 010306 general physics, General Environmental Science, Quantum Physics, business.industry, General Engineering, Pattern recognition, 021001 nanoscience & nanotechnology, Identification (information), Quantum dot, General Earth and Planetary Sciences, Artificial intelligence, State (computer science), Quantum Physics (quant-ph), 0210 nano-technology, business, Classifier (UML)

Abstract

Quantum dots (QDs) defined with electrostatic gates are a leading platform for a scalable quantum computing implementation. However, with increasing numbers of qubits, the complexity of the control parameter space also grows. Traditional measurement techniques, relying on complete or near-complete exploration via two-parameter scans (images) of the device response, quickly become impractical with increasing numbers of gates. Here we propose to circumvent this challenge by introducing a measurement technique relying on one-dimensional projections of the device response in the multidimensional parameter space. Dubbed the ``ray-based classification (RBC) framework,'' we use this machine learning approach to implement a classifier for QD states, enabling automated recognition of qubit-relevant parameter regimes. We show that RBC surpasses the 82 % accuracy benchmark from the experimental implementation of image-based classification techniques from prior work while reducing the number of measurement points needed by up to 70 %. The reduction in measurement cost is a significant gain for time-intensive QD measurements and is a step forward toward the scalability of these devices. We also discuss how the RBC-based optimizer, which tunes the device to a multiqubit regime, performs when tuning in the two-dimensional and three-dimensional parameter spaces defined by plunger and barrier gates that control the QDs.This work provides experimental validation of both efficient state identification and optimization with machine learning techniques for non-traditional measurements in quantum systems with high-dimensional parameter spaces and time-intensive measurements., 9 pages, 4 figures

Published

2021

3. Supercurrent Interference in Semiconductor Nanowire Josephson Junctions

Author

Bhaskaran Muralidharan, Kaveh Gharavi, Jonathan Baugh, Praveen Sriram, and Sandesh S. Kalantre

Subjects

Physics, Josephson effect, Condensed matter physics, Condensed Matter - Mesoscale and Nanoscale Physics, business.industry, Dephasing, Supercurrent, Nanowire, FOS: Physical sciences, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 01 natural sciences, Topological quantum computer, symbols.namesake, Semiconductor, Condensed Matter::Superconductivity, 0103 physical sciences, Bound state, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), symbols, 010306 general physics, 0210 nano-technology, Hamiltonian (quantum mechanics), business

Abstract

Semiconductor-superconductor hybrid systems provide a promising platform for hosting unpaired Majorana fermions towards the realisation of fault-tolerant topological quantum computing. In this study, we employ the Keldysh Non-Equilibrium Green's function formalism to model quantum transport in normal-superconductor junctions. We analyze III-V semiconductor nanowire Josephson junctions (InAs/Nb) using a three-dimensional discrete lattice model described by the Bogolubov-de Gennes Hamiltonian in the tight-binding approximation, and compute the Andreev bound state spectrum and current-phase relations. Recent experiments [Zuo et al., Phys. Rev. Lett. 119,187704 (2017)] and [Gharavi et al., arXiv:1405.7455v2 (2014)] reveal critical current oscillations in these devices, and our simulations confirm these to be an interference effect of the transverse sub-bands in the nanowire. We add disorder to model coherent scattering and study its effect on the critical current oscillations, with an aim to gain a thorough understanding of the experiments. The oscillations in the disordered junction are highly sensitive to the particular realisation of the random disorder potential, and to the gate voltage. A macroscopic current measurement thus gives us information about the microscopic profile of the junction. Finally, we study dephasing in the channel by including elastic phase-breaking interactions. The oscillations thus obtained are in good qualitative agreement with the experimental data, and this signifies the essential role of phase-breaking processes in III-V semiconductor nanowire Josephson junctions., Comment: 21 pages, 18 figures, Accepted for publication in Physical Review B

Published

2019

4. Auto-tuning of double dot devices in situ with machine learning

Author

Susan Coppersmith, J. P. Dodson, Max G. Lagally, Evan MacQuarrie, Mark A. Eriksson, Donald E. Savage, Jacob M. Taylor, Justyna P. Zwolak, Sandesh S. Kalantre, and Thomas McJunkin

Subjects

Quantum Physics, Fitness function, Computer science, business.industry, General Physics and Astronomy, FOS: Physical sciences, 02 engineering and technology, Function (mathematics), 021001 nanoscience & nanotechnology, Machine learning, computer.software_genre, 01 natural sciences, Range (mathematics), Qubit, 0103 physical sciences, Path (graph theory), State (computer science), Artificial intelligence, 010306 general physics, 0210 nano-technology, Heuristics, business, Quantum Physics (quant-ph), computer, Voltage

Abstract

The current practice of manually tuning quantum dots (QDs) for qubit operation is a relatively time-consuming procedure that is inherently impractical for scaling up and applications. In this work, we report on the {\it in situ} implementation of a recently proposed autotuning protocol that combines machine learning (ML) with an optimization routine to navigate the parameter space. In particular, we show that a ML algorithm trained using exclusively simulated data to quantitatively classify the state of a double-QD device can be used to replace human heuristics in the tuning of gate voltages in real devices. We demonstrate active feedback of a functional double-dot device operated at millikelvin temperatures and discuss success rates as a function of the initial conditions and the device performance. Modifications to the training network, fitness function, and optimizer are discussed as a path toward further improvement in the success rate when starting both near and far detuned from the target double-dot range., Comment: 9 pages, 7 figures

Published

2019

5. QFlow lite dataset: A machine-learning approach to the charge states in quantum dot experiments

Author

Xingyao Wu, Sandesh S. Kalantre, Jacob M. Taylor, Stephen Ragole, and Justyna P. Zwolak

Subjects

Topography, Databases, Factual, lcsh:Medicine, 02 engineering and technology, computer.software_genre, 01 natural sciences, Convolutional neural network, Machine Learning, Automation, Software, Drug Discovery, Nanotechnology, Data Mining, lcsh:Science, Quantum computer, computer.programming_language, Islands, Quantum Physics, Multidisciplinary, Artificial neural network, Physics, Applied Mathematics, Simulation and Modeling, Condensed Matter Physics, 021001 nanoscience & nanotechnology, GO, Physical Sciences, Engineering and Technology, Quantum Computing, 0210 nano-technology, Algorithms, Research Article, Computer and Information Sciences, Neural Networks, COMPUTER, FOS: Physical sciences, Research and Analysis Methods, Machine learning, Machine Learning Algorithms, Data visualization, Artificial Intelligence, Quantum Dots, 0103 physical sciences, Electron Density, Computer Simulation, 010306 general physics, Computer Security, Landforms, Computing Systems, business.industry, Data Visualization, lcsh:R, Biology and Life Sciences, Computational Biology, Reproducibility of Results, Geomorphology, Python (programming language), Semiconductors, Earth Sciences, Programming Languages, lcsh:Q, Neural Networks, Computer, Artificial intelligence, Quantum Physics (quant-ph), business, Heuristics, computer, Mathematics, Neuroscience

Abstract

Over the past decade, machine learning techniques have revolutionized how research is done, from designing new materials and predicting their properties to assisting drug discovery to advancing cybersecurity. Recently, we added to this list by showing how a machine learning algorithm (a so-called learner) combined with an optimization routine can assist experimental efforts in the realm of tuning semiconductor quantum dot (QD) devices. Among other applications, semiconductor QDs are a candidate system for building quantum computers. The present-day tuning techniques for bringing the QD devices into a desirable configuration suitable for quantum computing that rely on heuristics do not scale with the increasing size of the quantum dot arrays required for even near-term quantum computing demonstrations. Establishing a reliable protocol for tuning that does not rely on the gross-scale heuristics developed by experimentalists is thus of great importance. To implement the machine learning-based approach, we constructed a dataset of simulated QD device characteristics, such as the conductance and the charge sensor response versus the applied electrostatic gate voltages. Here, we describe the methodology for generating the dataset, as well as its validation in training convolutional neural networks. We show that the learner's accuracy in recognizing the state of a device is ~96.5 % in both current- and charge-sensor-based training. We also introduce a tool that enables other researchers to use this approach for further research: QFlow lite - a Python-based mini-software suite that uses the dataset to train neural networks to recognize the state of a device and differentiate between states in experimental data. This work gives the definitive reference for the new dataset that will help enable researchers to use it in their experiments or to develop new machine learning approaches and concepts., Comment: 18 pages, 6 figures, 3 tables

Published

2018