Search

Your search keyword '"Chakram S"' showing total 38 results
Start Over Author "Chakram S"
38 results on '"Chakram S"'

1. Tailoring the Energy Gap of Hybrid Hexagonal Boron Nitride Sheets Embedded with Carbon Domains of Different Shapes and Sizes

Author

Kah, Cherno B., Yu, M., and Jayanthi, Chakram S.

Subjects
Condensed Matter - Materials Science
Abstract

We present in this work the size-dependent and shape-dependent properties of carbon domains in hybrid h-BN/C sheets with the goal of tailoring their energy gaps. We have considered triangular, hexagonal, circular, and rectangular carbon domains embedded in h-BN sheets and optimized the structure of these h-BN/C sheets using the recently developed semi-empirical method, referred as SCED-LCAO. Calculated energy gaps of hybrid h-BN/C sheets exhibit interesting size- and shape-dependent properties. The energy gap of h-BN/C sheets embedded with rectangular domains shows a semi-metal behavior, while the size-dependence of the energy gap of hexagonal carbon domains exhibit a power-law decrease, and that of the energy gap of h-BN/C sheets with circular carbon domains show an oscillatory behavior. It is evident from the density of states calculations that the reduction in the energy gap of hybrid h-BN/C sheets compared to pristine h-BN sheets mainly arises from carbon domains. The bond distortions due to competing bond lengths (C-C, C-B, C-N, B-N, etc.) at the domain boundary also introduce states in the gap and this is particularly evident in sheets with smaller carbon domains., Comment: 21 pages, 7 figures, and 2 tables

Published
2020

2. Deterministic Bidirectional Communication and Remote Entanglement Generation Between Superconducting Quantum Processors

Author

Leung, N., Lu, Y., Chakram, S., Naik, R. K., Earnest, N., Ma, R., Jacobs, K., Cleland, A. N., and Schuster, D. I.

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

We propose and experimentally demonstrate a simple and efficient scheme for photonic communication between two remote superconducting modules. Each module consists of a random access quantum information processor with eight-qubit multimode memory and a single flux tunable transmon. The two processor chips are connected through a one-meter long coaxial cable that is coupled to a dedicated "communication" resonator on each chip. The two communication resonators hybridize with a mode of the cable to form a dark "communication mode" that is highly immune to decay in the coaxial cable. We modulate the transmon frequency via a parametric drive to generate sideband interactions between the transmon and the communication mode. We demonstrate bidirectional single-photon transfer with a success probability exceeding 60 %, and generate an entangled Bell pair with a fidelity of 79.3 $\pm$ 0.3 %.

Published
2018

3. Random access quantum information processors

Author

Naik, R. K., Leung, N., Chakram, S., Groszkowski, P., Lu, Y., Earnest, N., McKay, D. C., Koch, Jens, and Schuster, D. I.

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

Qubit connectivity is an important property of a quantum processor, with an ideal processor having random access -- the ability of arbitrary qubit pairs to interact directly. Here, we implement a random access superconducting quantum information processor, demonstrating universal operations on a nine-bit quantum memory, with a single transmon serving as the central processor. The quantum memory uses the eigenmodes of a linear array of coupled superconducting resonators. The memory bits are superpositions of vacuum and single-photon states, controlled by a single superconducting transmon coupled to the edge of the array. We selectively stimulate single-photon vacuum Rabi oscillations between the transmon and individual eigenmodes through parametric flux modulation of the transmon frequency, producing sidebands resonant with the modes. Utilizing these oscillations for state transfer, we perform a universal set of single- and two-qubit gates between arbitrary pairs of modes, using only the charge and flux bias of the transmon. Further, we prepare multimode entangled Bell and GHZ states of arbitrary modes. The fast and flexible control, achieved with efficient use of cryogenic resources and control electronics, in a scalable architecture compatible with state-of-the-art quantum memories is promising for quantum computation and simulation., Comment: 7 pages, 5 figures, supplementary information ancillary file, 21 pages

Published
2017
Full Text
View/download PDF

4. Publisher Correction: Random access quantum information processors using multimode circuit quantum electrodynamics.

Author

Naik, RK, Leung, N, Chakram, S, Groszkowski, Peter, Lu, Y, Earnest, N, McKay, DC, Koch, Jens, and Schuster, DI

Abstract

In the original version of this Article, the affiliation details for Peter Groszkowski and Jens Koch were incorrectly given as 'Department of Physics, University of Chicago, Chicago, IL, 60637, USA', instead of the correct 'Department of Physics and Astronomy, Northwestern University, Evanston, Illinois 60208, USA'. This has now been corrected in both the PDF and HTML versions of the Article.

Published
2018

5. Random access quantum information processors using multimode circuit quantum electrodynamics.

Author

Naik, RK, Leung, N, Chakram, S, Groszkowski, Peter, Lu, Y, Earnest, N, McKay, DC, Koch, Jens, and Schuster, DI

Subjects
quant-ph, cond-mat.mes-hall, cond-mat.supr-con
Abstract

Qubit connectivity is an important property of a quantum processor, with an ideal processor having random access-the ability of arbitrary qubit pairs to interact directly. This a challenge with superconducting circuits, as state-of-the-art architectures rely on only nearest-neighbor coupling. Here, we implement a random access superconducting quantum information processor, demonstrating universal operations on a nine-qubit memory, with a Josephson junction transmon circuit serving as the central processor. The quantum memory uses the eigenmodes of a linear array of coupled superconducting resonators. We selectively stimulate vacuum Rabi oscillations between the transmon and individual eigenmodes through parametric flux modulation of the transmon frequency. Utilizing these oscillations, we perform a universal set of quantum gates on 38 arbitrary pairs of modes and prepare multimode entangled states, all using only two control lines. We thus achieve hardware-efficient random access multi-qubit control in an architecture compatible with long-lived microwave cavity-based quantum memories.

Published
2017

6. Nonlinear Phonon Interferometry at the Heisenberg Limit

Author

Cheung, H. F. H., Patil, Y. S., Chang, L., Chakram, S., and Vengalattore, M.

Subjects
Quantum Physics
Abstract

Interferometers operating at or close to quantum limits of precision have found wide application in tabletop searches for physics beyond the standard model, the study of fundamental forces and symmetries of nature and foundational tests of quantum mechanics. The limits imposed by quantum fluctuations and measurement backaction on conventional interferometers ($\delta \phi \sim 1/\sqrt{N}$) have spurred the development of schemes to circumvent these limits through quantum interference, multiparticle interactions and entanglement. A prominent example of such schemes, the so-called $SU(1,1)$ interferometer, has been shown to be particularly robust against particle loss and inefficient detection, and has been demonstrated with photons and ultracold atoms. Here, we realize a $SU(1,1)$ interferometer in a fundamentally new platform in which the interfering arms are distinct flexural modes of a millimeter-scale mechanical resonator. We realize up to 15.4(3) dB of noise squeezing and demonstrate the Heisenberg scaling of interferometric sensitivity ($\delta \phi \sim 1/N$), corresponding to a 6-fold improvement in measurement precision over a conventional interferometer. Our work extends the optomechanical toolbox for the quantum manipulation of macroscopic mechanical motion and presents new avenues for studies of optomechanical sensing and the nonequilibrium dynamics of multimode optomechanical systems.

Published
2016

8. Multimode phononic correlations in a nondegenerate parametric amplifier

Author

Chakram, S., Patil, Y. S., and Vengalattore, M.

Subjects
Quantum Physics
Abstract

We describe the realization of multimode phononic correlations that arise from nonlinear interactions in a mechanical nondegenerate parametric amplifier. The nature of these correlations differs qualitatively depending on the strength of the driving field in relation to the threshold for parametric instability. Below this threshold, the correlations are manifest in a combined quadrature of the coupled mechanical modes. In this regime, the system is amenable to back-action evading measurement schemes for the detection of weak forces. Above threshold, the correlations are manifest in the amplitude difference between the two mechanical modes, akin to intensity difference squeezing observed in optical parametric oscillators. We discuss the crossover of correlations between these two regimes and applications of this quantum-compatible mechanical system to nonlinear metrology and out-of-equilibrium dynamics.

Published
2014

9. Quantum Control by Imaging : The Zeno effect in an ultracold lattice gas

Author

Patil, Y. S., Chakram, S., and Vengalattore, M.

Subjects
Condensed Matter - Quantum Gases, Quantum Physics
Abstract

We demonstrate the control of quantum tunneling in an ultracold lattice gas by the measurement backaction imposed by an imaging process. A {\em in situ} imaging technique is used to acquire repeated images of an ultracold gas confined in a shallow optical lattice. The backaction induced by these position measurements modifies the coherent quantum tunneling of atoms within the lattice. By smoothly varying the rate at which spatial information is extracted from the atomic ensemble, we observe the continuous crossover from the 'weak measurement regime' where position measurements have little influence on the tunneling dynamics, to the 'strong measurement regime' where measurement-induced localization causes a large suppression of tunneling. This suppression of coherent tunneling is a manifestation of the Quantum Zeno effect. Our study realizes an experimental demonstration of the paradigmatic Heisenberg microscope in a lattice gas and sheds light on the implications of quantum measurement on the coherent evolution of a mesoscopic quantum system. In addition, this demonstrates a powerful technique for the control of an interacting many-body quantum system via spatially resolved measurement backaction.

Published
2014
Full Text
View/download PDF

10. Thermomechanical two-mode squeezing in an ultrahigh $Q$ membrane resonator

Author

Patil, Y. S., Chakram, S., Chang, L., and Vengalattore, M.

Subjects
Quantum Physics, Physics - Atomic Physics
Abstract

We realize a nondegenerate parametric amplifier in an ultrahigh $Q$ mechanical membrane resonator and demonstrate two-mode thermomechanical noise squeezing. Our measurements are accurately described by a two-mode model that attributes this nonlinear mechanical interaction to a substrate-mediated process which is dramatically enhanced by the quality factors of the individual modes. This realization of strong multimode nonlinearities in a mechanical platform compatible with quantum-limited optical detection and cooling makes this a powerful system for nonlinear approaches to quantum metrology, transduction between optical and phononic fields and the quantum manipulation of phononic degrees of freedom.

Published
2014

11. Nondestructive imaging of an ultracold lattice gas

Author

Patil, Y. S., Aycock, L. M., Chakram, S., and Vengalattore, M.

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

We demonstrate the nondestructive imaging of a lattice gas of ultracold bosons. Atomic fluorescence is induced in the simultaneous presence of degenerate Raman sideband cooling. The combined influence of these processes controllably cycles an atom between a dark state and a fluorescing state while eliminating heating and loss. Through spatially resolved sideband spectroscopy following the imaging sequence, we demonstrate the efficacy of this imaging technique in various regimes of lattice depth and fluorescence acquisition rate. Our work provides an important extension of quantum gas imaging to the nondestructive detection, control and manipulation of atoms in optical lattices. In addition, our technique can also be extended to atomic species that are less amenable to molasses-based lattice imaging.

Published
2014
Full Text
View/download PDF

12. Dissipation in ultrahigh quality factor SiN membrane resonators

Author

Chakram, S., Patil, Y. S., Chang, L., and Vengalattore, M.

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

We study the optomechanical properties of stoichiometric SiN resonators through a combination of spectroscopic and interferometric imaging techniques. At room temperature, we demonstrate ultrahigh quality factors of $5 \times 10^7$ and a $f \times Q$ product of $1 \times 10^{14}$ Hz that, to our knowledge, correspond to the largest values yet reported for mesoscopic flexural resonators. Through a comprehensive study of the limiting dissipation mechanisms as a function of resonator and substrate geometry, we identify radiation loss through the supporting substrate as the dominant loss process. In addition to pointing the way towards higher quality factors through optimized substrate designs, our work realizes an enabling platform for the observation and control of quantum behavior in a macroscopic mechanical system coupled to a room temperature bath.

Published
2013
Full Text
View/download PDF

13. Multimode photon blockade

Author

Chakram, S, Chakram, S, He, K, Dixit, AV, Oriani, AE, Naik, RK, Leung, N, Kwon, H, Ma, WL, Jiang, L, Schuster, DI, Chakram, S, Chakram, S, He, K, Dixit, AV, Oriani, AE, Naik, RK, Leung, N, Kwon, H, Ma, WL, Jiang, L, and Schuster, DI

Abstract

Interactions are essential for the creation of correlated quantum many-body states. Although two-body interactions underlie most natural phenomena, three- and four-body interactions are important for the physics of nuclei1, exotic few-body states in ultracold quantum gases2, the fractional quantum Hall effect3, quantum error correction4 and holography5,6. Recently, a number of artificial quantum systems have emerged as simulators for many-body physics, featuring the ability to engineer strong interactions. However, the interactions in these systems have largely been limited to the two-body paradigm and require building up multibody interactions by combining two-body forces. Here we implement a scheme to create a higher-order interaction between photons stored in multiple electromagnetic modes of a microwave cavity. The system is dressed such that there is collectively no interaction until a target total photon number is reached across multiple distinct modes, at which point the photons interact strongly. In our demonstration, we create interactions involving up to three bodies and across up to five modes. We harness the interaction to prepare single-mode Fock states and multimode W states, which we verify by introducing a multimode Wigner tomography method.

Published
2022

17. Light controlled signaling initiated by subretinal semiconducting-polymer layer in developing-blind-retina mimics the response of the neonatal retina

Author

Chakram S Deepak, Abhijith Krishnan, and K S Narayan

Subjects
Retinal Ganglion Cells, Cellular and Molecular Neuroscience, Polymers, Biomedical Engineering, Infant, Newborn, Action Potentials, Humans, Photoreceptor Cells, Retina
Abstract

Optoelectronic semiconducting polymer material interfaced with a blind-developing chick-retina (E13–E18) in subretinal configuration reveals a response to full-field flash stimulus that resembles an elicited response from natural photoreceptors in a neonatal chick retina. The response manifests as evoked-firing of action potentials and was recorded using a multi-electrode array in contact with the retinal ganglion layer. Characteristics of increasing features in the signal unfold during different retina-development stages and highlight the emerging network mediated pathways typically present in the vision process of the artificial photoreceptor interfaced retina.

Published
2021

20. Thin-film nucleation through molecular cluster beam deposition: Comparison of tight-binding and many-body empirical potential molecular dynamics simulations.

Author

Hu, Yanhong, Shen, Sanguo, Liu, Lei, Jayanthi, Chakram S., Wu, Shi-Yu, and Sinnott, Susan B.

Subjects
MOLECULAR dynamics, NUCLEATION, SIMULATION methods & models
Abstract

Molecular dynamics simulations are performed to investigate the chemical products of molecular ethylene-cluster beam deposition on diamond substrates at room temperature. The substrates are hydrogen-terminated diamond (111) surfaces of varying sizes. The computational approach is molecular dynamics simulations with two different methods for determining the forces on the atoms: an empirical reactive empirical bond-order hydrocarbon potential and an order-N nonorthogonal tight-binding method. The results of these two approaches to thin-film nucleation through ethylene-cluster beam deposition are compared and contrasted. The results are used to determine the similarities, differences, advantages, and limitations of these two approaches. © 2002 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published
2002
Full Text
View/download PDF

21. Universal Stabilization of a Parametrically Coupled Qubit

Author

Lu, Yao, primary, Chakram, S., additional, Leung, N., additional, Earnest, N., additional, Naik, R. K., additional, Huang, Ziwen, additional, Groszkowski, Peter, additional, Kapit, Eliot, additional, Koch, Jens, additional, and Schuster, David I., additional

Published
2017
Full Text
View/download PDF

22. Quantum Control by Imaging : The Zeno effect in an ultracold lattice gas

Author

Yogesh Patil, Chakram, S., and Vengalattore, M.

Subjects
Condensed Matter::Quantum Gases, Quantum Physics, Quantum Gases (cond-mat.quant-gas), FOS: Physical sciences, Condensed Matter - Quantum Gases, Quantum Physics (quant-ph)
Abstract

We demonstrate the control of quantum tunneling in an ultracold lattice gas by the measurement backaction imposed by an imaging process. A {\em in situ} imaging technique is used to acquire repeated images of an ultracold gas confined in a shallow optical lattice. The backaction induced by these position measurements modifies the coherent quantum tunneling of atoms within the lattice. By smoothly varying the rate at which spatial information is extracted from the atomic ensemble, we observe the continuous crossover from the 'weak measurement regime' where position measurements have little influence on the tunneling dynamics, to the 'strong measurement regime' where measurement-induced localization causes a large suppression of tunneling. This suppression of coherent tunneling is a manifestation of the Quantum Zeno effect. Our study realizes an experimental demonstration of the paradigmatic Heisenberg microscope in a lattice gas and sheds light on the implications of quantum measurement on the coherent evolution of a mesoscopic quantum system. In addition, this demonstrates a powerful technique for the control of an interacting many-body quantum system via spatially resolved measurement backaction.

Published
2014
Full Text
View/download PDF

30. Thermomechanical Two-Mode Squeezing in an Ultrahigh-Q Membrane Resonator.

Author

Patil, Y. S., Chakram, S., Chang, L., and Vengalattore, M.

Subjects
*RESONATORS, *METALS, *THERMOMECHANICAL treatment, *PHONONIC crystals, *HIGH temperatures, *AMPLIFICATION reactions
Abstract

We realize a quantum-compatible multimode interaction in an ultrahigh Q mechanical resonator via a reservoir-mediated parametric coupling. We use this interaction to demonstrate nondegenerate parametric amplification and thermomechanical noise squeezing, finding excellent agreement with a theoretical model of this interaction over a large dynamic range. This realization of strong multimode nonlinearities in a mechanical platform compatible with quantum-limited optical detection and cooling makes this a powerful system for nonlinear approaches to quantum metrology, transduction between optical and phononic fields, and the quantum manipulation of phononic degrees of freedom. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

33. Universal Stabilization of a Parametrically Coupled Qubit.

Author

Yao Lu, Chakram, S., Leung, N., Earnest, N., Naik, R. K., Ziwen Huang, Groszkowski, Peter, Kapit, Eliot, Koch, Jens, and Schuster, David I.

Subjects
*QUBITS, *RESONATORS, *PHOTONS
Abstract

We autonomously stabilize arbitrary states of a qubit through parametric modulation of the coupling between a fixed frequency qubit and resonator. The coupling modulation is achieved with a tunable coupling design, in which the qubit and the resonator are connected in parallel to a superconducting quantum interference device. This allows for quasistatic tuning of the qubit-cavity coupling strength from 12 MHz to more than 300 MHz. Additionally, the coupling can be dynamically modulated, allowing for single-photon exchange in 6 ns. Qubit coherence times exceeding 20 µs are maintained over the majority of the range of tuning, limited primarily by the Purcell effect. The parametric stabilization technique realized using the tunable coupler involves engineering the qubit bath through a combination of photon nonconserving sideband interactions realized by flux modulation, and direct qubit Rabi driving. We demonstrate that the qubit can be stabilized to arbitrary states on the Bloch sphere with a worst-case fidelity exceeding 80%. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

34. Efficient multimode Wigner tomography.

Author

He K, Yuan M, Wong Y, Chakram S, Seif A, Jiang L, and Schuster DI

Abstract

Advancements in quantum system lifetimes and control have enabled the creation of increasingly complex quantum states, such as those on multiple bosonic cavity modes. When characterizing these states, traditional tomography scales exponentially with the number of modes in both computational and experimental measurement requirement, which becomes prohibitive as the system size increases. Here, we implement a state reconstruction method whose sampling requirement instead scales polynomially with system size, and thus mode number, for states that can be represented within such a polynomial subspace. We demonstrate this improved scaling with Wigner tomography of multimode entangled W states of up to 4 modes on a 3D circuit quantum electrodynamics (cQED) system. This approach performs similarly in efficiency to existing matrix inversion methods for 2 modes, and demonstrates a noticeable improvement for 3 and 4 modes, with even greater theoretical gains at higher mode numbers., (© 2024. The Author(s).)

Published
2024
Full Text
View/download PDF

35. Stimulated Emission of Signal Photons from Dark Matter Waves.

Author

Agrawal A, Dixit AV, Roy T, Chakram S, He K, Naik RK, Schuster DI, and Chou A

Abstract

The manipulation of quantum states of light has resulted in significant advancements in both dark matter searches and gravitational wave detectors. Current dark matter searches operating in the microwave frequency range use nearly quantum-limited amplifiers. Future high frequency searches will use photon counting techniques to evade the standard quantum limit. We present a signal enhancement technique that utilizes a superconducting qubit to prepare a superconducting microwave cavity in a nonclassical Fock state and stimulate the emission of a photon from a dark matter wave. By initializing the cavity in an |n=4⟩ Fock state, we demonstrate a quantum enhancement technique that increases the signal photon rate and hence also the dark matter scan rate each by a factor of 2.78. Using this technique, we conduct a dark photon search in a band around 5.965 GHz (24.67  μeV), where the kinetic mixing angle ε≥4.35×10^{-13} is excluded at the 90% confidence level.

Published
2024
Full Text
View/download PDF

36. Seamless High-Q Microwave Cavities for Multimode Circuit Quantum Electrodynamics.

Author

Chakram S, Oriani AE, Naik RK, Dixit AV, He K, Agrawal A, Kwon H, and Schuster DI

Abstract

Multimode cavity quantum electrodynamics-where a two-level system interacts simultaneously with many cavity modes-provides a versatile framework for quantum information processing and quantum optics. Because of the combination of long coherence times and large interaction strengths, one of the leading experimental platforms for cavity QED involves coupling a superconducting circuit to a 3D microwave cavity. In this work, we realize a 3D multimode circuit QED system with single photon lifetimes of 2 ms across 9 modes of a novel seamless cavity. We demonstrate a variety of protocols for universal single-mode quantum control applicable across all cavity modes, using only a single drive line. We achieve this by developing a straightforward flute method for creating monolithic superconducting microwave cavities that reduces loss while simultaneously allowing control of the mode spectrum and mode-qubit interaction. We highlight the flexibility and ease of implementation of this technique by using it to fabricate a variety of 3D cavity geometries, providing a template for engineering multimode quantum systems with exceptionally low dissipation. This work is an important step towards realizing hardware efficient random access quantum memories and processors, and for exploring quantum many-body physics with photons.

Published
2021
Full Text
View/download PDF

37. Searching for Dark Matter with a Superconducting Qubit.

Author

Dixit AV, Chakram S, He K, Agrawal A, Naik RK, Schuster DI, and Chou A

Abstract

Detection mechanisms for low mass bosonic dark matter candidates, such as the axion or hidden photon, leverage potential interactions with electromagnetic fields, whereby the dark matter (of unknown mass) on rare occasion converts into a single photon. Current dark matter searches operating at microwave frequencies use a resonant cavity to coherently accumulate the field sourced by the dark matter and a near standard quantum limited (SQL) linear amplifier to read out the cavity signal. To further increase sensitivity to the dark matter signal, sub-SQL detection techniques are required. Here we report the development of a novel microwave photon counting technique and a new exclusion limit on hidden photon dark matter. We operate a superconducting qubit to make repeated quantum nondemolition measurements of cavity photons and apply a hidden Markov model analysis to reduce the noise to 15.7 dB below the quantum limit, with overall detector performance limited by a residual background of real photons. With the present device, we perform a hidden photon search and constrain the kinetic mixing angle to ε≤1.68×10^{-15} in a band around 6.011 GHz (24.86  μeV) with an integration time of 8.33 s. This demonstrated noise reduction technique enables future dark matter searches to be sped up by a factor of 1,300. By coupling a qubit to an arbitrary quantum sensor, more general sub-SQL metrology is possible with the techniques presented in this Letter.

Published
2021
Full Text
View/download PDF

38. Two-Dimensional Material Tunnel Barrier for Josephson Junctions and Superconducting Qubits.

Author

Lee KH, Chakram S, Kim SE, Mujid F, Ray A, Gao H, Park C, Zhong Y, Muller DA, Schuster DI, and Park J

Abstract

Quantum computing based on superconducting qubits requires the understanding and control of the materials, device architecture, and operation. However, the materials for the central circuit element, the Josephson junction, have mostly been focused on using the AlO x tunnel barrier. Here, we demonstrate Josephson junctions and superconducting qubits employing two-dimensional materials as the tunnel barrier. We batch-fabricate and design the critical Josephson current of these devices via layer-by-layer stacking N layers of MoS 2 on the large scale. Based on such junctions, MoS 2 transmon qubits are engineered and characterized in a bulk superconducting microwave resonator for the first time. Our work allows Josephson junctions to access the diverse material properties of two-dimensional materials that include a wide range of electrical and magnetic properties, which can be used to study the effects of different material properties in superconducting qubits and to engineer novel quantum circuit elements in the future.

Published
2019
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results