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17 results on '"Marinelli, Brian"'

1. A Practical Introduction to Benchmarking and Characterization of Quantum Computers

Author

Hashim, Akel, Nguyen, Long B., Goss, Noah, Marinelli, Brian, Naik, Ravi K., Chistolini, Trevor, Hines, Jordan, Marceaux, J. P., Kim, Yosep, Gokhale, Pranav, Tomesh, Teague, Chen, Senrui, Jiang, Liang, Ferracin, Samuele, Rudinger, Kenneth, Proctor, Timothy, Young, Kevin C., Blume-Kohout, Robin, and Siddiqi, Irfan

Subjects
Quantum Physics
Abstract

Rapid progress in quantum technology has transformed quantum computing and quantum information science from theoretical possibilities into tangible engineering challenges. Breakthroughs in quantum algorithms, quantum simulations, and quantum error correction are bringing useful quantum computation closer to fruition. These remarkable achievements have been facilitated by advances in quantum characterization, verification, and validation (QCVV). QCVV methods and protocols enable scientists and engineers to scrutinize, understand, and enhance the performance of quantum information-processing devices. In this Tutorial, we review the fundamental principles underpinning QCVV, and introduce a diverse array of QCVV tools used by quantum researchers. We define and explain QCVV's core models and concepts -- quantum states, measurements, and processes -- and illustrate how these building blocks are leveraged to examine a target system or operation. We survey and introduce protocols ranging from simple qubit characterization to advanced benchmarking methods. Along the way, we provide illustrated examples and detailed descriptions of the protocols, highlight the advantages and disadvantages of each, and discuss their potential scalability to future large-scale quantum computers. This Tutorial serves as a guidebook for researchers unfamiliar with the benchmarking and characterization of quantum computers, and also as a detailed reference for experienced practitioners.

Published
2024

2. Quantum Digital Simulation of Cavity Quantum Electrodynamics: Insights from Superconducting and Trapped Ion Quantum Testbeds

Author

Rubin, Alex H., Marinelli, Brian, Norman, Victoria A., Rizvi, Zainab, Burch, Ashlyn D., Naik, Ravi K., Kreikebaum, John Mark, Chow, Matthew N. H., Lobser, Daniel S., Revelle, Melissa C., Yale, Christopher G., Ivory, Megan, Santiago, David I., Spitzer, Christopher, Krstic-Marinkovic, Marina, Clark, Susan M., Siddiqi, Irfan, and Radulaski, Marina

Subjects
Quantum Physics
Abstract

A leading application of quantum computers is the efficient simulation of large unitary quantum systems. Extending this advantage to the study of open Cavity Quantum Electrodynamics (CQED) systems could enable the use of quantum computers in the exploration and design of many-body quantum optical devices. Such devices have promising applications in optical quantum communication, simulation, and computing. In this work, we present an early exploration of the potential for quantum computers to efficiently investigate open CQED physics. Our simulations make use of a recent quantum algorithm that maps the dynamics of a singly excited open Tavis-Cummings model containing $N$ atoms coupled to a lossy cavity. We report the results of executing this algorithm on two noisy intermediate-scale quantum computers, a superconducting processor and a trapped ion processor, to simulate the population dynamics of an open CQED system featuring $N = 3$ atoms. By applying technology-specific transpilation and error mitigation techniques, we minimize the impact of gate errors, noise, and decoherence in each hardware platform, obtaining results which agree closely with the exact solution of the system. These results provide confidence that future simulation algorithms, combined with emerging large-scale quantum processors, can be a powerful tool for studying cavity quantum electrodynamics., Comment: 10 pages, 15 figures

Published
2024

3. Programmable Heisenberg interactions between Floquet qubits

Author

Nguyen, Long B, Kim, Yosep, Hashim, Akel, Goss, Noah, Marinelli, Brian, Bhandari, Bibek, Das, Debmalya, Naik, Ravi K, Kreikebaum, John Mark, Jordan, Andrew N, Santiago, David I, and Siddiqi, Irfan

Subjects
Quantum Physics, Physical Sciences, Mathematical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences
Abstract

The trade-off between robustness and tunability is a central challenge in the pursuit of quantum simulation and fault-tolerant quantum computation. In particular, quantum architectures are often designed to achieve high coherence at the expense of tunability. Many current qubit designs have fixed energy levels and consequently limited types of controllable interactions. Here by adiabatically transforming fixed-frequency superconducting circuits into modifiable Floquet qubits, we demonstrate an XXZ Heisenberg interaction with fully adjustable anisotropy. This interaction model can act as the primitive for an expressive set of quantum operations, but is also the basis for quantum simulations of spin systems. To illustrate the robustness and versatility of our Floquet protocol, we tailor the Heisenberg Hamiltonian and implement two-qubit iSWAP, CZ and SWAP gates with good estimated fidelities. In addition, we implement a Heisenberg interaction between higher energy levels and employ it to construct a three-qubit CCZ gate, also with a competitive fidelity. Our protocol applies to multiple fixed-frequency high-coherence platforms, providing a collection of interactions for high-performance quantum information processing. It also establishes the potential of the Floquet framework as a tool for exploring quantum electrodynamics and optimal control.

Published
2024

4. Quantum computation of frequency-domain molecular response properties using a three-qubit iToffoli gate

Author

Sun, Shi-Ning, Marinelli, Brian, Koh, Jin Ming, Kim, Yosep, Nguyen, Long B, Chen, Larry, Kreikebaum, John Mark, Santiago, David I, Siddiqi, Irfan, and Minnich, Austin J

Subjects
Quantum Physics, Physical Sciences, Theory of computation, Mathematical physics, Quantum physics
Abstract

The quantum computation of molecular response properties on near-term quantum hardware is a topic of substantial interest. Computing these properties directly in the frequency domain is desirable, but the circuits require large depth if the typical hardware gate set consisting of single- and two-qubit gates is used. While high-fidelity multipartite gates have been reported recently, their integration into quantum simulation and the demonstration of improved accuracy of the observable properties remains to be shown. Here, we report the application of a high-fidelity multipartite gate, the iToffoli gate, to the computation of frequency-domain response properties of diatomic molecules. The iToffoli gate enables a ~50% reduction in circuit depth and ~40% reduction in circuit execution time compared to the traditional gate set. We show that the molecular properties obtained with the iToffoli gate exhibit comparable or better agreement with theory than those obtained with the native CZ gates. Our work is among the first demonstrations of the practical usage of a native multi-qubit gate in quantum simulation, with diverse potential applications to near-term quantum computation.

Published
2024

5. Dynamically Reconfigurable Photon Exchange in a Superconducting Quantum Processor

Author

Marinelli, Brian, Luo, Jie, Ren, Hengjiang, Niedzielski, Bethany M., Kim, David K., Das, Rabindra, Schwartz, Mollie, Santiago, David I., and Siddiqi, Irfan

Subjects
Quantum Physics
Abstract

Realizing the advantages of quantum computation requires access to the full Hilbert space of states of many quantum bits (qubits). Thus, large-scale quantum computation faces the challenge of efficiently generating entanglement between many qubits. In systems with a limited number of direct connections between qubits, entanglement between non-nearest neighbor qubits is generated by a series of nearest neighbor gates, which exponentially suppresses the resulting fidelity. Here we propose and demonstrate a novel, on-chip photon exchange network. This photonic network is embedded in a superconducting quantum processor (QPU) to implement an arbitrarily reconfigurable qubit connectivity graph. We show long-range qubit-qubit interactions between qubits with a maximum spatial separation of $9.2~\text{cm}$ along a meandered bus resonator and achieve photon exchange rates up to $g_{\text{qq}} = 2\pi \times 0.9~\text{MHz}$. These experimental demonstrations provide a foundation to realize highly connected, reconfigurable quantum photonic networks and opens a new path towards modular quantum computing., Comment: 9 pages (+13 pages in supplement) 3 Figures (+8 in supplement)

Published
2023

6. Quantum Computation of Frequency-Domain Molecular Response Properties Using a Three-Qubit iToffoli Gate

Author

Sun, Shi-Ning, Marinelli, Brian, Koh, Jin Ming, Kim, Yosep, Nguyen, Long B., Chen, Larry, Kreikebaum, John Mark, Santiago, David I., Siddiqi, Irfan, and Minnich, Austin J.

Subjects
Quantum Physics
Abstract

The quantum computation of molecular response properties on near-term quantum hardware is a topic of significant interest. While computing time-domain response properties is in principle straightforward due to the natural ability of quantum computers to simulate unitary time evolution, circuit depth limitations restrict the maximum time that can be simulated and hence the extraction of frequency-domain properties. Computing properties directly in the frequency domain is therefore desirable, but the circuits require large depth when the typical hardware gate set consisting of single- and two-qubit gates is used. Here, we report the experimental quantum computation of the response properties of diatomic molecules directly in the frequency domain using a three-qubit iToffoli gate, enabling a reduction in circuit depth by a factor of two. We show that the molecular properties obtained with the iToffoli gate exhibit comparable or better agreement with theory than those obtained with the native CZ gates. Our work is among the first demonstrations of the practical usage of a native multi-qubit gate in quantum simulation, with diverse potential applications to the simulation of quantum many-body systems on near-term digital quantum computers., Comment: 10 pages, 6 figures

Published
2023

7. Programmable Heisenberg interactions between Floquet qubits

Author

Nguyen, Long B., Kim, Yosep, Hashim, Akel, Goss, Noah, Marinelli, Brian, Bhandari, Bibek, Das, Debmalya, Naik, Ravi K., Kreikebaum, John Mark, Jordan, Andrew N., Santiago, David I., and Siddiqi, Irfan

Subjects
Quantum Physics, Condensed Matter - Superconductivity, Physics - Applied Physics
Abstract

The fundamental trade-off between robustness and tunability is a central challenge in the pursuit of quantum simulation and fault-tolerant quantum computation. In particular, many emerging quantum architectures are designed to achieve high coherence at the expense of having fixed spectra and consequently limited types of controllable interactions. Here, by adiabatically transforming fixed-frequency superconducting circuits into modifiable Floquet qubits, we demonstrate an XXZ Heisenberg interaction with fully adjustable anisotropy. This interaction model is on one hand the basis for many-body quantum simulation of spin systems, and on the other hand the primitive for an expressive quantum gate set. To illustrate the robustness and versatility of our Floquet protocol, we tailor the Heisenberg Hamiltonian and implement two-qubit iSWAP, CZ, and SWAP gates with estimated fidelities of 99.32(3)%, 99.72(2)%, and 98.93(5)%, respectively. In addition, we implement a Heisenberg interaction between higher energy levels and employ it to construct a three-qubit CCZ gate with a fidelity of 96.18(5)%. Importantly, the protocol is applicable to various fixed-frequency high-coherence platforms, thereby unlocking a suite of essential interactions for high-performance quantum information processing. From a broader perspective, our work provides compelling avenues for future exploration of quantum electrodynamics and optimal control using the Floquet framework.

Published
2022
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8. High-Fidelity Qutrit Entangling Gates for Superconducting Circuits

Author

Goss, Noah, Morvan, Alexis, Marinelli, Brian, Mitchell, Bradley K., Nguyen, Long B., Naik, Ravi K., Chen, Larry, Jünger, Christian, Kreikebaum, John Mark, Santiago, David I., Wallman, Joel J., and Siddiqi, Irfan

Subjects
Quantum Physics, Condensed Matter - Superconductivity
Abstract

Ternary quantum information processing in superconducting devices poses a promising alternative to its more popular binary counterpart through larger, more connected computational spaces and proposed advantages in quantum simulation and error correction. Although generally operated as qubits, transmons have readily addressable higher levels, making them natural candidates for operation as quantum three-level systems (qutrits). Recent works in transmon devices have realized high fidelity single qutrit operation. Nonetheless, effectively engineering a high-fidelity two-qutrit entanglement remains a central challenge for realizing qutrit processing in a transmon device. In this work, we apply the differential AC Stark shift to implement a flexible, microwave-activated, and dynamic cross-Kerr entanglement between two fixed-frequency transmon qutrits, expanding on work performed for the $ZZ$ interaction with transmon qubits. We then use this interaction to engineer efficient, high-fidelity qutrit CZ$^\dag$ and CZ gates, with estimated process fidelities of 97.3(1)% and 95.2(3)% respectively, a significant step forward for operating qutrits on a multi-transmon device., Comment: 8 pages (+19 pages in supplement) 5 Figures (+7 in supplement)

Published
2022
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9. Author Correction: High-fidelity qutrit entangling gates for superconducting circuits

Author

Goss, Noah, Morvan, Alexis, Marinelli, Brian, Mitchell, Bradley K, Nguyen, Long B, Naik, Ravi K, Chen, Larry, Jünger, Christian, Kreikebaum, John Mark, Santiago, David I, Wallman, Joel J, and Siddiqi, Irfan

Abstract

Correction to: Nature Communications, published online 05 December 2022 The original version of this Article contained an error in the second sentence of the Acknowledgements, which incorrectly read: ‘This work was supported by the Quantum Testbed Program of the Advanced Scientific Computing Research for Basic Energy Sciences program, Office of Science of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231’. The correct version states ‘the Quantum Testbed Program of the Advanced Scientific Computing Research Division’ in place of ‘the Quantum Testbed Program of the Advanced Scientific Computing Research for Basic Energy Sciences program’. This has been corrected in both the PDF and HTML versions of the Article.

Published
2023

10. Hardware-Efficient Microwave-Activated Tunable Coupling Between Superconducting Qubits

Author

Mitchell, Bradley K., Naik, Ravi K., Morvan, Alexis, Hashim, Akel, Kreikebaum, John Mark, Marinelli, Brian, Lavrijsen, Wim, Nowrouzi, Kasra, Santiago, David I., and Siddiqi, Irfan

Subjects
Quantum Physics
Abstract

Generating high-fidelity, tunable entanglement between qubits is crucial for realizing gate-based quantum computation. In superconducting circuits, tunable interactions are often implemented using flux-tunable qubits or coupling elements, adding control complexity and noise sources. Here, we realize a tunable $ZZ$ interaction between two transmon qubits with fixed frequencies and fixed coupling, induced by driving both transmons off-resonantly. We show tunable coupling over one order of magnitude larger than the static coupling, and change the sign of the interaction, enabling cancellation of the idle coupling. Further, this interaction is amenable to large quantum processors: the drive frequency can be flexibly chosen to avoid spurious transitions, and because both transmons are driven, it is resilient to microwave crosstalk. We apply this interaction to implement a controlled phase (CZ) gate with a gate fidelity of $99.43(1)\%$ as measured by cycle benchmarking, and we find the fidelity is limited by incoherent errors., Comment: 12 pages, 7 figures

Published
2021
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11. Hardware-Efficient Microwave-Activated Tunable Coupling Between Superconducting Qubits

Author

Mitchell, Bradley K, Naik, Ravi K, Morvan, Alexis, Hashim, Akel, Kreikebaum, John Mark, Marinelli, Brian, Lavrijsen, Wim, Nowrouzi, Kasra, Santiago, David I, and Siddiqi, Irfan

Subjects
quant-ph
Abstract

Generating high-fidelity, tunable entanglement between qubits is crucial forrealizing gate-based quantum computation. In superconducting circuits, tunableinteractions are often implemented using flux-tunable qubits or couplingelements, adding control complexity and noise sources. Here, we realize atunable $ZZ$ interaction between two transmon qubits with fixed frequencies andfixed coupling, induced by driving both transmons off-resonantly. We showtunable coupling over one order of magnitude larger than the static coupling,and change the sign of the interaction, enabling cancellation of the idlecoupling. Further, this interaction is amenable to large quantum processors:the drive frequency can be flexibly chosen to avoid spurious transitions, andbecause both transmons are driven, it is resilient to microwave crosstalk. Weapply this interaction to implement a controlled phase (CZ) gate with a gatefidelity of $99.43(1)\%$ as measured by cycle benchmarking, and we find thefidelity is limited by incoherent errors.

Published
2021

14. High-fidelity qutrit entangling gates for superconducting circuits

Author

Goss, Noah, primary, Morvan, Alexis, additional, Marinelli, Brian, additional, Mitchell, Bradley K., additional, Nguyen, Long B., additional, Naik, Ravi K., additional, Chen, Larry, additional, Jünger, Christian, additional, Kreikebaum, John Mark, additional, Santiago, David I., additional, Wallman, Joel J., additional, and Siddiqi, Irfan, additional

Published
2022
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