Your search keyword '"Christopher Monroe"' showing total 244 results

1. Programmable N-Body Interactions with Trapped Ions

Author

Or Katz, Marko Cetina, and Christopher Monroe

Subjects

Physics, QC1-999, Computer software, QA76.75-76.765

Abstract

Trapped atomic ion qubits or effective spins are a powerful quantum platform for quantum computation and simulation, featuring densely connected and efficiently programmable interactions between the spins. While native interactions between trapped-ion spins are typically pairwise, many quantum algorithms and quantum spin models naturally feature couplings between triplets, quartets, or higher orders of spins. Here, we formulate and analyze a mechanism that extends the standard Mølmer-Sørensen pairwise entangling gate and generates a controllable and programmable coupling between N spins of trapped ions. We show that spin-dependent optical parametric drives applied at twice the motional frequency generate a coordinate transformation of the collective ion motion in phase space, rendering displacement forces that are nonlinear in the spin operators. We formulate a simple framework that enables a systematic and faithful construction of high-order spin Hamiltonians and gates, including the effect of multiple modes of motion, and characterize the performance of such operations under realistic conditions.

Published

2023

2. Quantum Simulation for High-Energy Physics

Author

Christian W. Bauer, Zohreh Davoudi, A. Baha Balantekin, Tanmoy Bhattacharya, Marcela Carena, Wibe A. de Jong, Patrick Draper, Aida El-Khadra, Nate Gemelke, Masanori Hanada, Dmitri Kharzeev, Henry Lamm, Ying-Ying Li, Junyu Liu, Mikhail Lukin, Yannick Meurice, Christopher Monroe, Benjamin Nachman, Guido Pagano, John Preskill, Enrico Rinaldi, Alessandro Roggero, David I. Santiago, Martin J. Savage, Irfan Siddiqi, George Siopsis, David Van Zanten, Nathan Wiebe, Yukari Yamauchi, Kübra Yeter-Aydeniz, and Silvia Zorzetti

Subjects

Physics, QC1-999, Computer software, QA76.75-76.765

Abstract

It is for the first time that quantum simulation for high-energy physics (HEP) is studied in the U.S. decadal particle-physics community planning, and in fact until recently, this was not considered a mainstream topic in the community. This fact speaks of a remarkable rate of growth of this subfield over the past few years, stimulated by the impressive advancements in quantum information sciences (QIS) and associated technologies over the past decade, and the significant investment in this area by the government and private sectors in the U.S. and other countries. High-energy physicists have quickly identified problems of importance to our understanding of nature at the most fundamental level, from tiniest distances to cosmological extents, that are intractable with classical computers but may benefit from quantum advantage. They have initiated, and continue to carry out, a vigorous program in theory, algorithm, and hardware co-design for simulations of relevance to the HEP mission. This Roadmap is an attempt to bring this exciting and yet challenging area of research to the spotlight, and to elaborate on what the promises, requirements, challenges, and potential solutions are over the next decade and beyond.

Published

2023

3. Quantum walks and Dirac cellular automata on a programmable trapped-ion quantum computer

Author

C. Huerta Alderete, Shivani Singh, Nhung H. Nguyen, Daiwei Zhu, Radhakrishnan Balu, Christopher Monroe, C. M. Chandrashekar, and Norbert M. Linke

Subjects

Science

Abstract

Implementations of quantum walks on ion trap quantum computers have been so far limited to the analogue simulation approach. Here, the authors implement a quantum-circuit-based discrete quantum walk in one-dimensional position space, realizing a Dirac cellular automaton with tunable mass parameter.

Published

2020

4. Many-Body Quantum Teleportation via Operator Spreading in the Traversable Wormhole Protocol

Author

Thomas Schuster, Bryce Kobrin, Ping Gao, Iris Cong, Emil T. Khabiboulline, Norbert M. Linke, Mikhail D. Lukin, Christopher Monroe, Beni Yoshida, and Norman Y. Yao

Subjects

Physics, QC1-999

Abstract

By leveraging shared entanglement between a pair of qubits, one can teleport a quantum state from one particle to another. Recent advances have uncovered an intrinsically many-body generalization of quantum teleportation, with an elegant and surprising connection to gravity. In particular, the teleportation of quantum information relies on many-body dynamics, which originate from strongly interacting systems that are holographically dual to gravity; from the gravitational perspective, such quantum teleportation can be understood as the transmission of information through a traversable wormhole. Here, we propose and analyze a new mechanism for many-body quantum teleportation—dubbed peaked-size teleportation. Intriguingly, peaked-size teleportation utilizes precisely the same type of quantum circuit as traversable wormhole teleportation yet has a completely distinct microscopic origin: It relies upon the spreading of local operators under generic thermalizing dynamics and not gravitational physics. We demonstrate the ubiquity of peaked-size teleportation, both analytically and numerically, across a diverse landscape of physical systems, including random unitary circuits, the Sachdev-Ye-Kitaev model (at high temperatures), one-dimensional spin chains, and a bulk theory of gravity with stringy corrections. Our results pave the way toward using many-body quantum teleportation as a powerful experimental tool for (i) characterizing the size distributions of operators in strongly correlated systems and (ii) distinguishing between generic and intrinsically gravitational scrambling dynamics. To this end, we provide a detailed experimental blueprint for realizing many-body quantum teleportation in both trapped ions and Rydberg atom arrays; effects of decoherence and experimental imperfections are analyzed.

Published

2022

5. Resource-Optimized Fermionic Local-Hamiltonian Simulation on a Quantum Computer for Quantum Chemistry

Author

Qingfeng Wang, Ming Li, Christopher Monroe, and Yunseong Nam

Subjects

Physics, QC1-999

Abstract

The ability to simulate a fermionic system on a quantum computer is expected to revolutionize chemical engineering, materials design, nuclear physics, to name a few. Thus, optimizing the simulation circuits is of significance in harnessing the power of quantum computers. Here, we address this problem in two aspects. In the fault-tolerant regime, we optimize the $R_z$ and $\textit{T gate}$ counts along with the ancilla qubit counts required, assuming the use of a product-formula algorithm for implementation. We obtain a savings ratio of two in the gate counts and a savings ratio of eleven in the number of ancilla qubits required over the state of the art. In the pre-fault tolerant regime, we optimize the two-qubit gate counts, assuming the use of the variational quantum eigensolver (VQE) approach. Specific to the latter, we present a framework that enables bootstrapping the VQE progression towards the convergence of the ground-state energy of the fermionic system. This framework, based on perturbation theory, is capable of improving the energy estimate at each cycle of the VQE progression, by about a factor of three closer to the known ground-state energy compared to the standard VQE approach in the test-bed, classically-accessible system of the water molecule. The improved energy estimate in turn results in a commensurate level of savings of quantum resources, such as the number of qubits and quantum gates, required to be within a pre-specified tolerance from the known ground-state energy. We also explore a suite of generalized transformations of fermion to qubit operators and show that resource-requirement savings of up to more than $20\%$, in small instances, is possible.

Published

2021

6. Quantum Computer Systems for Scientific Discovery

Author

Yuri Alexeev, Dave Bacon, Kenneth R. Brown, Robert Calderbank, Lincoln D. Carr, Frederic T. Chong, Brian DeMarco, Dirk Englund, Edward Farhi, Bill Fefferman, Alexey V. Gorshkov, Andrew Houck, Jungsang Kim, Shelby Kimmel, Michael Lange, Seth Lloyd, Mikhail D. Lukin, Dmitri Maslov, Peter Maunz, Christopher Monroe, John Preskill, Martin Roetteler, Martin J. Savage, and Jeff Thompson

Subjects

Physics, QC1-999, Computer software, QA76.75-76.765

Abstract

The great promise of quantum computers comes with the dual challenges of building them and finding their useful applications. We argue that these two challenges should be considered together, by codesigning full-stack quantum computer systems along with their applications in order to hasten their development and potential for scientific discovery. In this context, we identify scientific and community needs, opportunities, a sampling of a few use case studies, and significant challenges for the development of quantum computers for science over the next 2–10 years. This document is written by a community of university, national laboratory, and industrial researchers in the field of Quantum Information Science and Technology, and is based on a summary from a U.S. National Science Foundation workshop on Quantum Computing held on October 21–22, 2019 in Alexandria, VA.

Published

2021

7. Development of Quantum Interconnects (QuICs) for Next-Generation Information Technologies

Author

David Awschalom, Karl K. Berggren, Hannes Bernien, Sunil Bhave, Lincoln D. Carr, Paul Davids, Sophia E. Economou, Dirk Englund, Andrei Faraon, Martin Fejer, Saikat Guha, Martin V. Gustafsson, Evelyn Hu, Liang Jiang, Jungsang Kim, Boris Korzh, Prem Kumar, Paul G. Kwiat, Marko Lončar, Mikhail D. Lukin, David A.B. Miller, Christopher Monroe, Sae Woo Nam, Prineha Narang, Jason S. Orcutt, Michael G. Raymer, Amir H. Safavi-Naeini, Maria Spiropulu, Kartik Srinivasan, Shuo Sun, Jelena Vučković, Edo Waks, Ronald Walsworth, Andrew M. Weiner, and Zheshen Zhang

Subjects

Physics, QC1-999, Computer software, QA76.75-76.765

Abstract

Just as “classical” information technology rests on a foundation built of interconnected information-processing systems, quantum information technology (QIT) must do the same. A critical component of such systems is the “interconnect,” a device or process that allows transfer of information between disparate physical media, for example, semiconductor electronics, individual atoms, light pulses in optical fiber, or microwave fields. While interconnects have been well engineered for decades in the realm of classical information technology, quantum interconnects (QuICs) present special challenges, as they must allow the transfer of fragile quantum states between different physical parts or degrees of freedom of the system. The diversity of QIT platforms (superconducting, atomic, solid-state color center, optical, etc.) that will form a “quantum internet” poses additional challenges. As quantum systems scale to larger size, the quantum interconnect bottleneck is imminent, and is emerging as a grand challenge for QIT. For these reasons, it is the position of the community represented by participants of the NSF workshop on “Quantum Interconnects” that accelerating QuIC research is crucial for sustained development of a national quantum science and technology program. Given the diversity of QIT platforms, materials used, applications, and infrastructure required, a convergent research program including partnership between academia, industry, and national laboratories is required.

Published

2021

8. Quantum Simulators: Architectures and Opportunities

Author

Ehud Altman, Kenneth R. Brown, Giuseppe Carleo, Lincoln D. Carr, Eugene Demler, Cheng Chin, Brian DeMarco, Sophia E. Economou, Mark A. Eriksson, Kai-Mei C. Fu, Markus Greiner, Kaden R.A. Hazzard, Randall G. Hulet, Alicia J. Kollár, Benjamin L. Lev, Mikhail D. Lukin, Ruichao Ma, Xiao Mi, Shashank Misra, Christopher Monroe, Kater Murch, Zaira Nazario, Kang-Kuen Ni, Andrew C. Potter, Pedram Roushan, Mark Saffman, Monika Schleier-Smith, Irfan Siddiqi, Raymond Simmonds, Meenakshi Singh, I.B. Spielman, Kristan Temme, David S. Weiss, Jelena Vučković, Vladan Vuletić, Jun Ye, and Martin Zwierlein

Subjects

Physics, QC1-999, Computer software, QA76.75-76.765

Abstract

Quantum simulators are a promising technology on the spectrum of quantum devices from specialized quantum experiments to universal quantum computers. These quantum devices utilize entanglement and many-particle behavior to explore and solve hard scientific, engineering, and computational problems. Rapid development over the last two decades has produced more than 300 quantum simulators in operation worldwide using a wide variety of experimental platforms. Recent advances in several physical architectures promise a golden age of quantum simulators ranging from highly optimized special purpose simulators to flexible programmable devices. These developments have enabled a convergence of ideas drawn from fundamental physics, computer science, and device engineering. They have strong potential to address problems of societal importance, ranging from understanding vital chemical processes, to enabling the design of new materials with enhanced performance, to solving complex computational problems. It is the position of the community, as represented by participants of the National Science Foundation workshop on “Programmable Quantum Simulators,” that investment in a national quantum simulator program is a high priority in order to accelerate the progress in this field and to result in the first practical applications of quantum machines. Such a program should address two areas of emphasis: (1) support for creating quantum simulator prototypes usable by the broader scientific community, complementary to the present universal quantum computer effort in industry; and (2) support for fundamental research carried out by a blend of multi-investigator, multidisciplinary collaborations with resources for quantum simulator software, hardware, and education.This document is a summary from a U.S. National Science Foundation supported workshop held on 16–17 September 2019 in Alexandria, VA. Attendees were charged to identify the scientific and community needs, opportunities, and significant challenges for quantum simulators over the next 2–5 years.

Published

2021

9. Towards analog quantum simulations of lattice gauge theories with trapped ions

Author

Zohreh Davoudi, Mohammad Hafezi, Christopher Monroe, Guido Pagano, Alireza Seif, and Andrew Shaw

Subjects

Physics, QC1-999

Abstract

Gauge field theories play a central role in modern physics and are at the heart of the Standard Model of elementary particles and interactions. Despite significant progress in applying classical computational techniques to simulate gauge theories, it has remained a challenging task to compute the real-time dynamics of systems described by gauge theories. An exciting possibility that has been explored in recent years is the use of highly controlled quantum systems to simulate, in an analog fashion, properties of a target system whose dynamics are difficult to compute. Engineered atom-laser interactions in a linear crystal of trapped ions offer a wide range of possibilities for quantum simulations of complex physical systems. Here we devise practical proposals for analog simulation of simple lattice gauge theories whose dynamics can be mapped onto spin-spin interactions in any dimension. These include 1+1D quantum electrodynamics, 2+1D Abelian Chern-Simons theory coupled to fermions, and 2+1D pure Z_{2} gauge theory. The scheme proposed, along with the optimization protocol applied, will have applications beyond the examples presented in this work, and will enable scalable analog quantum simulation of Heisenberg spin models in any number of dimensions and with arbitrary interaction strengths.

Published

2020

10. Quantum repeaters based on two species trapped ions

Author

Siddhartha Santra, Sreraman Muralidharan, Martin Lichtman, Liang Jiang, Christopher Monroe, and Vladimir S Malinovsky

Subjects

quantum repeaters, two species trapped ions, quantum key distribution, Science, Physics, QC1-999

Abstract

We examine the viability of quantum repeaters based on two-species trapped ion modules for long-distance quantum key distribution. Repeater nodes comprised of ion-trap modules of co-trapped ions of distinct species are considered. The species used for communication qubits has excellent optical properties while the other longer lived species serves as a memory qubit in the modules. Each module interacts with the network only via single photons emitted by the communication ions. Coherent Coulomb interaction between ions is utilized to transfer quantum information between the communication and memory ions and to achieve entanglement swapping between two memory ions. We describe simple modular quantum repeater architectures realizable with the ion-trap modules and numerically study the dependence of the quantum key distribution rate on various experimental parameters, including coupling efficiency, gate infidelity, operation time and length of the elementary links. Our analysis suggests crucial improvements necessary in a physical implementation for co-trapped two-species ions to be a competitive platform in long-distance quantum communication.

Published

2019

11. Quantum Computing with Atoms.

Author

Christopher Monroe

Published

2021

12. Measurement-induced quantum phases realized in a trapped-ion quantum computer

Author

Crystal Noel, Pradeep Niroula, Daiwei Zhu, Andrew Risinger, Laird Egan, Debopriyo Biswas, Marko Cetina, Alexey V. Gorshkov, Michael J. Gullans, David A. Huse, and Christopher Monroe

Subjects

General Physics and Astronomy

Published

2022

13. Phase transition in magic with random quantum circuits

Author

Niroula, Pradeep, White, Christopher David, Qingfeng Wang, Sonika Johri, Daiwei Zhu, Christopher Monroe, and Michael Gullans

Abstract

Magic is a property of quantum states that enables universal fault-tolerant quantum computing using simple sets of gate operations. Understanding the mechanisms by which magic is created or destroyed is, therefore, a crucial step towards efficient and practical fault-tolerant computation. We observe that a random stabilizer code subject to coherent errors exhibits a phase transition in magic, which we characterize through analytic, numeric and experimental probes.Below a critical error rate, stabilizer syndrome measurements remove the accumulated magic in the circuit, effectively protecting against coherent errors; above the critical error rate syndrome measurements concentrate magic. A better understanding of such rich behavior in the resource theory of magic could shed more light on origins of quantum speedup and pave pathways for more efficient magic state generation.&nbsp

Published

2023

14. Fault-tolerant control of an error-corrected qubit

Author

Muyuan Li, Debopriyo Biswas, Christopher Monroe, Crystal Noel, Dripto M. Debroy, Marko Cetina, Kenneth R. Brown, Laird Egan, Daiwei Zhu, Andrew Risinger, and Michael Newman

Subjects

Multidisciplinary, Observational error, Computer science, Physical system, Quantum Physics, Topology, Noise (electronics), Computer Science::Hardware Architecture, Computer Science::Emerging Technologies, Quantum error correction, Qubit, Quantum information, Error detection and correction, Quantum

Abstract

Quantum error correction protects fragile quantum information by encoding it into a larger quantum system1,2. These extra degrees of freedom enable the detection and correction of errors, but also increase the control complexity of the encoded logical qubit. Fault-tolerant circuits contain the spread of errors while controlling the logical qubit, and are essential for realizing error suppression in practice3–6. Although fault-tolerant design works in principle, it has not previously been demonstrated in an error-corrected physical system with native noise characteristics. Here we experimentally demonstrate fault-tolerant circuits for the preparation, measurement, rotation and stabilizer measurement of a Bacon–Shor logical qubit using 13 trapped ion qubits. When we compare these fault-tolerant protocols to non-fault-tolerant protocols, we see significant reductions in the error rates of the logical primitives in the presence of noise. The result of fault-tolerant design is an average state preparation and measurement error of 0.6 per cent and a Clifford gate error of 0.3 per cent after offline error correction. In addition, we prepare magic states with fidelities that exceed the distillation threshold7, demonstrating all of the key single-qubit ingredients required for universal fault-tolerant control. These results demonstrate that fault-tolerant circuits enable highly accurate logical primitives in current quantum systems. With improved two-qubit gates and the use of intermediate measurements, a stabilized logical qubit can be achieved. Fault-tolerant circuits for the control of a logical qubit encoded in 13 trapped ion qubits through a Bacon–Shor quantum error correction code are demonstrated.

Published

2021

15. Observation of a prethermal discrete time crystal

Author

K. S. Collins, Dominic V. Else, Lei Feng, Christopher Monroe, P. Becker, Francisco Machado, W. Morong, Guido Pagano, A. Kyprianidis, Paul Hess, Chetan Nayak, and Norman Y. Yao

Subjects

Physics, Quantum Physics, Multidisciplinary, Statistical Mechanics (cond-mat.stat-mech), General Science & Technology, FOS: Physical sciences, Non-equilibrium thermodynamics, 01 natural sciences, 010305 fluids & plasmas, Crystal, Discrete time and continuous time, Quantum Gases (cond-mat.quant-gas), 0103 physical sciences, Statistical physics, Quantum Physics (quant-ph), Condensed Matter - Quantum Gases, 010306 general physics, Condensed Matter - Statistical Mechanics

Abstract

The conventional framework for defining and understanding phases of matter requires thermodynamic equilibrium. Extensions to non-equilibrium systems have led to surprising insights into the nature of many-body thermalization and the discovery of novel phases of matter, often catalyzed by driving the system periodically. The inherent heating from such Floquet drives can be tempered by including strong disorder in the system, but this can also mask the generality of non-equilibrium phases. In this work, we utilize a trapped-ion quantum simulator to observe signatures of a non-equilibrium driven phase without disorder: the prethermal discrete time crystal (PDTC). Here, many-body heating is suppressed not by disorder-induced many-body localization, but instead via high-frequency driving, leading to an expansive time window where non-equilibrium phases can emerge. We observe a number of key features that distinguish the PDTC from its many-body-localized disordered counterpart, such as the drive-frequency control of its lifetime and the dependence of time-crystalline order on the energy density of the initial state. Floquet prethermalization is thus presented as a general strategy for creating, stabilizing and studying intrinsically out-of-equilibrium phases of matter., 9 + 10 pages, 3 + 6 figures

Published

2021

16. Probing Many-Body Quantum Chaos on a Trapped Ion Quantum Simulator

Author

Christopher Monroe, Peter Zoller, Victor Galitski, Benoît Vermersch, Amit Vikram, Andreas Elben, Lata Kh Joshi, William Morong, Arinjoy De, and Kate Collins

Published

2022

17. Programmable N-body interactions with trapped ion qubits

Author

Marko Cetina, Christopher Monroe, Andrew Risinger, Lei Feng, and Or Katz

Published

2022

18. Implementing Real-Time Logical Qubit Error Detection & Correction on a Trapped Ion Quantum Computer

Author

Christopher Monroe, Marko Cetina, Or Katz, Debopriyo Biswas, Daiwei Zhu, Laird Egan, Bradley Bondurant, Crystal Noel, Daniel Lobser, Alan Bell, and Andrew Risinger

Published

2022

19. Domain-wall confinement and dynamics in a quantum simulator

Author

K. S. Collins, Wen Lin Tan, Arinjoy De, Alexey V. Gorshkov, Guido Pagano, Lei Feng, Fangli Liu, A. Kyprianidis, H. B. Kaplan, Rex Lundgren, Christopher Monroe, W. Morong, Seth Whitsitt, and P. Becker

Subjects

Quark, Physics, General Physics and Astronomy, Quantum simulator, 01 natural sciences, String (physics), 010305 fluids & plasmas, Quantum electrodynamics, 0103 physical sciences, Bound state, Quasiparticle, Color confinement, 010306 general physics, Quantum, Spin-½

Abstract

Particles subject to confinement experience an attractive potential that increases without bound as they separate. A prominent example is colour confinement in particle physics, in which baryons and mesons are produced by quark confinement. Confinement can also occur in low-energy quantum many-body systems when elementary excitations are confined into bound quasiparticles. Here we report the observation of magnetic domain-wall confinement in interacting spin chains with a trapped-ion quantum simulator. By measuring how correlations spread, we show that confinement can suppress information propagation and thermalization in such many-body systems. We quantitatively determine the excitation energy of domain-wall bound states from the non-equilibrium quench dynamics. We also study the number of domain-wall excitations created for different quench parameters, in a regime that is difficult to model with classical computers. This work demonstrates the capability of quantum simulators for investigating high-energy physics phenomena, such as quark collision and string breaking. Long-range Ising interactions present in one-dimensional spin chains can induce a confining potential between pairs of domain walls, slowing down the thermalization of the system. This has now been observed in a trapped-ion quantum simulator.

Published

2021

20. Analog-Digital Quantum Simulations with Trapped Ions

Author

Christopher Monroe, Arinjoy De, Kate Collins, and William Morong

Published

2022

21. $N$-body interactions between trapped ion qubits via spin-dependent squeezing

Author

Or Katz, Marko Cetina, and Christopher Monroe

Subjects

Quantum Physics, Computer Science::Emerging Technologies, Atomic Physics (physics.atom-ph), General Physics and Astronomy, FOS: Physical sciences, Hardware_ARITHMETICANDLOGICSTRUCTURES, Quantum Physics (quant-ph), Physics - Atomic Physics

Abstract

We describe a simple protocol for the single-step generation of $N$-body entangling interactions between trapped atomic ion qubits. We show that qubit state-dependent squeezing operations and displacement forces on the collective atomic motion can generate full $N$-body interactions. Similar to the M{\o}lmer-S{\o}rensen two-body Ising interaction at the core of most trapped ion quantum computers and simulators, the proposed operation is relatively insensitive to the state of motion. We show how this $N$-body gate operation allows the single-step implementation of a family of $N$-bit gate operations such as the powerful $N$-Toffoli gate, which flips a single qubit if and only if all other $N$-$1$ qubits are in a particular state.

Published

2022

22. Continuous Symmetry Breaking in a Trapped-Ion Spin Chain

Author

Christopher Monroe, Lei Feng, Or Katz, Casey Haack, Mohammad Maghrebi, Alexey Gorshkov, Zhexuan Gong, and Marko Cetina

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Statistical Mechanics (cond-mat.stat-mech), Strongly Correlated Electrons (cond-mat.str-el), Quantum Gases (cond-mat.quant-gas), FOS: Physical sciences, Condensed Matter - Quantum Gases, Quantum Physics (quant-ph), Condensed Matter - Statistical Mechanics

Abstract

One-dimensional systems exhibiting a continuous symmetry can host quantum phases of matter with true long-range order only in the presence of sufficiently long-range interactions. In most physical systems, however, the interactions are short-ranged, hindering the emergence of such phases in one dimension. Here we use a one-dimensional trapped-ion quantum simulator to prepare states with long-range spin order that extends over the system size of up to $23$ spins and is characteristic of the continuous symmetry-breaking phase of matter. Our preparation relies on simultaneous control over an array of tightly focused individual-addressing laser beams, generating long-range spin-spin interactions. We also observe a disordered phase with frustrated correlations. We further study the phases at different ranges of interaction and the out-of-equilibrium response to symmetry-breaking perturbations. This work opens an avenue to study new quantum phases and out-of-equilibrium dynamics in low-dimensional systems.

Published

2022

23. Cryogenic trapped-ion system for large scale quantum simulation

Author

Wen Lin Tan, Christopher Monroe, Guido Pagano, Micah Hernandez, J. Zhang, P. Becker, H. B. Kaplan, A. Kyprianidis, Yukai Wu, Eric Birckelbaw, Paul Hess, and Philip Richerme

Subjects

Cryostat, Materials science, Physics and Astronomy (miscellaneous), Atomic Physics (physics.atom-ph), Materials Science (miscellaneous), Quantum physics, Quantum simulator, FOS: Physical sciences, Cryogenics, 01 natural sciences, Ion trapping, 010305 fluids & plasmas, Ion, Physics - Atomic Physics, Physics::Plasma Physics, 0103 physical sciences, Quantum computation, Electrical and Electronic Engineering, 010306 general physics, Quantum computer, Atomic and Molecular Physics, and Optics, Elastic collision, Physical sciences, Ion trap, Atomic physics, Quantum Physics (quant-ph)

Abstract

We present a cryogenic ion trapping system designed for large scale quantum simulation of spin models. Our apparatus is based on a segmented-blade ion trap enclosed in a 4 K cryostat, which enables us to routinely trap over 100 $^{171}$Yb$^+$ ions in a linear configuration for hours due to a low background gas pressure from differential cryo-pumping. We characterize the cryogenic vacuum by using trapped ion crystals as a pressure gauge, measuring both inelastic and elastic collision rates with the molecular background gas. We demonstrate nearly equidistant ion spacing for chains of up to 44 ions using anharmonic axial potentials. This reliable production and lifetime enhancement of large linear ion chains will enable quantum simulation of spin models that are intractable with classical computer modelling., Comment: 16 pages, 11 figures

Published

2022

24. Cross-Platform Comparison of Arbitrary Quantum Computations

Author

Ze-Pei Cian, Daiwei Zhu, Crystal Noel, Andrew Risinger, Debopriyo Biswas, Laird Egan, Yingyue Zhu, Alaina Green, Cinthia Huerta Alderete, Nhung Nguyen, Qingfeng Wang, Andrii Maksymov, Yunseong Nam, Marko Cetina, Norbert Linke, Mohammad Hafezi, and Christopher Monroe

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

As we approach the era of quantum advantage, when quantum computers (QCs) can outperform any classical computer on particular tasks, there remains the difficult challenge of how to validate their performance. While algorithmic success can be easily verified in some instances such as number factoring or oracular algorithms, these approaches only provide pass/fail information for a single QC. On the other hand, a comparison between different QCs on the same arbitrary circuit provides a lower-bound for generic validation: a quantum computation is only as valid as the agreement between the results produced on different QCs. Such an approach is also at the heart of evaluating metrological standards such as disparate atomic clocks. In this paper, we report a cross-platform QC comparison using randomized and correlated measurements that results in a wealth of information on the QC systems. We execute several quantum circuits on widely different physical QC platforms and analyze the cross-platform fidelities.

Published

2021

25. Benchmarking an 11-qubit quantum computer

Author

Sarah M. Kreikemeier, Neal C. Pisenti, Matthew J. Keesan, Mike Williams, J. Mizrahi, Andrew M. Ducore, Vandiver Chaplin, Coleman Collins, Aleksey Blinov, Nikodem Grzesiak, J. D. Wong-Campos, Mika Chmielewski, Kai Hudek, Jungsang Kim, Kristin M. Beck, Yunseong Nam, Kenneth Wright, Joel Apisdorf, Phil Solomon, Jwo-Sy Chen, Jason M. Amini, Christopher Monroe, Stewart O. Allen, and Shantanu Debnath

Subjects

Quantum information, Computer science, Science, MathematicsofComputing_GENERAL, General Physics and Astronomy, FOS: Physical sciences, 02 engineering and technology, Type (model theory), computer.software_genre, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Field (computer science), 0103 physical sciences, Atomic and molecular physics, 010306 general physics, lcsh:Science, Quantum, Quantum computer, Quantum Physics, Multidisciplinary, General Chemistry, Benchmarking, 021001 nanoscience & nanotechnology, Computer engineering, Qubit, Quantum algorithm, lcsh:Q, Compiler, 0210 nano-technology, Quantum Physics (quant-ph), computer

Abstract

The field of quantum computing has grown from concept to demonstration devices over the past 20 years. Universal quantum computing offers efficiency in approaching problems of scientific and commercial interest, such as factoring large numbers, searching databases, simulating intractable models from quantum physics, and optimizing complex cost functions. Here, we present an 11-qubit fully-connected, programmable quantum computer in a trapped ion system composed of 13 171Yb+ ions. We demonstrate average single-qubit gate fidelities of 99.5\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\%$$\end{document}%, average two-qubit-gate fidelities of 97.5\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\%$$\end{document}%, and SPAM errors of 0.7\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\%$$\end{document}%. To illustrate the capabilities of this universal platform and provide a basis for comparison with similarly-sized devices, we compile the Bernstein-Vazirani and Hidden Shift algorithms into our native gates and execute them on the hardware with average success rates of 78\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\%$$\end{document}% and 35\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\%$$\end{document}%, respectively. These algorithms serve as excellent benchmarks for any type of quantum hardware, and show that our system outperforms all other currently available hardware., The growing complexity of quantum computing devices makes presents challenges for benchmarking their performance as previous, exhaustive approaches become infeasible. Here the authors characterise the quality of their 11-qubit device by successfully computing two quantum algorithms.

Published

2019

26. Probing many-body localization on a noisy quantum computer

Author

A. Y. Matsuura, Daiwei Zhu, Sonika Johri, Christopher Monroe, C. Huerta Alderete, K. A. Landsman, Nhung H. Nguyen, and Norbert M. Linke

Subjects

Coupling, Physics, Quantum Physics, Strongly Correlated Electrons (cond-mat.str-el), Heisenberg model, Computation, Phase (waves), FOS: Physical sciences, 01 natural sciences, Noise (electronics), Spectral line, 010305 fluids & plasmas, Condensed Matter - Strongly Correlated Electrons, 0103 physical sciences, Quantum system, Statistical physics, Quantum Physics (quant-ph), 010306 general physics, Quantum computer

Abstract

A disordered quantum system of interacting particles exhibits localized behavior when the disorder is large compared to the interaction strength. Studying this phenomenon on a quantum computer with no, or limited, error correction is challenging because even weak coupling to a thermal environment destroys most signatures of localization. Fortunately, spectral functions of local operators are known to contain features that can survive the presence of noise. In these spectra, discrete peaks and a soft gap at low frequencies compared to the thermal phase indicate localization. Here, we present the computation of spectral functions on a trapped-ion quantum computer for a one-dimensional Heisenberg model with disorder. Further, we design an error-mitigation technique which is effective at removing the noise from the measurement allowing clear signatures of localization to emerge as the disorder increases. Thus, we show that spectral functions can serve as a robust and scalable diagnostic of many-body localization on current and future generations of quantum computers.

Published

2021

27. Quantum Computer Systems for Scientific Discovery

Author

A. Robert Calderbank, Edward Farhi, Kenneth R. Brown, Peter Maunz, Michael Lange, Yuri Alexeev, John Preskill, Frederic T. Chong, Jeff D. Thompson, Martin J. Savage, Mikhail D. Lukin, Alexey V. Gorshkov, Dmitri Maslov, Christopher Monroe, Dave Bacon, Lincoln D. Carr, Andrew Houck, Martin Roetteler, Bill Fefferman, Seth Lloyd, Jungsang Kim, Dirk Englund, Brian DeMarco, and Shelby Kimmel

Subjects

High Energy Physics - Theory, Engineering, Nuclear Theory, General Computer Science, Scientific discovery, FOS: Physical sciences, General Physics and Astronomy, Context (language use), Field (computer science), Nuclear Theory (nucl-th), High Energy Physics - Lattice, Electrical and Electronic Engineering, Quantum information science, Nuclear theory, Mathematical Physics, Quantum computer, Quantum Physics, business.industry, Applied Mathematics, High Energy Physics - Lattice (hep-lat), DUAL (cognitive architecture), Data science, Electronic, Optical and Magnetic Materials, Condensed Matter - Other Condensed Matter, High Energy Physics - Theory (hep-th), Quantum Physics (quant-ph), business, National laboratory, Other Condensed Matter (cond-mat.other)

Abstract

The great promise of quantum computers comes with the dual challenges of building them and finding their useful applications. We argue that these two challenges should be considered together, by co-designing full-stack quantum computer systems along with their applications in order to hasten their development and potential for scientific discovery. In this context, we identify scientific and community needs, opportunities, a sampling of a few use case studies, and significant challenges for the development of quantum computers for science over the next 2--10 years. This document is written by a community of university, national laboratory, and industrial researchers in the field of Quantum Information Science and Technology, and is based on a summary from a U.S. National Science Foundation workshop on Quantum Computing held on October 21--22, 2019 in Alexandria, VA.

Published

2021

28. Observation of Stark many-body localization without disorder

Author

A. Kyprianidis, Alexey V. Gorshkov, P. Becker, Guido Pagano, W. Morong, Lei Feng, Fangli Liu, K. S. Collins, Christopher Monroe, and T. You

Subjects

Physics, Quantum Physics, Multidisciplinary, Field (physics), Spins, Thermodynamic equilibrium, Physical system, Measure (physics), FOS: Physical sciences, Quantum simulator, 01 natural sciences, Article, 010305 fluids & plasmas, Quantum Gases (cond-mat.quant-gas), 0103 physical sciences, Quantum system, Statistical physics, Quantum Physics (quant-ph), 010306 general physics, Condensed Matter - Quantum Gases, Quantum

Abstract

Thermalization is a ubiquitous process of statistical physics, in which details of few-body observables are washed out in favor of a featureless steady state. Even in isolated quantum many-body systems, limited to reversible dynamics, thermalization typically prevails. However, in these systems, there is another possibility: many-body localization (MBL) can result in preservation of a non-thermal state. While disorder has long been considered an essential ingredient for this phenomenon, recent theoretical work has suggested that a quantum many-body system with a uniformly increasing field -- but no disorder -- can also exhibit MBL, resulting in `Stark MBL.' Here we realize Stark MBL in a trapped-ion quantum simulator and demonstrate its key properties: halting of thermalization and slow propagation of correlations. Tailoring the interactions between ionic spins in an effective field gradient, we directly observe their microscopic equilibration for a variety of initial states, and we apply single-site control to measure correlations between separate regions of the spin chain. Further, by engineering a varying gradient, we create a disorder-free system with coexisting long-lived thermalized and nonthermal regions. The results demonstrate the unexpected generality of MBL, with implications about the fundamental requirements for thermalization and with potential uses in engineering long-lived non-equilibrium quantum matter., Near published version

Published

2021

29. Heisenberg-scaling measurement protocol for analytic functions with quantum sensor networks

Author

Kevin, Qian, Zachary, Eldredge, Wenchao, Ge, Guido, Pagano, Christopher, Monroe, J V, Porto, and Alexey V, Gorshkov

Subjects

Computer Science::Networking and Internet Architecture, Article

Abstract

We generalize past work on quantum sensor networks to show that, for d input parameters, entanglement can yield a factor O(d) improvement in mean-squared error when estimating an analytic function of these parameters. We show that the protocol is optimal for qubit sensors, and we conjecture an optimal protocol for photons passing through interferometers. Our protocol is also applicable to continuous variable measurements, such as one quadrature of a field operator. We outline a few potential applications, including calibration of laser operations in trapped ion quantum computing.

Published

2020

30. Many-body thermodynamics on quantum computers via partition function zeros

Author

Cinthia Huerta Alderete, Daiwei Zhu, James Freericks, Norbert M. Linke, Alexander F. Kemper, Christopher Monroe, Xiao Xiao, Akhil Francis, and Sonika Johri

Subjects

Physics, Phase transition, Multidisciplinary, Critical phenomena, Entire function, SciAdv r-articles, Function (mathematics), Partition function (mathematics), Condensed Matter Physics, Thermodynamic limit, Statistical physics, Complex plane, Computer Science::Databases, Research Articles, Quantum computer, Research Article

Abstract

Quantum computers can study thermodynamics by finding zeros of functions in the complex plane., Partition functions are ubiquitous in physics: They are important in determining the thermodynamic properties of many-body systems and in understanding their phase transitions. As shown by Lee and Yang, analytically continuing the partition function to the complex plane allows us to obtain its zeros and thus the entire function. Moreover, the scaling and nature of these zeros can elucidate phase transitions. Here, we show how to find partition function zeros on noisy intermediate-scale trapped-ion quantum computers in a scalable manner, using the XXZ spin chain model as a prototype, and observe their transition from XY-like behavior to Ising-like behavior as a function of the anisotropy. While quantum computers cannot yet scale to the thermodynamic limit, our work provides a pathway to do so as hardware improves, allowing the future calculation of critical phenomena for systems beyond classical computing limits.

Published

2020

31. Fault-tolerant control of an error-corrected qubit

Author

Laird, Egan, Dripto M, Debroy, Crystal, Noel, Andrew, Risinger, Daiwei, Zhu, Debopriyo, Biswas, Michael, Newman, Muyuan, Li, Kenneth R, Brown, Marko, Cetina, and Christopher, Monroe

Abstract

Quantum error correction protects fragile quantum information by encoding it into a larger quantum system

Published

2020

32. Quantum computing: how conditions created by the COVID-19 shutdown are delivering ‘the best data we have ever seen’

Author

Christopher Monroe

Subjects

Ions, Multidisciplinary, Maryland, Universities, Coronavirus disease 2019 (COVID-19), Computer science, Lasers, Shutdown, Pneumonia, Viral, Real-time computing, COVID-19, Cloud Computing, Computing Methodologies, Vibration, Electromagnetic Fields, Social Isolation, Calibration, Humans, Quantum Theory, Coronavirus Infections, Pandemics, Algorithms, Quantum computer

Abstract

Remotely controlled experiments are the way forward. Remotely controlled experiments are the way forward.

Published

2020

33. Efficient Ground-State Cooling of Large Trapped-Ion Chains with an Electromagnetically-Induced-Transparency Tripod Scheme

Author

Arinjoy De, A. Chu, A. Menon, Guido Pagano, Lei Feng, Wen Lin Tan, and Christopher Monroe

Subjects

Physics, Electromagnetically induced transparency, Tripod (photography), General Physics and Astronomy, Quantum simulator, 01 natural sciences, Ion, Transverse mode, 0103 physical sciences, Physics::Atomic Physics, Atomic physics, 010306 general physics, Ground state, Quantum, Quantum computer

Abstract

We report the electromagnetically-induced-transparency (EIT) cooling of a large trapped $^{171}{\mathrm{Yb}}^{+}$ ion chain to the quantum ground state. Unlike conventional EIT cooling, we engage a four-level tripod structure and achieve fast sub-Doppler cooling over all motional modes. We observe simultaneous ground-state cooling across the complete transverse mode spectrum of up to 40 ions, occupying a bandwidth of over 3 MHz. The cooling time is observed to be less than $300\text{ }\text{ }\ensuremath{\mu}\mathrm{s}$, independent of the number of ions. Such efficient cooling across the entire spectrum is essential for high-fidelity quantum operations using trapped ion crystals for quantum simulators or quantum computers.

Published

2020

34. Ground-state energy estimation of the water molecule on a trapped-ion quantum computer

Author

Yunseong Nam, Jwo-Sy Chen, Jonathan Mizrahi, Neal C. Pisenti, Andrew M. Ducore, Mike Williams, Shantanu Debnath, David Moehring, Jason M. Amini, Matthew J. Keesan, Dmitri Maslov, Kai Hudek, Kenneth R. Brown, Phil Solomon, Sarah M. Kreikemeier, Kristin M. Beck, Conor Delaney, Christopher Monroe, Jungsang Kim, Stewart O. Allen, Aleksey Blinov, Mika Chmielewski, Coleman Collins, Joel Apisdorf, Kenneth Wright, J. D. Wong-Campos, and Vandiver Chaplin

Subjects

Computer Networks and Communications, Statistical and Nonlinear Physics, Richardson extrapolation, 02 engineering and technology, Quantum entanglement, 021001 nanoscience & nanotechnology, 01 natural sciences, lcsh:QC1-999, lcsh:QA75.5-76.95, Computational science, Controllability, Computational Theory and Mathematics, 0103 physical sciences, Computer Science (miscellaneous), Quantum algorithm, lcsh:Electronic computers. Computer science, Computational problem, 010306 general physics, 0210 nano-technology, Quantum, lcsh:Physics, Trapped ion quantum computer, Quantum computer

Abstract

Quantum computing leverages the quantum resources of superposition and entanglement to efficiently solve computational problems considered intractable for classical computers. Examples include calculating molecular and nuclear structure, simulating strongly interacting electron systems, and modeling aspects of material function. While substantial theoretical advances have been made in mapping these problems to quantum algorithms, there remains a large gap between the resource requirements for solving such problems and the capabilities of currently available quantum hardware. Bridging this gap will require a co-design approach, where the expression of algorithms is developed in conjunction with the hardware itself to optimize execution. Here we describe an extensible co-design framework for solving chemistry problems on a trapped-ion quantum computer and apply it to estimating the ground-state energy of the water molecule using the variational quantum eigensolver (VQE) method. The controllability of the trapped-ion quantum computer enables robust energy estimates using the prepared VQE ansatz states. The systematic and statistical errors are comparable to the chemical accuracy, which is the target threshold necessary for predicting the rates of chemical reaction dynamics, without resorting to any error mitigation techniques based on Richardson extrapolation.

Published

2020

35. Quantum walks and Dirac cellular automata on a programmable trapped-ion quantum computer

Author

Shivani Singh, Nhung H. Nguyen, Norbert M. Linke, Daiwei Zhu, C. M. Chandrashekar, Christopher Monroe, C. Huerta Alderete, and Radhakrishnan Balu

Subjects

Science, Physical system, FOS: Physical sciences, General Physics and Astronomy, Position and momentum space, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, 010305 fluids & plasmas, symbols.namesake, 0103 physical sciences, Quantum walk, Statistical physics, lcsh:Science, 010306 general physics, Quantum, Trapped ion quantum computer, Quantum computer, Physics, Quantum Physics, Multidisciplinary, General Chemistry, Dirac equation, symbols, lcsh:Q, Quantum algorithm, Quantum simulation, Quantum Physics (quant-ph)

Abstract

The quantum walk formalism is a widely used and highly successful framework for modeling quantum systems, such as simulations of the Dirac equation, different dynamics in both the low and high energy regime, and for developing a wide range of quantum algorithms. Here we present the circuit-based implementation of a discrete-time quantum walk in position space on a five-qubit trapped-ion quantum processor. We encode the space of walker positions in particular multi-qubit states and program the system to operate with different quantum walk parameters, experimentally realizing a Dirac cellular automaton with tunable mass parameter. The quantum walk circuits and position state mapping scale favorably to a larger model and physical systems, allowing the implementation of any algorithm based on discrete-time quantum walks algorithm and the dynamics associated with the discretized version of the Dirac equation., 8 pages, 6 figures

Published

2020

36. Many-Body Dephasing in a Trapped-Ion Quantum Simulator

Author

Arinjoy De, Guido Pagano, Lingzhen Guo, Wen Lin Tan, Christopher Monroe, Florian Marquardt, and H. B. Kaplan

Subjects

Physics, Quantum Physics, Statistical Mechanics (cond-mat.stat-mech), Strongly Correlated Electrons (cond-mat.str-el), Integrable system, Atomic Physics (physics.atom-ph), Dephasing, FOS: Physical sciences, General Physics and Astronomy, Quantum simulator, Physics - Atomic Physics, Exponential function, Condensed Matter - Strongly Correlated Electrons, symbols.namesake, Magnetization, Quantum Gases (cond-mat.quant-gas), Quantum mechanics, symbols, Ising model, Quantum Physics (quant-ph), Condensed Matter - Quantum Gases, Hamiltonian (quantum mechanics), Quantum, Condensed Matter - Statistical Mechanics

Abstract

How a closed interacting quantum many-body system relaxes and dephases as a function of time is a fundamental question in thermodynamic and statistical physics. In this work, we analyse and observe the persistent temporal fluctuations after a quantum quench of a tunable long-range interacting transverse-field Ising Hamiltonian realized with a trapped-ion quantum simulator. We measure the temporal fluctuations in the average magnetization of a finite-size system of spin-$1/2$ particles. We experiment in a regime where the properties of the system are closely related to the integrable Hamiltonian with global spin-spin coupling, which enables analytical predictions even for the long-time non-integrable dynamics. The analytical expression for the temporal fluctuations predicts the exponential suppression of temporal fluctuations with increasing system size. Our measurement data is consistent with our theory predicting the regime of many-body dephasing., 5 pages, 4 figures, to be published in Physical Review Letters

Published

2020

37. The Character of Motional Modes for Entanglement and Sympathetic Cooling of Mixed-Species Trapped Ion Chains

Author

Allison Carter, Christopher Monroe, and Ksenia Sosnova

Subjects

Physics, Sympathetic cooling, Quantum Physics, FOS: Physical sciences, Quantum entanglement, Mass ratio, 01 natural sciences, Molecular physics, 010305 fluids & plasmas, Ion, Transverse plane, Qubit, 0103 physical sciences, Laser power scaling, 010306 general physics, Quantum Physics (quant-ph), Order of magnitude

Abstract

Modular mixed-species ion-trap networks are a promising framework for scalable quantum information processing, where one species acts as a memory qubit and another as a communication qubit. This architecture requires high-fidelity mixed-species entangling gates to transfer information from communication to memory qubits through their collective motion. We investigate the character of the motional modes of a mixed-species ion chain for entangling operations and also sympathetic cooling. We find that the laser power required for high-fidelity entangling gates based on transverse modes is at least an order of magnitude higher than that based on axial modes for widely different masses of the two species. We also find that for even moderate mass differences, the transverse modes are much harder to cool than the axial modes regardless of the ion chain configuration. Therefore, transverse modes conventionally used for operations in single-species ion chains may not be well suited for mixed-species chains with widely different masses., Comment: 8 pages, 5 figures

Published

2020

38. The U.S. National Quantum Initiative: From Act to action

Author

Jacob M. Taylor, Michael G. Raymer, and Christopher Monroe

Subjects

Multidisciplinary, Action (philosophy), Quantum, Law and economics

Abstract

Academia, agencies, and industry will work together

Published

2019

39. Complete 3-Qubit Grover search on a programmable quantum computer

Author

Shantanu Debnath, Christopher Monroe, K. A. Landsman, Norbert M. Linke, Caroline Figgatt, and Dmitri Maslov

Subjects

FOS: Computer and information sciences, Speedup, Computer science, Science, FOS: Physical sciences, General Physics and Astronomy, Computer Science - Emerging Technologies, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, 010305 fluids & plasmas, Ion, Quadratic equation, Computer Science::Emerging Technologies, Search algorithm, 0103 physical sciences, 010306 general physics, lcsh:Science, Quantum, Quantum computer, Quantum Physics, Multidisciplinary, General Chemistry, Emerging Technologies (cs.ET), Qubit, Scalability, Quantum algorithm, lcsh:Q, Quantum Physics (quant-ph), Algorithm, Hardware_LOGICDESIGN

Abstract

Searching large databases is an important problem with broad applications. The Grover search algorithm provides a powerful method for quantum computers to perform searches with a quadratic speedup in the number of required database queries over classical computers. It is an optimal search algorithm for a quantum computer, and has further applications as a subroutine for other quantum algorithms. Searches with two qubits have been demonstrated on a variety of platforms and proposed for others, but larger search spaces have only been demonstrated on a non-scalable NMR system. Here, we report results for a complete three-qubit Grover search algorithm using the scalable quantum computing technology of trapped atomic ions, with better-than-classical performance. The algorithm is performed for all 8 possible single-result oracles and all 28 possible two-result oracles. Two methods of state marking are used for the oracles: a phase-flip method employed by other experimental demonstrations, and a Boolean method requiring an ancilla qubit that is directly equivalent to the state-marking scheme required to perform a classical search. All quantum solutions are shown to outperform their classical counterparts. We also report the first implementation of a Toffoli-4 gate, which is used along with Toffoli-3 gates to construct the algorithms; these gates have process fidelities of 70.5% and 89.6%, respectively., 11 pages, 10 figures, 2 tables

Published

2017

40. Comparison of cloud-based ion trap and superconducting quantum computer architectures

Author

Christopher Monroe, S. Blinov, and B. Wu

Subjects

FOS: Computer and information sciences, Quantum Physics, Computer Networks and Communications, Computer science, business.industry, Information processing, FOS: Physical sciences, Computer Science - Emerging Technologies, Context (language use), Cloud computing, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Computational science, Emerging Technologies (cs.ET), Computational Theory and Mathematics, Component (UML), Ion trap, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Quantum Physics (quant-ph), business, Quantum, Quantum computer, Electronic circuit

Abstract

Quantum computing represents a radical departure from conventional approaches to information processing, offering the potential for solving problems that can never be approached classically. While large-scale quantum computer hardware is still in development, several quantum computing systems have recently become available as commercial cloud services. The authors compare the performance of IBMQ-16-Melbourne, IBMQ-Vigo, and Rigetti Aspen-8 superconducting systems, and IonQ ion trap systems on several simple quantum circuits and algorithms and examine component performance in the context of each system's architecture.

Published

2021

41. Ultrafast creation of large Schrödinger cat states of an atom

Author

Brian Neyenhuis, J. D. Wong-Campos, Christopher Monroe, Jonathan Mizrahi, and K. G. Johnson

Subjects

Quantum decoherence, Science, General Physics and Astronomy, 02 engineering and technology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, symbols.namesake, Superposition principle, Quantum mechanics, 0103 physical sciences, Physics::Atomic Physics, 010306 general physics, Quantum information science, lcsh:Science, Quantum, Harmonic oscillator, Physics, Mesoscopic physics, Multidisciplinary, General Chemistry, 021001 nanoscience & nanotechnology, Coherent control, symbols, lcsh:Q, 0210 nano-technology, Schrödinger's cat

Abstract

Mesoscopic quantum superpositions, or Schrödinger cat states, are widely studied for fundamental investigations of quantum measurement and decoherence as well as applications in sensing and quantum information science. The generation and maintenance of such states relies upon a balance between efficient external coherent control of the system and sufficient isolation from the environment. Here we create a variety of cat states of a single trapped atom’s motion in a harmonic oscillator using ultrafast laser pulses. These pulses produce high fidelity impulsive forces that separate the atom into widely separated positions, without restrictions that typically limit the speed of the interaction or the size and complexity of the resulting motional superposition. This allows us to quickly generate and measure cat states larger than previously achieved in a harmonic oscillator, and create complex multi-component superposition states in atoms., Generation of mesoscopic quantum superpositions requires both reliable coherent control and isolation from the environment. Here, the authors succeed in creating a variety of cat states of a single trapped atom, mapping spin superpositions into spatial superpositions using ultrafast laser pulses.

Published

2017

42. High purity single photons entangled with an atomic qubit

Author

Ksenia Sosnova, Allison Carter, Martin Lichtman, C. Crocker, Christopher Monroe, and Sophia Scarano

Subjects

Physics, Quantum network, Background subtraction, Photon, business.industry, Physics::Optics, Quantum Physics, 02 engineering and technology, Quantum entanglement, 021001 nanoscience & nanotechnology, Polarization (waves), 01 natural sciences, Atomic and Molecular Physics, and Optics, 010309 optics, Optics, Qubit, 0103 physical sciences, Photon polarization, Optoelectronics, Photonics, 0210 nano-technology, business

Abstract

Trapped atomic ions are an ideal candidate for quantum network nodes, with long-lived identical qubit memories that can be locally entangled through their Coulomb interaction and remotely entangled through photonic channels. The integrity of this photonic interface is generally reliant on the purity of single photons produced by the quantum memory. Here, we demonstrate a single-photon source for quantum networking based on a trapped 138Ba+ ion with a single photon purity of g (2)(0)=(8.1±2.3)×10−5 without background subtraction. We further optimize the tradeoff between the photonic generation rate and the memory-photon entanglement fidelity for the case of polarization photonic qubits by tailoring the spatial mode of the collected light.

Published

2019

43. Generation of Thermofield Double States and Critical Ground States with a Quantum Computer

Author

Norbert M. Linke, A. Y. Matsuura, Daiwei Zhu, K. A. Landsman, Christopher Monroe, C. Huerta Alderete, Nhung H. Nguyen, Sonika Johri, and Timothy H. Hsieh

Subjects

Physics, High Energy Physics - Theory, Work (thermodynamics), Quantum Physics, Multidisciplinary, Strongly Correlated Electrons (cond-mat.str-el), FOS: Physical sciences, Quantum simulator, Quantum entanglement, trapped ions, Noise (electronics), quantum computing, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory (hep-th), thermofield double state, Quantum state, Quantum mechanics, Physical Sciences, Ising model, Quantum Physics (quant-ph), Quantum, quantum simulation, Quantum computer

Abstract

Significance Our experiment prepares two types of nontrivial quantum states on a trapped ion quantum computer: the thermofield double state of the transverse-field Ising model at arbitrary temperature and the quantum critical state of the zero-temperature model. We use techniques motivated by the quantum approximate optimization algorithm, and we implement a hybrid quantum–classical optimization loop to prepare the quantum critical state. Our results pave the way for exploring strongly correlated models at finite temperature and teleportation protocols inspired by black hole physics., Finite-temperature phases of many-body quantum systems are fundamental to phenomena ranging from condensed-matter physics to cosmology, yet they are generally difficult to simulate. Using an ion trap quantum computer and protocols motivated by the quantum approximate optimization algorithm (QAOA), we generate nontrivial thermal quantum states of the transverse-field Ising model (TFIM) by preparing thermofield double states at a variety of temperatures. We also prepare the critical state of the TFIM at zero temperature using quantum–classical hybrid optimization. The entanglement structure of thermofield double and critical states plays a key role in the study of black holes, and our work simulates such nontrivial structures on a quantum computer. Moreover, we find that the variational quantum circuits exhibit noise thresholds above which the lowest-depth QAOA circuits provide the best results.

Published

2019

44. Discrete Time Crystals

Author

Norman Y. Yao, Chetan Nayak, Christopher Monroe, and Dominic V. Else

Subjects

Coupling, Physics, Class (set theory), Strongly Correlated Electrons (cond-mat.str-el), Statistical Mechanics (cond-mat.stat-mech), Spontaneous symmetry breaking, FOS: Physical sciences, Disordered Systems and Neural Networks (cond-mat.dis-nn), Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Condensed Matter - Strongly Correlated Electrons, Discrete time and continuous time, Quantum Gases (cond-mat.quant-gas), Quantum mechanics, 0103 physical sciences, General Materials Science, 010306 general physics, Condensed Matter - Quantum Gases, Quantum, Condensed Matter - Statistical Mechanics

Abstract

Experimental advances have allowed for the exploration of nearly isolated quantum many-body systems whose coupling to an external bath is very weak. A particularly interesting class of such systems is those which do not thermalize under their own isolated quantum dynamics. In this review, we highlight the possibility for such systems to exhibit new non-equilibrium phases of matter. In particular, we focus on "discrete time crystals", which are many-body phases of matter characterized by a spontaneously broken discrete time translation symmetry. We give a definition of discrete time crystals from several points of view, emphasizing that they are a non-equilibrium phenomenon, which is stabilized by many-body interactions, with no analog in non-interacting systems. We explain the theory behind several proposed models of discrete time crystals, and compare a number of recent realizations, in different experimental contexts., 42 pages (double-spaced) + 3 pages appendices. Submitted to Annual Reviews of Condensed Matter Physics

Published

2019

45. Heisenberg-Scaling Measurement Protocol for Analytic Functions with Quantum Sensor Networks

Author

Wenchao Ge, Alexey V. Gorshkov, Guido Pagano, Kevin Qian, James V. Porto, Christopher Monroe, and Zachary Eldredge

Subjects

Physics, Quantum Physics, Photon, Field (physics), Atomic Physics (physics.atom-ph), Operator (physics), Quantum sensor, FOS: Physical sciences, Quantum entanglement, Topology, 01 natural sciences, 010305 fluids & plasmas, Physics - Atomic Physics, Qubit, 0103 physical sciences, Computer Science::Networking and Internet Architecture, 010306 general physics, Quantum Physics (quant-ph), Analytic function, Quantum computer

Abstract

We generalize past work on quantum sensor networks to show that, for $d$ input parameters, entanglement can yield a factor $\mathcal O(d)$ improvement in mean squared error when estimating an analytic function of these parameters. We show that the protocol is optimal for qubit sensors, and conjecture an optimal protocol for photons passing through interferometers. Our protocol is also applicable to continuous variable measurements, such as one quadrature of a field operator. We outline a few potential applications, including calibration of laser operations in trapped ion quantum computing., 10 pages, 2 figures, v2: updated to published version

Published

2019

46. Two-qubit entangling gates within arbitrarily long chains of trapped ions

Author

K. A. Landsman, Kenneth R. Brown, Christopher Monroe, Daiwei Zhu, Yukai Wu, Norbert M. Linke, Pak Hong Leung, and L.-M. Duan

Subjects

Physics, Atomic Physics (physics.atom-ph), Inverse, FOS: Physical sciences, Quantum Physics, 01 natural sciences, Physics - Atomic Physics, 010305 fluids & plasmas, Ion, Computer Science::Emerging Technologies, Quantum gate, Qubit, Quantum mechanics, 0103 physical sciences, Coulomb, Ion trap, 010306 general physics, Scaling, Quantum computer

Abstract

Ion trap systems are a leading platform for large scale quantum computers. Trapped ion qubit crystals are fully-connected and reconfigurable, owing to their long range Coulomb interaction that can be modulated with external optical forces. However, the spectral crowding of collective motional modes could pose a challenge to the control of such interactions for large numbers of qubits. Here, we show that high-fidelity quantum gate operations are still possible with very large trapped ion crystals, simplifying the scaling of ion trap quantum computers. To this end, we present analytical work that determines how parallel entangling gates produce a crosstalk error that falls off as the inverse cube of the distance between the pairs. We also show experimental work demonstrating entangling gates on a fully-connected chain of seventeen $^{171}{\rm{Yb}}^{+}$ ions with fidelities as high as $97(1)\%$., Comment: 10 pages, 6 figures

Published

2019

47. Quantum Computing and Simulation with Trapped Atomic Ions

Author

P. Becker, C. Crocker, Norbert M. Linke, D. Risinger, H. B. Kaplan, Marko Cetina, M. Goldman, Daiwei Zhu, K. S. Collins, Wen Lin Tan, Allison Carter, K. A. Landsman, Laird Egan, Martin Lichtman, Christopher Monroe, A. Kyprianidis, Fangli Liu, Ksenia Sosnova, Guido Pagano, and Alexey V. Gorshkov

Subjects

Physics, ComputerSystemsOrganization_MISCELLANEOUS, Optical force, Quantum simulator, Quantum information, Computer Science::Databases, Laser beams, Ion, Computational physics, Quantum computer

Abstract

I will review some of the latest results in both gate-based quantum computing and analog quantum simulation, speculating on how this platform can realistically be scaled in the near future.

Published

2019

48. Quantum Simulators: Architectures and Opportunities

Author

Monika Schleier-Smith, Ehud Altman, Markus Greiner, Kai-Mei C. Fu, Cheng Chin, Pedram Roushan, Christopher Monroe, Andrew C. Potter, Kater Murch, Kristan Temme, Kaden R. A. Hazzard, David S. Weiss, Giuseppe Carleo, Alicia J. Kollár, Lincoln D. Carr, Jelena Vuckovic, Raymond W. Simmonds, Mark Saffman, Sophia E. Economou, Brian DeMarco, Irfan Siddiqi, Randall G. Hulet, Kang-Kuen Ni, Xiao Mi, Ian B. Spielman, Eugene Demler, Zaira Nazario, Meenakshi Singh, Martin Zwierlein, Mark A. Eriksson, Ruichao Ma, Vladan Vuletic, Shashank Misra, Jun Ye, Mikhail D. Lukin, Benjamin Lev, and Kenneth R. Brown

Subjects

Quantum Physics, Quantum Turing machine, Strongly Correlated Electrons (cond-mat.str-el), business.industry, Computer science, General Engineering, Quantum simulator, FOS: Physical sciences, Quantum entanglement, Computational Physics (physics.comp-ph), USable, Condensed Matter - Strongly Correlated Electrons, Software, Quantum Gases (cond-mat.quant-gas), Systems engineering, General Earth and Planetary Sciences, Computational problem, business, Condensed Matter - Quantum Gases, Quantum Physics (quant-ph), Quantum, Physics - Computational Physics, General Environmental Science, Quantum computer

Abstract

Quantum simulators are a promising technology on the spectrum of quantum devices from specialized quantum experiments to universal quantum computers. These quantum devices utilize entanglement and many-particle behaviors to explore and solve hard scientific, engineering, and computational problems. Rapid development over the last two decades has produced more than 300 quantum simulators in operation worldwide using a wide variety of experimental platforms. Recent advances in several physical architectures promise a golden age of quantum simulators ranging from highly optimized special purpose simulators to flexible programmable devices. These developments have enabled a convergence of ideas drawn from fundamental physics, computer science, and device engineering. They have strong potential to address problems of societal importance, ranging from understanding vital chemical processes, to enabling the design of new materials with enhanced performance, to solving complex computational problems. It is the position of the community, as represented by participants of the NSF workshop on "Programmable Quantum Simulators," that investment in a national quantum simulator program is a high priority in order to accelerate the progress in this field and to result in the first practical applications of quantum machines. Such a program should address two areas of emphasis: (1) support for creating quantum simulator prototypes usable by the broader scientific community, complementary to the present universal quantum computer effort in industry; and (2) support for fundamental research carried out by a blend of multi-investigator, multi-disciplinary collaborations with resources for quantum simulator software, hardware, and education., Comment: 41 pages -- references and acknowledgments added in v2

Published

2019

49. Quantum Approximate Optimization of the Long-Range Ising Model with a Trapped-Ion Quantum Simulator

Author

Stephen P. Jordan, Arinjoy De, Guido Pagano, Abhinav Deshpande, H. B. Kaplan, Fangli Liu, C. L. Baldwin, Paul Hess, Christopher Monroe, P. Becker, K. S. Collins, Alexey V. Gorshkov, A. Kyprianidis, Wen Lin Tan, Lucas T. Brady, and Aniruddha Bapat

Subjects

Quantum Physics, Multidisciplinary, Strongly Correlated Electrons (cond-mat.str-el), Heuristic (computer science), Computer science, Quantum simulator, FOS: Physical sciences, Condensed Matter - Strongly Correlated Electrons, Quantum Gases (cond-mat.quant-gas), Qubit, Ising model, Quantum algorithm, Statistical physics, Quantum information science, Condensed Matter - Quantum Gases, Quantum Physics (quant-ph), Quantum, Quantum computer

Abstract

Quantum computers and simulators may offer significant advantages over their classical counterparts, providing insights into quantum many-body systems and possibly improving performance for solving exponentially hard problems, such as optimization and satisfiability. Here, we report the implementation of a low-depth Quantum Approximate Optimization Algorithm (QAOA) using an analog quantum simulator. We estimate the ground-state energy of the Transverse Field Ising Model with long-range interactions with tunable range, and we optimize the corresponding combinatorial classical problem by sampling the QAOA output with high-fidelity, single-shot, individual qubit measurements. We execute the algorithm with both an exhaustive search and closed-loop optimization of the variational parameters, approximating the ground-state energy with up to 40 trapped-ion qubits. We benchmark the experiment with bootstrapping heuristic methods scaling polynomially with the system size. We observe, in agreement with numerics, that the QAOA performance does not degrade significantly as we scale up the system size and that the runtime is approximately independent from the number of qubits. We finally give a comprehensive analysis of the errors occurring in our system, a crucial step in the path forward toward the application of the QAOA to more general problem instances.

Published

2019

50. Entanglement as a resource for quantum networking

Author

Christopher Monroe, Vladimir S. Malinovsky, Siddhartha Santra, and Liang Jiang

Subjects

Physics, Quantum network, Photon, Resource (project management), Coupling efficiency, Quantum entanglement, Statistical physics, Quantum channel, Quantum key distribution, Quantum

Abstract

We examine the viability of quantum repeaters based on two-species trapped ion modules for long-distance quantum key distribution. We discuss the dependence of the quantum key distribution rate on various experimental parameters, including coupling efficiency, gate infidelity, operation time and length of the elementary links.

Published

2019