Your search keyword '"Risinger, Andrew"' showing total 26 results

1. Fast photon-mediated entanglement of continuously-cooled trapped ions for quantum networking

Author

O'Reilly, Jameson, Toh, George, Goetting, Isabella, Saha, Sagnik, Shalaev, Mikhail, Carter, Allison, Risinger, Andrew, Kalakuntla, Ashish, Li, Tingguang, Verma, Ashrit, and Monroe, Christopher

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We entangle two co-trapped atomic barium ion qubits by collecting single visible photons from each ion through in-vacuo 0.8 NA objectives, interfering them through an integrated fiber-beamsplitter and detecting them in coincidence. This projects the qubits into an entangled Bell state with an observed fidelity lower bound of F > 94%. We also introduce an ytterbium ion for sympathetic cooling to remove the need for recooling interruptions and achieve a continuous entanglement rate of 250 1/s., Comment: 8 pages, 5 figures

Published

2024

2. Interactive cryptographic proofs of quantumness using mid-circuit measurements

Author

Zhu, Daiwei, Kahanamoku-Meyer, Gregory D, Lewis, Laura, Noel, Crystal, Katz, Or, Harraz, Bahaa, Wang, Qingfeng, Risinger, Andrew, Feng, Lei, Biswas, Debopriyo, Egan, Laird, Gheorghiu, Alexandru, Nam, Yunseong, Vidick, Thomas, Vazirani, Umesh, Yao, Norman Y, Cetina, Marko, and Monroe, Christopher

Subjects

Quantum Physics, Physical Sciences, Bioengineering, Mathematical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences

Abstract

The ability to perform measurements in the middle of a quantum circuit is a powerful resource. It underlies a wide range of applications, from remote state preparation to quantum error correction. Here we apply mid-circuit measurements for a particular task: demonstrating quantum computational advantage. The goal of such a demonstration is for a quantum device to perform a computational task that is infeasible for a classical device with comparable resources. In contrast to existing demonstrations, the distinguishing feature of our approach is that the classical verification process is efficient, both in asymptotic complexity and in practice. Furthermore, the classical hardness of performing the task is based upon well-established cryptographic assumptions. Protocols with these features are known as cryptographic proofs of quantumness. Using a trapped-ion quantum computer, we perform mid-circuit measurements by spatially isolating portions of the ion chain via shuttling. This enables us to implement two interactive cryptographic proofs of quantumness, which when suitably scaled to larger systems, promise the efficient verification of quantum computational advantage. Our methods can be applied to a range of interactive quantum protocols.

Published

2023

3. Experimental Implementation of an Efficient Test of Quantumness

Author

Lewis, Laura, Zhu, Daiwei, Gheorghiu, Alexandru, Noel, Crystal, Katz, Or, Harraz, Bahaa, Wang, Qingfeng, Risinger, Andrew, Feng, Lei, Biswas, Debopriyo, Egan, Laird, Vidick, Thomas, Cetina, Marko, and Monroe, Christopher

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

A test of quantumness is a protocol where a classical user issues challenges to a quantum device to determine if it exhibits non-classical behavior, under certain cryptographic assumptions. Recent attempts to implement such tests on current quantum computers rely on either interactive challenges with efficient verification, or non-interactive challenges with inefficient (exponential time) verification. In this paper, we execute an efficient non-interactive test of quantumness on an ion-trap quantum computer. Our results significantly exceed the bound for a classical device's success., Comment: 6 pages, 2 figures

Published

2022

4. Demonstration of three- and four-body interactions between trapped-ion spins

Author

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

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

Quantum processors use the native interactions between effective spins to simulate Hamiltonians or execute quantum gates. In most processors, the native interactions are pairwise, limiting the efficiency of controlling entanglement between many qubits. Here we experimentally demonstrate a new class of native interactions between trapped-ion qubits, extending conventional pairwise interactions to higher order. We realize three- and four-body spin interactions as examples, showing that high-order spin polynomials may serve as a new toolbox for quantum information applications.

Published

2022

5. Demonstration of three- and four-body interactions between trapped-ion spins

Author

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

Published

2023

6. Interactive Protocols for Classically-Verifiable Quantum Advantage

Author

Zhu, Daiwei, Kahanamoku-Meyer, Gregory D., Lewis, Laura, Noel, Crystal, Katz, Or, Harraz, Bahaa, Wang, Qingfeng, Risinger, Andrew, Feng, Lei, Biswas, Debopriyo, Egan, Laird, Gheorghiu, Alexandru, Nam, Yunseong, Vidick, Thomas, Vazirani, Umesh, Yao, Norman Y., Cetina, Marko, and Monroe, Christopher

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter

Abstract

Achieving quantum computational advantage requires solving a classically intractable problem on a quantum device. Natural proposals rely upon the intrinsic hardness of classically simulating quantum mechanics; however, verifying the output is itself classically intractable. On the other hand, certain quantum algorithms (e.g. prime factorization via Shor's algorithm) are efficiently verifiable, but require more resources than what is available on near-term devices. One way to bridge the gap between verifiability and implementation is to use "interactions" between a prover and a verifier. By leveraging cryptographic functions, such protocols enable the classical verifier to enforce consistency in a quantum prover's responses across multiple rounds of interaction. In this work, we demonstrate the first implementation of an interactive quantum advantage protocol, using an ion trap quantum computer. We execute two complementary protocols -- one based upon the learning with errors problem and another where the cryptographic construction implements a computational Bell test. To perform multiple rounds of interaction, we implement mid-circuit measurements on a subset of trapped ion qubits, with subsequent coherent evolution. For both protocols, the performance exceeds the asymptotic bound for classical behavior; maintaining this fidelity at scale would conclusively demonstrate verifiable quantum advantage., Comment: 11 pages, 3 figures; supp. info 23 pages, 4 figures

Published

2021

7. Digital quantum simulation of NMR experiments

Author

Seetharam, Kushal, Biswas, Debopriyo, Noel, Crystal, Risinger, Andrew, Zhu, Daiwei, Katz, Or, Chattopadhyay, Sambuddha, Cetina, Marko, Monroe, Christopher, Demler, Eugene, and Sels, Dries

Subjects

Quantum Physics, Physics - Chemical Physics

Abstract

Computational simulations of nuclear magnetic resonance (NMR) experiments are essential for extracting information about molecular structure and dynamics, but are often intractable on classical computers for large molecules such as proteins and protocols such as zero-field NMR. We demonstrate the first quantum simulation of a NMR spectrum, computing the zero-field spectrum of the methyl group of acetonitrile on a trapped-ion quantum computer. We reduce the sampling cost of the quantum simulation by an order of magnitude using compressed sensing techniques. Our work opens a new practical application for quantum computation, and we show how the inherent decoherence of NMR systems may enable the simulation of classically hard molecules on near-term quantum hardware., Comment: 5 pages + 3 figures (main text), 10 pages + 6 figures (supplementary material)

Published

2021

8. Cross-Platform Comparison of Arbitrary Quantum Computations

Author

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

Subjects

Quantum Physics

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

9. Observation of measurement-induced quantum phases in a trapped-ion quantum computer

Author

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

Subjects

Quantum Physics

Abstract

Many-body open quantum systems balance internal dynamics against decoherence from interactions with an environment. Here, we explore this balance via random quantum circuits implemented on a trapped ion quantum computer, where the system evolution is represented by unitary gates with interspersed projective measurements. As the measurement rate is varied, a purification phase transition is predicted to emerge at a critical point akin to a fault-tolerent threshold. We probe the "pure" phase, where the system is rapidly projected to a deterministic state conditioned on the measurement outcomes, and the "mixed" or "coding" phase, where the initial state becomes partially encoded into a quantum error correcting codespace. We find convincing evidence of the two phases and show numerically that, with modest system scaling, critical properties of the transition clearly emerge., Comment: 17 pages, 8 figures

Published

2021

10. Optimizing Stabilizer Parities for Improved Logical Qubit Memories

Author

Debroy, Dripto M., Egan, Laird, Noel, Crystal, Risinger, Andrew, Zhu, Daiwei, Biswas, Debopriyo, Cetina, Marko, Monroe, Chris, and Brown, Kenneth R.

Subjects

Quantum Physics

Abstract

We study variants of Shor's code that are adept at handling single-axis correlated idling errors, which are commonly observed in many quantum systems. By using the repetition code structure of the Shor's code basis states, we calculate the logical channel applied to the encoded information when subjected to coherent and correlated single qubit idling errors, followed by stabilizer measurement. Changing the signs of the stabilizer generators allows us to change how the coherent errors interfere, leading to a quantum error correcting code which performs as well as a classical repetition code of equivalent distance against these errors. We demonstrate a factor of 4 improvement of the logical memory in a distance-3 logical qubit implemented on a trapped-ion quantum computer. Even-distance versions of our Shor code variants are decoherence-free subspaces and fully robust to identical and independent coherent idling noise.

Published

2021

11. Fault-Tolerant Operation of a Quantum Error-Correction Code

Author

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

Subjects

Quantum Physics

Abstract

Quantum error correction protects fragile quantum information by encoding it into a larger quantum system. These extra degrees of freedom enable the detection and correction of errors, but also increase the operational complexity of the encoded logical qubit. Fault-tolerant circuits contain the spread of errors while operating the logical qubit, and are essential for realizing error suppression in practice. While fault-tolerant design works in principle, it has not previously been demonstrated in an error-corrected physical system with native noise characteristics. In this work, we experimentally demonstrate fault-tolerant 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% and a Clifford gate error of 0.3% after error correction. Additionally, we prepare magic states with fidelities exceeding the distillation threshold, demonstrating all of the key single-qubit ingredients required for universal fault-tolerant operation. 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., Comment: Additional data on magic states and stabilizers added. Significant revision of text for improved clarity. Key results unchanged

Published

2020

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

Author

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

Published

2022

13. Exploring More-Coherent Quantum Annealing

Author

Novikov, Sergey, Hinkey, Robert, Disseler, Steven, Basham, James I., Albash, Tameem, Risinger, Andrew, Ferguson, David, Lidar, Daniel A., and Zick, Kenneth M.

Subjects

Quantum Physics, Computer Science - Emerging Technologies

Abstract

In the quest to reboot computing, quantum annealing (QA) is an interesting candidate for a new capability. While it has not demonstrated an advantage over classical computing on a real-world application, many important regions of the QA design space have yet to be explored. In IARPA's Quantum Enhanced Optimization (QEO) program, we have opened some new lines of inquiry to get to the heart of QA, and are designing testbed superconducting circuits and conducting key experiments. In this paper, we discuss recent experimental progress related to one of the key design dimensions: qubit coherence. Using MIT Lincoln Laboratory's qubit fabrication process and extending recent progress in flux qubits, we are implementing and measuring QA-capable flux qubits. Achieving high coherence in a QA context presents significant new engineering challenges. We report on techniques and preliminary measurement results addressing two of the challenges: crosstalk calibration and qubit readout. This groundwork enables exploration of other promising features and provides a path to understanding the physics and the viability of quantum annealing as a computing resource., Comment: 7 pages, 3 figures. Accepted by the 2018 IEEE International Conference on Rebooting Computing (ICRC)

Published

2018

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

Author

Egan, Laird, Debroy, Dripto M., Noel, Crystal, Risinger, Andrew, Zhu, Daiwei, Biswas, Debopriyo, and Newman, Michael

Subjects

Engineering research, Error-correcting codes -- Research, Fault tolerance (Computers) -- Research, Quantum computing -- Research, Fault tolerance, Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Quantum error correction protects fragile quantum information by encoding it into a larger quantum system.sup.1,2. 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 practice.sup.3-6. 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 threshold.sup.7, 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., Author(s): Laird Egan [sup.1] [sup.2] [sup.10] , Dripto M. Debroy [sup.4] [sup.11] , Crystal Noel [sup.1] [sup.2] , Andrew Risinger [sup.1] [sup.2] [sup.3] , Daiwei Zhu [sup.1] [sup.2] [sup.3] , [...]

Published

2021

15. Experimental implementation of an efficient test of quantumness

Author

Lewis, Laura, primary, Zhu, Daiwei, additional, Gheorghiu, Alexandru, additional, Noel, Crystal, additional, Katz, Or, additional, Harraz, Bahaa, additional, Wang, Qingfeng, additional, Risinger, Andrew, additional, Feng, Lei, additional, Biswas, Debopriyo, additional, Egan, Laird, additional, Vidick, Thomas, additional, Cetina, Marko, additional, and Monroe, Christopher, additional

Published

2024

16. Photon-mediated entanglement of co-trapped atomic barium ions

Author

O'Reilly, Jameson, primary, Toh, George, primary, Shalaev, Mikhail, primary, Carter, Allison, primary, Risinger, Andrew, primary, Saha, Sagnik, primary, Goetting, Isabella, primary, Li, Tingguang, primary, and Monroe, Christopher, primary

Published

2023

17. Engineering a Control System for a Logical Qubit-Scale Trapped Ion Quantum Computer

Author

Risinger, Andrew Russ and Risinger, Andrew Russ

Abstract

Quantum computing is a promising field for continuing to develop new computing capabilities, both in its own right and for continued gains as Moore's Law growth ends.Trapped ion quantum computing is a leading technology in the field of quantum computing, as it combines the important characteristics of high fidelity operations, individual addressing, and long coherence times. However, quantum computers are still in their infancy; the first quantum computers to have more than a handful of quantum bits (qubits) are less than a decade old. As research groups push the boundaries of the number of qubits in a system, they are consistently running into engineering obstacles preventing them from achieving their goals. There is effectively a knowledge gap between the physicists who have the capability to push the field of quantum computing forward, and the engineers who can design the large-scale & reliable systems that enable pushing those envelopes. This thesis is an attempt to bridge that gap by framing trapped ion quantum computing in a manner accessible to engineers, as well as improving on the state-of-the-art in quantum computer digital and RF control systems. We also consider some of the practical and theoretical engineering challenges that arise when developing a leading-edge trapped ion quantum computer capable of demonstrating error-corrected logical qubits, using trapped Ytterbium-171 qubits.There are many fundamental quantum operations that quantum information theory assumes, yet which are quite complicated to implement in reality. First, we address the time cost of rearranging a chain of ions after a scrambling collision with background gases. Then we consider a gate waveform generator that reduces programming time while supporting conditional quantum gates. Next, we discuss the development of a digital control system custom-designed for quantum computing and quantum networking applications. Finally, we demonstrate experimental results of the waveform generator

Published

2023

18. Programmable N-body interactions with trapped ion qubits

Author

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

Published

2022

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

Author

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

Published

2022

20. Optimizing Stabilizer Parities for Improved Logical Qubit Memories

Author

Debroy, Dripto M., primary, Egan, Laird, additional, Noel, Crystal, additional, Risinger, Andrew, additional, Zhu, Daiwei, additional, Biswas, Debopriyo, additional, Cetina, Marko, additional, Monroe, Chris, additional, and Brown, Kenneth R., additional

Published

2021

21. Cross-Platform Comparison of Arbitrary Quantum Computations

Author

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

Published

2021

22. Exploring More-Coherent Quantum Annealing

Author

Novikov, Sergey, primary, Hinkey, Robert, additional, Disseler, Steven, additional, Basham, James I, additional, Albash, Tameem, additional, Risinger, Andrew, additional, Ferguson, David, additional, Lidar, Daniel A., additional, and Zick, Kenneth M., additional

Published

2018

23. Implementation of a levenberg-marquardt algorithm to perform regression to I-V curves

Author

Risinger, Andrew, primary

Published

2013

24. NASHVILLE'S CROWN JEWEL RESTORED.

Author

Murray, Douglas and Risinger, Andrew

Subjects

*ORGANS (Musical instruments), *MUSIC facilities, *MUSICAL instrument repair

Abstract

The article reports on the Martin Foundation Organ in the Schermerhorn Symphony Center in Nashville, Tennesse that has been restored after it was damaged by the May 2010 flood. The organ along with other instruments in the basement of the center were submerged in water during the disaster. Organ builder Schoenstein & Co. assessed the organ and made some damage control and modifications to the musical instrument. The original console was replaced by a replica.

Published

2012

25. Fast Photon-Mediated Entanglement of Continuously Cooled Trapped Ions for Quantum Networking.

Author

O'Reilly J, Toh G, Goetting I, Saha S, Shalaev M, Carter AL, Risinger A, Kalakuntla A, Li T, Verma A, and Monroe C

Abstract

We entangle two cotrapped atomic barium ion qubits by collecting single visible photons from each ion through in vacuo 0.8 NA objectives, interfering them through an integrated fiber beam splitter and detecting them in coincidence. This projects the qubits into an entangled Bell state with an observed fidelity lower bound of F>94%. We also introduce an ytterbium ion for sympathetic cooling to remove the need for recooling interruptions and achieve a continuous entanglement rate of 250  s^{-1}.

Published

2024

26. Digital quantum simulation of NMR experiments.

Author

Seetharam K, Biswas D, Noel C, Risinger A, Zhu D, Katz O, Chattopadhyay S, Cetina M, Monroe C, Demler E, and Sels D

Abstract

Simulations of nuclear magnetic resonance (NMR) experiments can be an important tool for extracting information about molecular structure and optimizing experimental protocols but are often intractable on classical computers for large molecules such as proteins and for protocols such as zero-field NMR. We demonstrate the first quantum simulation of an NMR spectrum, computing the zero-field spectrum of the methyl group of acetonitrile using four qubits of a trapped-ion quantum computer. We reduce the sampling cost of the quantum simulation by an order of magnitude using compressed sensing techniques. We show how the intrinsic decoherence of NMR systems may enable the zero-field simulation of classically hard molecules on relatively near-term quantum hardware and discuss how the experimentally demonstrated quantum algorithm can be used to efficiently simulate scientifically and technologically relevant solid-state NMR experiments on more mature devices. Our work opens a practical application for quantum computation.

Published

2023