Markus Ansmann’s research while affiliated with Mountain View College and other places

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Publications (86)


Quantum error correction below the surface code threshold
  • Article

December 2024

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2 Reads

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2 Citations

Nature

Rajeev Acharya

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Dmitry A. Abanin

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Laleh Aghababaie-Beni

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[...]

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Nicholas Zobrist


Phase transitions in RCS
One phase transition goes between a concentrated output distribution of bit strings from RCS at a low number of cycles to a broad or anti-concentrated distribution. There is a second phase transition in a noisy system. A strong-enough error per cycle induces a phase transition from a regime where correlations extend to the full system to a regime where the system may be approximately represented by the product of several uncorrelated subsystems.
Phase transitions in the linear cross-entropy
a–d, At a low number of cycles, XEB grows with the size of the system. In a noiseless device, XEB will converge to 1 with the number of cycles. In the presence of noise, XEB becomes an estimator of the system fidelity. a,b, We experimentally observed a dynamical phase transition at a fixed number of cycles between these two regimes in one (a) and two dimensions (b). The random circuits have Haar random single-qubit gates and an iSWAP-like gate as an entangler. c,d, We experimentally probed a noise-induced phase transition using a weak-link model (see the main text), where the weak link is applied every 12 cycles (discrete gate set; see main text). c, The two different regimes. In the weak-noise regime, XEB converges to the fidelity, whereas in the strong-noise regime, XEB remains higher than predicted by the digital error model. d, We induced errors to scan the transition from one regime to the other.
Noise-induced phase transitions
a–c, Experimental noise-induced phase transitions as a function of the error per cycle for several periods T of the weak-link model (discrete gate set) (T = 8 (a), T = 12 (b) and T = 18 (c)). As T increases, the critical value of noise or error per cycle becomes lower. d, Phase diagram of the transition with analytical, numerical and experimental data. The experimental data were extracted from the crossing of the largest number of cycles scanned. e,f, Experimental transitions in two dimensions with different patterns: staggered ACBD (e) and unstaggered EGFH (f; discrete gate set). g, Numerical phase diagram of the two-dimensional phase transition. We show the critical point for different sizes and patterns. The qubits are arranged as shown in the inset of e. For fixed size, we increased the number of bridges (such as the red coupler in e) until all bridges were applied (four and six for the 4 × 4 and 4 × 6 systems, respectively), denoted as links per four cycles in g. For all the patterns, we delimited a lower bound on the critical error rate of 0.47 errors per cycle to separate the region of strong noise where XEB failed to characterize the underlying fidelity and where global correlations were subdominant. The experimental results shown in Fig. 4 (SYC-67) and in Supplementary Information section C1 (SYC-70) are represented by red stars, which are well within the weak-noise regime.
Demonstration of a classically intractable computation
a, Verification of RCS fidelity with logarithmic XEB. The full device is divided into two (green) or three (blue) patches to estimate the XEB fidelity for a modest computational cost. We used the discrete gate set of single-qubit gates chosen randomly from ZpX1/2Z−p with p ∈ {−1, −3/4, −1/2, …, 3/4}. For each number of cycles, 20 circuit instances were sampled with 100,000 shots each. The solid lines indicate the XEB estimated from the digital error model. b, Verification of RCS fidelity with Loschmidt echo. The inversion was done by reversing the circuit and inserting single-qubit gates. In this case, the Loschmidt echo number of cycles doubled. c, Time complexity estimated as a function of the number of qubits and the number of cycles for a set of circuits. As a working definition of time complexity, we used the number of FLOPs needed to compute the probability of a single bit string under no memory constraints. The solid line indicates the depth at which correlations spread to the full device and the FLOPs with depth go from exponential to polynomial. d, Evolution of the time complexity of the RCS experiments. The dashed line represents doubly exponential growth as a guide for the eye.
Phase transitions in random circuit sampling
  • Article
  • Full-text available

October 2024

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79 Reads

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12 Citations

Nature

Undesired coupling to the surrounding environment destroys long-range correlations in quantum processors and hinders coherent evolution in the nominally available computational space. This noise is an outstanding challenge when leveraging the computation power of near-term quantum processors¹. It has been shown that benchmarking random circuit sampling with cross-entropy benchmarking can provide an estimate of the effective size of the Hilbert space coherently available2–8. Nevertheless, quantum algorithms’ outputs can be trivialized by noise, making them susceptible to classical computation spoofing. Here, by implementing an algorithm for random circuit sampling, we demonstrate experimentally that two phase transitions are observable with cross-entropy benchmarking, which we explain theoretically with a statistical model. The first is a dynamical transition as a function of the number of cycles and is the continuation of the anti-concentration point in the noiseless case. The second is a quantum phase transition controlled by the error per cycle; to identify it analytically and experimentally, we create a weak-link model, which allows us to vary the strength of the noise versus coherent evolution. Furthermore, by presenting a random circuit sampling experiment in the weak-noise phase with 67 qubits at 32 cycles, we demonstrate that the computational cost of our experiment is beyond the capabilities of existing classical supercomputers. Our experimental and theoretical work establishes the existence of transitions to a stable, computationally complex phase that is reachable with current quantum processors.

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Observation of disorder-free localization and efficient disorder averaging on a quantum processor

October 2024

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34 Reads

One of the most challenging problems in the computational study of localization in quantum manybody systems is to capture the effects of rare events, which requires sampling over exponentially many disorder realizations. We implement an efficient procedure on a quantum processor, leveraging quantum parallelism, to efficiently sample over all disorder realizations. We observe localization without disorder in quantum many-body dynamics in one and two dimensions: perturbations do not diffuse even though both the generator of evolution and the initial states are fully translationally invariant. The disorder strength as well as its density can be readily tuned using the initial state. Furthermore, we demonstrate the versatility of our platform by measuring Renyi entropies. Our method could also be extended to higher moments of the physical observables and disorder learning.


Visualizing Dynamics of Charges and Strings in (2+1)D Lattice Gauge Theories

September 2024

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27 Reads

Lattice gauge theories (LGTs) can be employed to understand a wide range of phenomena, from elementary particle scattering in high-energy physics to effective descriptions of many-body interactions in materials. Studying dynamical properties of emergent phases can be challenging as it requires solving many-body problems that are generally beyond perturbative limits. We investigate the dynamics of local excitations in a Z2\mathbb{Z}_2 LGT using a two-dimensional lattice of superconducting qubits. We first construct a simple variational circuit which prepares low-energy states that have a large overlap with the ground state; then we create particles with local gates and simulate their quantum dynamics via a discretized time evolution. As the effective magnetic field is increased, our measurements show signatures of transitioning from deconfined to confined dynamics. For confined excitations, the magnetic field induces a tension in the string connecting them. Our method allows us to experimentally image string dynamics in a (2+1)D LGT from which we uncover two distinct regimes inside the confining phase: for weak confinement the string fluctuates strongly in the transverse direction, while for strong confinement transverse fluctuations are effectively frozen. In addition, we demonstrate a resonance condition at which dynamical string breaking is facilitated. Our LGT implementation on a quantum processor presents a novel set of techniques for investigating emergent particle and string dynamics.


Quantum error correction below the surface code threshold

August 2024

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385 Reads

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2 Citations

Quantum error correction provides a path to reach practical quantum computing by combining multiple physical qubits into a logical qubit, where the logical error rate is suppressed exponentially as more qubits are added. However, this exponential suppression only occurs if the physical error rate is below a critical threshold. In this work, we present two surface code memories operating below this threshold: a distance-7 code and a distance-5 code integrated with a real-time decoder. The logical error rate of our larger quantum memory is suppressed by a factor of Λ\Lambda = 2.14 ±\pm 0.02 when increasing the code distance by two, culminating in a 101-qubit distance-7 code with 0.143% ±\pm 0.003% error per cycle of error correction. This logical memory is also beyond break-even, exceeding its best physical qubit's lifetime by a factor of 2.4 ±\pm 0.3. We maintain below-threshold performance when decoding in real time, achieving an average decoder latency of 63 μ\mus at distance-5 up to a million cycles, with a cycle time of 1.1 μ\mus. To probe the limits of our error-correction performance, we run repetition codes up to distance-29 and find that logical performance is limited by rare correlated error events occurring approximately once every hour, or 3 ×\times 109^9 cycles. Our results present device performance that, if scaled, could realize the operational requirements of large scale fault-tolerant quantum algorithms.


Thermalization and Criticality on an Analog-Digital Quantum Simulator

May 2024

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68 Reads

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1 Citation

Understanding how interacting particles approach thermal equilibrium is a major challenge of quantum simulators. Unlocking the full potential of such systems toward this goal requires flexible initial state preparation, precise time evolution, and extensive probes for final state characterization. We present a quantum simulator comprising 69 superconducting qubits which supports both universal quantum gates and high-fidelity analog evolution, with performance beyond the reach of classical simulation in cross-entropy benchmarking experiments. Emulating a two-dimensional (2D) XY quantum magnet, we leverage a wide range of measurement techniques to study quantum states after ramps from an antiferromagnetic initial state. We observe signatures of the classical Kosterlitz-Thouless phase transition, as well as strong deviations from Kibble-Zurek scaling predictions attributed to the interplay between quantum and classical coarsening of the correlated domains. This interpretation is corroborated by injecting variable energy density into the initial state, which enables studying the effects of the eigenstate thermalization hypothesis (ETH) in targeted parts of the eigenspectrum. Finally, we digitally prepare the system in pairwise-entangled dimer states and image the transport of energy and vorticity during thermalization. These results establish the efficacy of superconducting analog-digital quantum processors for preparing states across many-body spectra and unveiling their thermalization dynamics.


Dynamics of magnetization at infinite temperature in a Heisenberg spin chain

April 2024

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114 Reads

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32 Citations

Science

Understanding universal aspects of quantum dynamics is an unresolved problem in statistical mechanics. In particular, the spin dynamics of the one-dimensional Heisenberg model were conjectured as to belong to the Kardar-Parisi-Zhang (KPZ) universality class based on the scaling of the infinite-temperature spin-spin correlation function. In a chain of 46 superconducting qubits, we studied the probability distribution of the magnetization transferred across the chain’s center, P M . The first two moments of P M show superdiffusive behavior, a hallmark of KPZ universality. However, the third and fourth moments ruled out the KPZ conjecture and allow for evaluating other theories. Our results highlight the importance of studying higher moments in determining dynamic universality classes and provide insights into universal behavior in quantum systems.


Stable quantum-correlated many-body states through engineered dissipation

March 2024

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104 Reads

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47 Citations

Science

Engineered dissipative reservoirs have the potential to steer many-body quantum systems toward correlated steady states useful for quantum simulation of high-temperature superconductivity or quantum magnetism. Using up to 49 superconducting qubits, we prepared low-energy states of the transverse-field Ising model through coupling to dissipative auxiliary qubits. In one dimension, we observed long-range quantum correlations and a ground-state fidelity of 0.86 for 18 qubits at the critical point. In two dimensions, we found mutual information that extends beyond nearest neighbors. Lastly, by coupling the system to auxiliaries emulating reservoirs with different chemical potentials, we explored transport in the quantum Heisenberg model. Our results establish engineered dissipation as a scalable alternative to unitary evolution for preparing entangled many-body states on noisy quantum processors.


Fig. 1. Sycamore quantum processor architecture. (a) High-level architecture showing arrangements of qubits and couplers on a 2-D grid. (b) Representative schematic of a two-qubit patch of the Sycamore processor, highlighting internal control and measurement ports. In the actual chip, X Y and Z signals are multiplexed to a single port.
Fig. 5. Top-level chip block diagram.
Fig. 6. X Y controller block diagram, showing DRAG waveform generation.
Fig. 8. Block diagram of g/Z controller with example Z control waveform.
Design and Characterization of a ${

November 2023

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429 Reads

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6 Citations

IEEE Journal of Solid-State Circuits

A universal fault-tolerant quantum computer will require large-scale control systems that can realize all the waveforms required to implement a gateset that is universal for quantum computing. Optimization of such a system, which must be precise and extensible, is an open research challenge. Here, we present a cryogenic quantum control integrated circuit (IC) that is able to control all the necessary degrees of freedom of a two-qubit subcircuit of a superconducting quantum processor. Specifically, the IC contains a pair of 4–8-GHz RF pulse generators for XY control, three baseband current generators for qubit and coupler frequency control, and a digital controller that includes a sequencer for gate sequence playback. After motivating the architecture, we describe the circuit-level implementation details and present experimental results. Using standard benchmarking techniques, we show that the cryogenic CMOS (cryo-CMOS) IC is able to execute the components of a gateset that is universal for quantum computing while achieving single-qubit XY and Z average gate error rates of 0.17%–0.36% and 0.14%–0.17%, respectively, as well as two-qubit average cross-entropy benchmarking (XEB) cycle error rates of 1.2%. These error rates, which were achieved while dissipating just 4 mW/qubit, are comparable to the measured error rates obtained using baseline room-temperature electronics.


The UpCCD ansatz and its compilation to a 2D superconducting transmon grid
(top) Decomposition of the gates used in this experiment to CZ and single-qubit gates. See Supplementary Information Section II.B for details. (second from top, left) 2 × 5 grid with couplers in a square lattice geometry, showing couplers used during the ansatz (ring coupler, purple) and those used only during measurement (cross-coupler, red). (second from top, right) 2+1D circuit cartoon of a combined ansatz and measurement on a 2 × 5 transmon qubit array. (third from top) Cartoon of error-mitigation techniques used in this experiment. Different circuit pieces are described in the legend. (bottom) an example 8-qubit echo verification circuit to measure the expectation value of (X1X7 + Y1Y7 + Z1 + Z7)/2. Shaded gates at the top and bottom of the qubit array wrap around the 2 × 4 ring.
Digital quantum simulation of ground states of the RG model for ten spatial orbitals on a superconducting quantum device
a, Energy as a function of the coupling parameter g, estimated using various error-mitigation techniques (markers) and compared to classical models (lines). The classical pCCD results do not converge below a critical value, resulting in their cut-off. b, Log plot of experimental energy error (ignoring the model error from the UpCCD approximation). c, Many-body order parameter for the RG Hamiltonian (see text), again compared to classical models. d, Experimental error in estimating the superconducting order parameter versus the target state in the UpCCD approximation (again ignoring model error). Error bars show 1 standard deviation uncertainty from sampling noise, estimated by propagating variance (raw VQE, PS-VQE) or bootstrapping (EV, PS-VD); see Supplementary Information Section III for details. a.u., arbitrary units.
Scaling the simulation of the RG model to larger qubit counts
a, Experimental energy error (versus the UpCCD ground state) averaged over all points studied of the RG model. Error bars show sample standard deviation and lines a power-law fit. b, Experimental error in order parameter (versus the UpCCD ground state) averaged over all points studied of the RG model. Error bars and lines same as a. c, Different fidelity metrics for PS-VQE, EV, PS-VD and Loschmidt (LS) echo (see legend) averaged over all points studied of the RG model. d, Number of shots required for convergence at g = −0.9. Crosses and pluses give simulated estimations with two types of term grouping (see text for details) using observed fidelities of a ten-qubit experiment from c. Other symbols give experimental shots used.
Conrotatory CB ring opening pathway simulated in the seniority-zero subspace
Comparison of raw VQE (purple, ‘R’), PS-VQE (yellow, ‘PS’) and EV (green, ‘EV’) on an optimized unitary pair coupled-cluster ansatz. Darker (lighter) points correspond to six-qubit (6Q) (ten-qubit (10Q)) simulations. Error bars denote 1 s.d. calculated by either propagating error (VQE) or bootstrapping (EV). From left to right, the reaction path corresponds to the ring opening reaction. For the ten-orbital case, the unitary pair coupled-cluster ansatz (evaluated in simulation) has less than 1.8 × 10⁻⁴ energy difference from exact diagonalization in the seniority-zero space. The blue curves correspond to the exact diagonalization of the seniority-zero active space Hamiltonian spanning ten orbitals (broad, lighter-blue line) and six orbitals (narrow, darker-blue line). The red curve is the RHF mean-field energy. Some of the data are plotted on a discontinuous and different scale to preserve the visual scale of the reaction energy along the reaction coordinate.
Purification-based quantum error mitigation of pair-correlated electron simulations

October 2023

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153 Reads

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49 Citations

Nature Physics

An important measure of the development of quantum computing platforms has been the simulation of increasingly complex physical systems. Before fault-tolerant quantum computing, robust error-mitigation strategies were necessary to continue this growth. Here, we validate recently introduced error-mitigation strategies that exploit the expectation that the ideal output of a quantum algorithm would be a pure state. We consider the task of simulating electron systems in the seniority-zero subspace where all electrons are paired with their opposite spin. This affords a computational stepping stone to a fully correlated model. We compare the performance of error mitigations on the basis of doubling quantum resources in time or in space on up to 20 qubits of a superconducting qubit quantum processor. We observe a reduction of error by one to two orders of magnitude below less sophisticated techniques such as postselection. We study how the gain from error mitigation scales with the system size and observe a polynomial suppression of error with increased resources. Extrapolation of our results indicates that substantial hardware improvements will be required for classically intractable variational chemistry simulations.


Citations (47)


... Quantum devices with up to hundreds of individually addressable physical qubits are seeing significant experimental and theoretical interest [40][41][42][43]. Beyond further refining the implementation of prescheduled single-qubit and twoqubit gates, significant research has expanded to consider the optimal implementation and utilization of dynamic circuits [44][45][46][47][48][49]. ...

Reference:

Quantum computer error structure probed by quantum error correction syndrome measurements
Phase transitions in random circuit sampling

Nature

... These breakthroughs have undoubtedly pushed large-scale QEC research forward. Newly, Google Quantum AI and collaborators implemented a distance-7 surface code with 101 superconducting qubits (Acharya et al., 2024), which further reduces the logic error rate below the critical threshold. We should be aware that superconducting quantum computing will likely stay in the NISQ era for a long time, until the development of optimal solutions for QEC. ...

Quantum error correction below the surface code threshold

... Using interacting many-body quantum systems, one can enhance QB performance, especially through collective effects that exceed those of non-interacting systems. Heisenberg spin chains, known for their rich quantum phases and behaviors, are well-suited as working mediums for QBs and are readily realizable across various platforms, including NMR systems [13,[20][21][22], trapped ions [23][24][25][26], Rydberg atoms [27,28], and superconducting qubits [29]. ...

Dynamics of magnetization at infinite temperature in a Heisenberg spin chain
  • Citing Article
  • April 2024

Science

... A more heuristic approach using resonant ancillas as dissipative baths has been proposed in Refs. [8][9][10], and was recently implemented experimentally in [11]. In those works, one or more dissipative ancillas are coupled to one or more parts of the many-body system and the total new composite system is evolved until thermalization occurs. ...

Stable quantum-correlated many-body states through engineered dissipation
  • Citing Article
  • March 2024

Science

... This hybrid quantum algorithm is used in quantum chemistry, quantum simulations, and optimization problems [44,45]. Reference [46] provides a road map for the hardware requirement to have a clear quantum advantage in variational quantum simulations. The objective is to find the ground state of a given physical system by minimizing the energy E = ψ|Ĥ|ψ , whereĤ represents the Hamiltonian of the system. ...

Purification-based quantum error mitigation of pair-correlated electron simulations

Nature Physics

... However, a direct consequence of the existence of those extra accessible levels is that the qubit leaves the computational basis |0⟩ and |1⟩. This effect is known as leakage [13][14][15][16]. The existence of leakage makes the number of possible paths from an initial state to a final state to increase (as it is illustrated in Fig. 1b), thus, changing the time evolution operator. ...

Overcoming leakage in quantum error correction

Nature Physics

... Presumably in the integrable situation the origin of the KPZ scaling exponent in the integrable case is the formation of the long Bethe strings and the decay of the short strings nearby the long ones. More recently the presence of universal superdiffusion in correlators has been found in quantum gases [76], superconducting qubits [77] and neutron systems [2]. ...

Dynamics of magnetization at infinite temperature in a Heisenberg spin chain

... Unfortunately, we are not yet in position to experimentally generate and manipulate SUð2Þ k non-Abelian anyons. Quantum simulations, especially with versatile photonic or superconducting platforms, offer an exciting way to experimentally investigate properties of non-Abelian anyons [17][18][19][20][21]. Moreover, significant effort is dedicated in the experimental realization of Majorana zero modes (MZMs) [22][23][24]. ...

Non-Abelian braiding of graph vertices in a superconducting processor

Nature

... been demonstrated by sampling the final Haar-random states of randomized sequences of gate operations [35][36][37][38][39] . Recently, a method of measuring autocorrelation functions at infinite temperature based on the Haar-random states has been proposed, which opens up a practical application of pseudo-random quantum circuits for simulating hydrodynamics on NISQ devices 40,41 . ...

Phase transition in Random Circuit Sampling