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1. Realization of Constant-Depth Fan-Out with Real-Time Feedforward on a Superconducting Quantum Processor

Author

Song, Yongxin, Beltrán, Liberto, Besedin, Ilya, Kerschbaum, Michael, Pechal, Marek, Swiadek, François, Hellings, Christoph, Zanuz, Dante Colao, Flasby, Alexander, Besse, Jean-Claude, and Wallraff, Andreas

Subjects
Quantum Physics
Abstract

When using unitary gate sequences, the growth in depth of many quantum circuits with output size poses significant obstacles to practical quantum computation. The quantum fan-out operation, which reduces the circuit depth of quantum algorithms such as the quantum Fourier transform and Shor's algorithm, is an example that can be realized in constant depth independent of the output size. Here, we demonstrate a quantum fan-out gate with real-time feedforward on up to four output qubits using a superconducting quantum processor. By performing quantum state tomography on the output states, we benchmark our gate with input states spanning the entire Bloch sphere. We decompose the output-state error into a set of independently characterized error contributions. We extrapolate our constant-depth circuit to offer a scaling advantage compared to the unitary fan-out sequence beyond 25 output qubits with feedforward control, or beyond 17 output qubits if the classical feedforward latency is negligible. Our work highlights the potential of mid-circuit measurements combined with real-time conditional operations to improve the efficiency of complex quantum algorithms.

Published
2024

2. Direct implementation of a perceptron in superconducting circuit quantum hardware

Author

Pechal, Marek, Roy, Federico, Wilkinson, Samuel A., Salis, Gian, Werninghaus, Max, Hartmann, Michael J., and Filipp, Stefan

Subjects
Quantum Physics
Abstract

The utility of classical neural networks as universal approximators suggests that their quantum analogues could play an important role in quantum generalizations of machine-learning methods. Inspired by the proposal in [Torrontegui and Garc\'ia-Ripoll 2019 EPL 125 30004], we demonstrate a superconducting qubit implementation of an adiabatic controlled gate, which generalizes the action of a classical perceptron as the basic building block of a quantum neural network. We show full control over the steepness of the perceptron activation function, the input weight and the bias by tuning the adiabatic gate length, the coupling between the qubits and the frequency of the applied drive, respectively. In its general form, the gate realizes a multi-qubit entangling operation in a single step, whose decomposition into single- and two-qubit gates would require a number of gates that is exponential in the number of qubits. Its demonstrated direct implementation as perceptron in quantum hardware may therefore lead to more powerful quantum neural networks when combined with suitable additional standard gates.

Published
2021
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3. Radiative cooling of a spin ensemble

Author

Albanese, Bartolo, Probst, Sebastian, Ranjan, Vishal, Zollitsch, Cristoph, Pechal, Marek, Wallraff, Andreas, Morton, John, Vion, Denis, Esteve, Daniel, Flurin, Emmanuel, and Bertet, Patrice

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

Physical systems reach thermal equilibrium through energy exchange with their environment, and for spins in solids the relevant environment is almost always the host lattice in which they sit. However, recent studies motivated by observations from Purcell showed how coupling to a cavity can become the dominant form of relaxation for spins, given suitably strong spin-cavity coupling. In this regime, the cavity electromagnetic field takes over from the lattice as the dominant environment, inviting the prospect of controlling the spin temperature independently from that of the lattice, by engineering a suitable cavity field. Here, we report on precisely such control over spin temperature, illustrating a novel and universal method of electron spin hyperpolarisation. By switching the cavity input between loads at different temperatures we can control the electron spin polarisation, cooling it below the lattice temperature. Our demonstration uses donor spins in silicon coupled to a superconducting micro-resonator and we observe an increase of spin polarisation of over a factor of two. This approach provides general route to signal enhancement in electron spin resonance, or indeed nuclear magnetic resonance through dynamical nuclear spin polarisation (DNP).

Published
2019
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4. Electric fields for light: Propagation of microwave photons along a synthetic dimension

Author

Lee, Nathan R. A., Pechal, Marek, Wollack, E. Alex, Arrangoiz-Arriola, Patricio, Wang, Zhaoyou, and Safavi-Naeini, Amir H.

Subjects
Quantum Physics, Physics - Optics
Abstract

The evenly-spaced modes of an electromagnetic resonator are coupled to each other by appropriate time-modulation, leading to dynamics analogous to those of particles hopping between different sites of a lattice. This substitution of a real spatial dimension of a lattice with a "synthetic'" dimension in frequency space greatly reduces the hardware complexity of an analog quantum simulator. Complex control and read-out of a highly multi-moded structure can thus be accomplished with very few physical control lines. We demonstrate this concept with microwave photons in a superconducting transmission line resonator by modulating the system parameters at frequencies near the resonator's free spectral range and observing propagation of photon wavepackets in time domain. The linear propagation dynamics are equivalent to a tight-binding model, which we probe by measuring scattering parameters between frequency sites. We extract an approximate tight-binding dispersion relation for the synthetic lattice and initialize photon wavepackets with well-defined quasimomenta and group velocities. As an example application of this platform in simulating a physical system, we demonstrate Bloch oscillations associated with a particle in a periodic potential and subject to a constant external field. The simulated field strongly affects the photon dynamics despite photons having zero charge. Our observation of photon dynamics along a synthetic frequency dimension generalizes immediately to topological photonics and single-photon power levels, and expands the range of physical systems addressable by quantum simulation., Comment: 23 pages, 11 figures

Published
2019
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5. Mechanical Purcell Filters for Microwave Quantum Machines

Author

Cleland, Agnetta Y., Pechal, Marek, Stas, Pieter-Jan C., Sarabalis, Christopher J., and Safavi-Naeini, Amir H.

Subjects
Quantum Physics
Abstract

In circuit quantum electrodynamics, measuring the state of a superconducting qubit introduces a loss channel which can enhance spontaneous emission through the Purcell effect, thus decreasing qubit lifetime. This decay can be mitigated by performing the measurement through a Purcell filter which forbids signal propagation at the qubit transition frequency. If the filter is also well-matched at the readout cavity frequency, it will protect the qubit from decoherence channels without sacrificing measurement speed. We propose and analyze design for a mechanical Purcell filter, which we also fabricate and characterize at room temperature. The filter is comprised of an array of nanomechanical resonators in thin-film lithium niobate, connected in a ladder topology, with series and parallel resonances arranged to produce a bandpass response. The modest footprint, steep band edges, and absence of cross-talk in these filters make them a novel and appealing alternative to analogous electromagnetic versions currently used in microwave quantum machines., Comment: 5 pages, 5 figures

Published
2019
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6. Resolving the energy levels of a nanomechanical oscillator

Author

Arrangoiz-Arriola, Patricio, Wollack, E. Alex, Wang, Zhaoyou, Pechal, Marek, Jiang, Wentao, McKenna, Timothy P., Witmer, Jeremy D., and Safavi-Naeini, Amir H.

Subjects
Quantum Physics
Abstract

The coherent states that describe the classical motion of a mechanical oscillator do not have well-defined energy, but are rather quantum superpositions of equally-spaced energy eigenstates. Revealing this quantized structure is only possible with an apparatus that measures the mechanical energy with a precision greater than the energy of a single phonon, $\hbar\omega_\text{m}$. One way to achieve this sensitivity is by engineering a strong but nonresonant interaction between the oscillator and an atom. In a system with sufficient quantum coherence, this interaction allows one to distinguish different phonon number states by resolvable differences in the atom's transition frequency. Such dispersive measurements have been studied in cavity and circuit quantum electrodynamics where experiments using real and artificial atoms have resolved the photon number states of cavities. Here, we report an experiment where an artificial atom senses the motional energy of a driven nanomechanical oscillator with sufficient sensitivity to resolve the quantization of its energy. To realize this, we build a hybrid platform that integrates nanomechanical piezoelectric resonators with a microwave superconducting qubit on the same chip. We excite phonons with resonant pulses of varying amplitude and probe the resulting excitation spectrum of the qubit to observe phonon-number-dependent frequency shifts $\approx 5$ times larger than the qubit linewidth. Our result demonstrates a fully integrated platform for quantum acoustics that combines large couplings, considerable coherence times, and excellent control over the mechanical mode structure. With modest experimental improvements, we expect our approach will make quantum nondemolition measurements of phonons an experimental reality, leading the way to new quantum sensors and information processing approaches that use chip-scale nanomechanical devices., Comment: 16 pages, 10 figures

Published
2019
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7. Quantum dynamics of a few-photon parametric oscillator

Author

Wang, Zhaoyou, Pechal, Marek, Wollack, E. Alex, Arrangoiz-Arriola, Patricio, Gao, Maodong, Lee, Nathan R., and Safavi-Naeini, Amir H.

Subjects
Quantum Physics
Abstract

Modulating the frequency of a harmonic oscillator at nearly twice its natural frequency leads to amplification and self-oscillation. Above the oscillation threshold, the field settles into a coherent oscillating state with a well-defined phase of either $0$ or $\pi$. We demonstrate a quantum parametric oscillator operating at microwave frequencies and drive it into oscillating states containing only a few photons. The small number of photons present in the system and the coherent nature of the nonlinearity prevents the environment from learning the randomly chosen phase of the oscillator. This allows the system to oscillate briefly in a quantum superposition of both phases at once - effectively generating a nonclassical Schr\"{o}dinger's cat state. We characterize the dynamics and states of the system by analyzing the output field emitted by the oscillator and implementing quantum state tomography suited for nonlinear resonators. By demonstrating a quantum parametric oscillator and the requisite techniques for characterizing its quantum state, we set the groundwork for new schemes of quantum and classical information processing and extend the reach of these ubiquitous devices deep into the quantum regime.

Published
2019
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8. Two-Photon Resonance Fluorescence of a Ladder-Type Atomic System

Author

Gasparinetti, Simone, Besse, Jean-Claude, Pechal, Marek, Buijs, Robin D., Eichler, Christopher, Carmichael, Howard J., and Wallraff, Andreas

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

Multi-photon emitters are a sought-after resource in quantum photonics. Nonlinear interactions between a multi-level atomic system and a coherent drive can lead to resonant two-photon emission, but harvesting light from this process has remained a challenge due to the small oscillator strengths involved. Here we present a study of two-photon resonance fluorescence at microwave frequencies, using a superconducting, ladder-type artificial atom, a transmon, strongly coupled to a waveguide. We drive the two-photon transition between the ground and second-excited state at increasingly high powers and observe a resonance fluorescence peak whose intensity becomes comparable to single-photon emission until it splits into a Mollow-like triplet. We measure photon correlations of frequency-filtered spectral lines and find that while emission at the fundamental frequency stays antibunched, the resonance fluorescence peak at the two-photon transition is superbunched. Our results provide a route towards the realization of multi-photon sources in the microwave domain.

Published
2019
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9. Quantum communication with time-bin encoded microwave photons

Author

Kurpiers, Philipp, Pechal, Marek, Royer, Baptiste, Magnard, Paul, Walter, Theo, Heinsoo, Johannes, Salathé, Yves, Akin, Abdulkadir, Storz, Simon, Besse, Jean-Claude, Gasparinetti, Simone, Blais, Alexandre, and Wallraff, Andreas

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

Heralding techniques are useful in quantum communication to circumvent losses without resorting to error correction schemes or quantum repeaters. Such techniques are realized, for example, by monitoring for photon loss at the receiving end of the quantum link while not disturbing the transmitted quantum state. We describe and experimentally benchmark a scheme that incorporates error detection in a quantum channel connecting two transmon qubits using traveling microwave photons. This is achieved by encoding the quantum information as a time-bin superposition of a single photon, which simultaneously realizes high communication rates and high fidelities. The presented scheme is straightforward to implement in circuit QED and is fully microwave-controlled, making it an interesting candidate for future modular quantum computing architectures.

Published
2018
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10. Superconducting circuit quantum computing with nanomechanical resonators as storage

Author

Pechal, Marek, Arrangoiz-Arriola, Patricio, and Safavi-Naeini, Amir H.

Subjects
Quantum Physics
Abstract

We analyze the quantum information processing capability of a superconducting transmon circuit used to mediate interactions between quantum information stored in a collection of phononic crystal cavity resonators. Having only a single processing element to be controlled externally makes this approach significantly less hardware-intensive than traditional architectures with individual control of each qubit. Moreover, when compared with the commonly considered alternative approach using coplanar waveguide or 3d cavity microwave resonators for storage, the nanomechanical resonators offer both very long lifetime and small size -- two conflicting requirements for microwave resonators. A detailed gate error analysis leads to an optimal value for the qubit-resonator coupling rate as a function of the number of mechanical resonators in the system. For a given set of system parameters, a specific amount of coupling and number of resonators is found to optimize the quantum volume, an approximate measure for the computational capacity of a system. We see this volume is higher in the proposed hybrid nanomechanical architecture than in the competing on-chip electromagnetic approach.

Published
2018
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11. Observation of the Crossover from Photon Ordering to Delocalization in Tunably Coupled Resonators

Author

Collodo, Michele C., Potočnik, Anton, Gasparinetti, Simone, Besse, Jean-Claude, Pechal, Marek, Sameti, Mahdi, Hartmann, Michael J., Wallraff, Andreas, and Eichler, Christopher

Subjects
Quantum Physics
Abstract

Networks of nonlinear resonators offer intriguing perspectives as quantum simulators for non-equilibrium many-body phases of driven-dissipative systems. Here, we employ photon correlation measurements to study the radiation fields emitted from a system of two superconducting resonators, coupled nonlinearly by a superconducting quantum interference device (SQUID). We apply a parametrically modulated magnetic flux to control the linear photon hopping rate between the two resonators and its ratio with the cross-Kerr rate. When increasing the hopping rate, we observe a crossover from an ordered to a delocalized state of photons. The presented coupling scheme is intrinsically robust to frequency disorder and may therefore prove useful for realizing larger-scale resonator arrays.

Published
2018
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12. Coupling a superconducting quantum circuit to a phononic crystal defect cavity

Author

Arrangoiz-Arriola, Patricio, Wollack, E. Alex, Pechal, Marek, Witmer, Jeremy D., Hill, Jeff T., and Safavi-Naeini, Amir H.

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

Connecting nanoscale mechanical resonators to microwave quantum circuits opens new avenues for storing, processing, and transmitting quantum information. In this work, we couple a phononic crystal cavity to a tunable superconducting quantum circuit. By fabricating a one-dimensional periodic pattern in a thin film of lithium niobate and introducing a defect in this artificial lattice, we localize a 6 gigahertz acoustic resonance to a wavelength-scale volume of less than one cubic micron. The strong piezoelectricity of lithium niobate efficiently couples the localized vibrations to the electric field of a widely tunable high-impedance Josephson junction array resonator. We measure a direct phonon-photon coupling rate $g/2\pi \approx 1.6 \, \mathrm{MHz}$ and a mechanical quality factor $Q_\mathrm{m} \approx 3 \times 10^4$ leading to a cooperativity $C\sim 4$ when the two modes are tuned into resonance. Our work has direct application to engineering hybrid quantum systems for microwave-to-optical conversion as well as emerging architectures for quantum information processing., Comment: 9 pages, 7 figures

Published
2018
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13. Fast and Unconditional All-Microwave Reset of a Superconducting Qubit

Author

Magnard, Paul, Kurpiers, Philipp, Royer, Baptiste, Walter, Theo, Besse, Jean-Claude, Gasparinetti, Simone, Pechal, Marek, Heinsoo, Johannes, Storz, Simon, Blais, Alexandre, and Wallraff, Andreas

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

Active qubit reset is a key operation in many quantum algorithms, and particularly in error correction codes. Here, we experimentally demonstrate a reset scheme of a three level transmon artificial atom coupled to a large bandwidth resonator. The reset protocol uses a microwave-induced interaction between the $|f,0\rangle$ and $|g,1\rangle$ states of the coupled transmon-resonator system, with $|g\rangle$ and $|f\rangle$ denoting the ground and second excited states of the transmon, and $|0\rangle$ and $|1\rangle$ the photon Fock states of the resonator. We characterize the reset process and demonstrate reinitialization of the transmon-resonator system to its ground state with $0.2\%$ residual excitation in less than $500 \, \rm{ns}$. Our protocol is of practical interest as it has no requirements on the architecture, beyond those for fast and efficient single-shot readout of the transmon, and does not require feedback.

Published
2018
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14. Deterministic Quantum State Transfer and Generation of Remote Entanglement using Microwave Photons

Author

Kurpiers, Philipp, Magnard, Paul, Walter, Theo, Royer, Baptiste, Pechal, Marek, Heinsoo, Johannes, Salathé, Yves, Akin, Abdulkadir, Storz, Simon, Besse, Jean-Claude, Gasparinetti, Simone, Blais, Alexandre, and Wallraff, Andreas

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

Sharing information coherently between nodes of a quantum network is at the foundation of distributed quantum information processing. In this scheme, the computation is divided into subroutines and performed on several smaller quantum registers connected by classical and quantum channels. A direct quantum channel, which connects nodes deterministically, rather than probabilistically, is advantageous for fault-tolerant quantum computation because it reduces the threshold requirements and can achieve larger entanglement rates. Here, we implement deterministic state transfer and entanglement protocols between two superconducting qubits fabricated on separate chips. Superconducting circuits constitute a universal quantum node capable of sending, receiving, storing, and processing quantum information. Our implementation is based on an all-microwave cavity-assisted Raman process which entangles or transfers the qubit state of a transmon-type artificial atom to a time-symmetric itinerant single photon. We transfer qubit states at a rate of $50 \, \rm{kHz}$ using the emitted photons which are absorbed at the receiving node with a probability of $98.1 \pm 0.1 \%$ achieving a transfer process fidelity of $80.02 \pm 0.07 \%$. We also prepare on demand remote entanglement with a fidelity as high as $78.9 \pm 0.1 \%$. Our results are in excellent agreement with numerical simulations based on a master equation description of the system. This deterministic quantum protocol has the potential to be used as a backbone of surface code quantum error correction across different nodes of a cryogenic network to realize large-scale fault-tolerant quantum computation in the circuit quantum electrodynamic architecture., Comment: 11 pages 8 Figures

Published
2017
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15. Single-Shot Quantum Non-Demolition Detection of Itinerant Microwave Photons

Author

Besse, Jean-Claude, Gasparinetti, Simone, Collodo, Michele C., Walter, Theo, Kurpiers, Philipp, Pechal, Marek, Eichler, Christopher, and Wallraff, Andreas

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

Single-photon detection is an essential component in many experiments in quantum optics, but remains challenging in the microwave domain. We realize a quantum non-demolition detector for propagating microwave photons and characterize its performance using a single-photon source. To this aim we implement a cavity-assisted conditional phase gate between the incoming photon and a superconducting artificial atom. By reading out the state of this atom in single shot, we reach an internal photon detection fidelity of 71%, limited by the coherence properties of the qubit. By characterizing the coherence and average number of photons in the field reflected off the detector, we demonstrate its quantum non-demolition nature. We envisage applications in generating heralded remote entanglement between qubits and for realizing logic gates between propagating microwave photons.

Published
2017
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16. Millimeter-wave interconnects for microwave-frequency quantum machines

Author

Pechal, Marek and Safavi-Naeini, Amir H.

Subjects
Quantum Physics
Abstract

Superconducting microwave circuits form a versatile platform for storing and manipulating quantum information. A major challenge to further scalability is to find approaches for connecting these systems over long distances and at high rates. One approach is to convert the quantum state of a microwave circuit to optical photons that can be transmitted over kilometers at room temperature with little loss. Many proposals for electro-optic conversion between microwave and optics use optical driving of a weak three-wave mixing nonlinearity to convert the frequency of an excitation. Residual absorption of this optical pump leads to heating, which is problematic at cryogenic temperatures. Here we propose an alternative approach where a nonlinear superconducting circuit is driven to interconvert between microwave-frequency and millimeter-wave-frequency (300 GHz) photons. To understand the potential for quantum conversion between microwave and mm-wave photons, we consider the driven four-wave mixing quantum dynamics of nonlinear circuits. In contrast to the linear dynamics of the driven three-wave mixing converters, the proposed four-wave mixing converter has nonlinear decoherence channels that lead to a more complex parameter space of couplings and pump powers that we map out. We consider physical realizations of such converter circuits by deriving theoretically the upper bound on the maximum obtainable nonlinear coupling between any two modes in a lossless circuit, and synthesizing an optimal circuit based on realistic materials that saturates this bound. Our proposed circuit dissipates less than $10^{-9}$ times the energy of current electro-optic converters per qubit. Finally, we outline the quantum link budget for optical, microwave, and mm-wave connections, showing that our approach is viable for realizing interconnected quantum processors for intracity or quantum datacenter environments.

Published
2017
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17. Correlations and entanglement of microwave photons emitted in a cascade decay

Author

Gasparinetti, Simone, Pechal, Marek, Besse, Jean-Claude, Mondal, Mintu, Eichler, Christopher, and Wallraff, Andreas

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

An excited emitter decays by radiating a photon into a quantized mode of the electromagnetic field, a process known as spontaneous emission. If the emitter is driven to a higher excited state, it radiates multiple photons in a cascade decay. Atomic and biexciton cascades have been exploited as sources of polarization-entangled photon pairs. Because the photons are emitted sequentially, their intensities are strongly correlated in time, as measured in a double-beam coincidence experiment. Perhaps less intuitively, their phases can also be correlated, provided a single emitter is deterministically prepared into a superposition state, and the emitted radiation is detected in a phase-sensitive manner and with high efficiency. Here we have met these requirements by using a superconducting artificial atom, coherently driven to its second-excited state and decaying into a well-defined microwave mode. Our results highlight the coherent nature of cascade decay and demonstrate a novel protocol to generate entanglement between itinerant field modes.

Published
2017
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18. Measurement of a Vacuum-Induced Geometric Phase

Author

Gasparinetti, Simone, Berger, Simon, Abdumalikov, Abdufarrukh A., Pechal, Marek, Filipp, Stefan, and Wallraff, Andreas J.

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

Berry's geometric phase naturally appears when a quantum system is driven by an external field whose parameters are slowly and cyclically changed. A variation in the coupling between the system and the external field can also give rise to a geometric phase, even when the field is in the vacuum state or any other Fock state. Here we demonstrate the appearance of a vacuum-induced Berry phase in an artificial atom, a superconducting transmon, interacting with a single mode of a microwave cavity. As we vary the phase of the interaction, the artificial atom acquires a geometric phase determined by the path traced out in the combined Hilbert space of the atom and the quantum field. Our ability to control this phase opens new possibilities for the geometric manipulation of atom-cavity systems also in the context of quantum information processing., Comment: 5 + 6 pages

Published
2016
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23. Towards Millimeter-Wave Based Quantum Networks

Author

Stokowski, Hubert, primary, Pechal, Marek, additional, Snively, Emma, additional, Kevin Multani, K. S., additional, Welander, Paul B., additional, Witmer, Jeremy, additional, Nanni, Emilio A., additional, and Safavi-Naeini, Amir H., additional

Published
2019
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24. Resolving the energy levels of a nanomechanical oscillator

Author

Arrangoiz-Arriola, Patricio, primary, Wollack, E. Alex, additional, Wang, Zhaoyou, additional, Pechal, Marek, additional, Jiang, Wentao, additional, McKenna, Timothy P., additional, Witmer, Jeremy D., additional, Van Laer, Raphaël, additional, and Safavi-Naeini, Amir H., additional

Published
2019
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26. Microwave Quantum Acoustic Processor

Author

Arrangoiz-Arriola, Patricio, primary, Wollack, E. Alex, additional, Pechal, Marek, additional, Jiang, Wentao, additional, Wang, Zhaoyou, additional, McKenna, Timothy P., additional, Witmer, Jeremy, additional, Laer, Raphael Van, additional, Cleland, Agnetta, additional, Lee, Nathan, additional, Sarabalis, Christopher J., additional, Stas, Pieter-Jan, additional, and Safavi-Naeini, Amir H., additional

Published
2019
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33. Microwave photonics in superconducting circuits

Author

Pechal, Marek, Wallraff, Andreas, and Home, Jonathan

Subjects
Electric engineering, QUANTENELEKTRODYNAMIK, SUPERCONDUCTIVITY (CONDENSED MATTER PHYSICS), MICROWAVE ENGINEERING (ELECTRICAL ENGINEERING), SUPRALEITFÄHIGKEIT (PHYSIK DER KONDENSIERTEN MATERIE), ddc:621.3, MIKROWELLENTECHNIK (ELEKTROTECHNIK), Physics, QUANTUM ELECTRODYNAMICS, OPTICAL TELECOMMUNICATIONS + PHOTONICS (TELECOMMUNICATIONS), OPTISCHE NACHRICHTENTECHNIK + PHOTONIK (NACHRICHTENTECHNIK), QUANTENINFORMATION (INFORMATIONSTHEORIE), QUANTUM INFORMATION (INFORMATION THEORY), ddc:530
Published
2016

38. Microwave-Controlled Generation of Shaped Single Photons in Circuit Quantum Electrodynamics

Author

Pechal, Marek, Huthmacher, Lukas, Eichler, C., Zeytinoğlu, Sina, Abdumalikov, Abdufarrukh A., Berger, S., Wallraff, Andreas, and Filipp, S.

Subjects
7. Clean energy
Abstract

Large-scale quantum information processors or quantum communication networks will require reliable exchange of information between spatially separated nodes. The links connecting these nodes can be established using traveling photons that need to be absorbed at the receiving node with high efficiency. This is achievable by shaping the temporal profile of the photons and absorbing them at the receiver by time reversing the emission process. Here, we demonstrate a scheme for creating shaped microwave photons using a superconducting transmon-type three-level system coupled to a transmission line resonator. In a second-order process induced by a modulated microwave drive, we controllably transfer a single excitation from the third level of the transmon to the resonator and shape the emitted photon. We reconstruct the density matrices of the created single-photon states and show that the photons are antibunched. We also create multipeaked photons with a controlled amplitude and phase. In contrast to similar existing schemes, the one we present here is based solely on microwave drives, enabling operation with fixed frequency transmons., Physical Review X, 4, ISSN:2160-3308

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