Your search keyword '"Delsing, P."' showing total 745 results

1. On-demand single microwave photon source in a superconducting circuit with pulse-level frequency tunability over two octaves of bandwidth

Author

Hawaldar, Samarth, Khaire, Siddhi Satish, Delsing, Per, and Suri, Baladitya

Subjects

Quantum Physics

Abstract

In this article, we propose a new method of generating single microwave photons in superconducting circuits. We theoretically show that pure single microwave photons can be generated on demand and tuned over a large frequency band by making use of Landau-Zener transitions under a rapid sweep of a control parameter. We devise a protocol that enables pulse-level control of the frequency of the emitted photon over two octaves, without requiring extensive calibration. Additionally, we make theoretical estimates of the generation efficiency, tunability, purity, and linewidth of the photons emitted using this method for both charge and flux qubit-based architectures. We also provide estimates of optimal device parameters for these architectures in order to realize the device., Comment: 7+7 pages, 12 figures, Comments welcome

Published

2024

2. A small footprint travelling-wave parametric amplifier with a high Signal-to-Noise Ratio improvement in a wide band

Author

Nilsson, Hampus Renberg, Chen, Liangyu, Tancredi, Giovanna, Rehammar, Robert, Shiri, Daryoush, Nilsson, Filip, Osman, Amr, Shumeiko, Vitaly, and Delsing, Per

Subjects

Physics - Applied Physics, Quantum Physics

Abstract

We characterise a small footprint travelling-wave parametric amplifier (TWPA). The TWPA is built with magnetically flux-tunable superconducting nonlinear asymmetric inductive elements (SNAILs) and parallel-plate capacitors. It implements three-wave mixing (3WM) with resonant phase matching (RPM), a small cutoff frequency for high gain per unitcell and impedance matching networks for large bandwidth impedance matching. The device has 200 unitcells and a physical footprint of only 1.1 mm^2, yet demonstrates an average parametric gain of 19 dB over a 3 GHz bandwidth, an average effective signal-to-noise ratio improvement of 10 dB and a clear speedup of qubit readout time., Comment: 9 pages + 2 appendix pages, 3 figures + 2 appendix figures

Published

2024

3. Experimental Evaluation of Moving Target Compensation in High Time-Bandwidth Noise Radar

Author

Ankel, Martin, Jonsson, Robert S., Tholen, Mats, Bryllert, Tomas, Ulander, Lars M. H., and Delsing, Per

Subjects

Electrical Engineering and Systems Science - Signal Processing

Abstract

In this article, the effect a moving target has on the signal-to-interference-plus-noise-ratio (SINR) for high time-bandwidth noise radars is investigated. To compensate for cell migration we apply a computationally efficient stretch processing algorithm that is tailored for batched processing and suitable for implementation onto a real-time radar processor. The performance of the algorithm is studied using experimental data. In the experiment, pseudorandom noise, with a bandwidth of 100 MHz, is generated and transmitted in real-time. An unmanned aerial vehicle (UAV), flown at a speed of 11 m/s, is acting as a target. For an integration time of 1 s, the algorithm is shown to yield an increase in SINR of roughly 13 dB, compared to no compensation. It is also shown that coherent integration times of 2.5 s can be achieved., Comment: Presented at 2023 20th European Radar Conference (EuRAD)

Published

2024

4. Implementing a School-Wide Trauma-Informed Education Approach: An Evaluation of Student-Outcomes during the First Year of Implementation

Author

de Stigter, Rianne Wassink –, Nelen, Wendy, Delsing, Marc, de Berk, Afra, Kooijmans, Roel, Offerman, Evelyne, Asselman, Michiel, Nijhof, Karin, Lindauer, Ramón, and Helmond, Petra

Published

2024

5. SysML modeling of service-oriented system-of-systems

Author

Delsing, Jerker, Kulcsár, Géza, and Haugen, Øystein

Published

2024

6. Mitigation of interfacial dielectric loss in aluminum-on-silicon superconducting qubits

Author

Biznárová, Janka, Osman, Amr, Rehnman, Emil, Chayanun, Lert, Križan, Christian, Malmberg, Per, Rommel, Marcus, Warren, Christopher, Delsing, Per, Yurgens, August, Bylander, Jonas, and Fadavi Roudsari, Anita

Published

2024

7. Universal control of a bosonic mode via drive-activated native cubic interactions

Author

Eriksson, Axel M., Sépulcre, Théo, Kervinen, Mikael, Hillmann, Timo, Kudra, Marina, Dupouy, Simon, Lu, Yong, Khanahmadi, Maryam, Yang, Jiaying, Castillo-Moreno, Claudia, Delsing, Per, and Gasparinetti, Simone

Published

2024

8. Peripheral circuits for ideal performance of a travelling-wave parametric amplifier

Author

Nilsson, Hampus Renberg, Shiri, Daryoush, Rehammar, Robert, Roudsari, Anita Fadavi, and Delsing, Per

Subjects

Quantum Physics

Abstract

We investigate the required peripheral circuits to enable ideal performance for a high-gain travelling-wave parametric amplifier (TWPA) based on three-wave mixing (3WM). By embedding the TWPA in a network of superconducting diplexers, hybrid couplers and impedance matching networks, the amplifier can deliver a high stable gain with near-quantum-limited noise performance, with suppressed gain ripples, while eliminating the reflections of the signal, the idler and the pump as well as the transmission of all unwanted tones. We also demonstrate a configuration where the amplifier can isolate. We call this technique Wideband Idler Filtering (WIF). The theory is supported by simulations that predict over 20 dB gain in the 4-8 GHz band with 10 dB isolation for a single amplifier and 30 dB isolation for two cascaded amplifiers. We demonstrate how the WIF-TWPAs can be used to construct controllable isolators with over 40 dB isolation over the full 4-8 GHz band., Comment: 9 pages, 3 figures, 1 table

Published

2023

9. Mitigation of interfacial dielectric loss in aluminum-on-silicon superconducting qubits

Author

Biznárová, Janka, Osman, Amr, Rehnman, Emil, Chayanun, Lert, Križan, Christian, Malmberg, Per, Rommel, Marcus, Warren, Christopher, Delsing, Per, Yurgens, August, Bylander, Jonas, and Roudsari, Anita Fadavi

Subjects

Quantum Physics, Condensed Matter - Superconductivity

Abstract

We demonstrate aluminum-on-silicon planar transmon qubits with time-averaged ${T_1}$ energy relaxation times of up to ${270\,\mu s}$, corresponding to Q = 5 million, and a highest observed value of ${501\,\mu s}$. We use materials analysis techniques and numerical simulations to investigate the dominant sources of energy loss, and devise and demonstrate a strategy towards mitigating them. The mitigation of loss is achieved by reducing the presence of oxide, a known host of defects, near the substrate-metal interface, by growing aluminum films thicker than 300 nm. A loss analysis of coplanar-waveguide resonators shows that the improvement is owing to a reduction of dielectric loss due to two-level system defects. We perform time-of-flight secondary ion mass spectrometry and observe a reduced presence of oxygen at the substrate-metal interface for the thicker films. The correlation between the enhanced performance and the film thickness is due to the tendency of aluminum to grow in columnar structures of parallel grain boundaries, where the size of the grain depends on the film thickness: transmission electron microscopy imaging shows that the thicker film has larger grains and consequently fewer grain boundaries containing oxide near this interface. These conclusions are supported by numerical simulations of the different loss contributions in the device., Comment: 13 pages, 11 figures, 2 tables

Published

2023

10. Universal control of a bosonic mode via drive-activated native cubic interactions

Author

Eriksson, Axel M., Sépulcre, Théo, Kervinen, Mikael, Hillmann, Timo, Kudra, Marina, Dupouy, Simon, Lu, Yong, Khanahmadi, Maryam, Yang, Jiaying, Moreno, Claudia Castillo, Delsing, Per, and Gasparinetti, Simone

Subjects

Quantum Physics

Abstract

Linear bosonic modes offer a hardware-efficient alternative for quantum information processing but require access to some nonlinearity for universal control. The lack of nonlinearity in photonics has led to encoded measurement-based quantum computing, which rely on linear operations but requires access to resourceful ('nonlinear') quantum states, such as cubic phase states. In contrast, superconducting microwave circuits offer engineerable nonlinearities but suffer from static Kerr nonlinearity. Here, we demonstrate universal control of a bosonic mode composed of a superconducting nonlinear asymmetric inductive element (SNAIL) resonator, enabled by native nonlinearities in the SNAIL element. We suppress static nonlinearities by operating the SNAIL in the vicinity of its Kerr-free point and dynamically activate nonlinearities up to third order by fast flux pulses. We experimentally realize a universal set of generalized squeezing operations, as well as the cubic phase gate, and exploit them to deterministically prepare a cubic phase state in 60 ns. Our results initiate the experimental field of universal continuous-variables quantum computing., Comment: 11 pages, 6 figures and supplementary materials

Published

2023

11. Fast generation of Schr\'odinger cat states in a Kerr-tunable superconducting resonator

Author

He, X. L., Lu, Yong, Bao, D. Q., Xue, Hang, Jiang, W. B., Wang, Zhen, Roudsari, A. F., Delsing, Per, Tsai, J. S., and Lin, Z. R.

Subjects

Quantum Physics

Abstract

Schr\"odinger cat states, quantum superpositions of macroscopically distinct classical states, are an important resource for quantum communication, quantum metrology and quantum computation. Especially, cat states in a phase space protected against phase-flip errors can be used as a logical qubit. However, cat states, normally generated in three-dimensional cavities, are facing the challenges of scalability and controllability. Here, we present a novel strategy to generate and store cat states in a coplanar superconducting circuit by the fast modulation of Kerr nonlinearity. At the Kerr-free work point, our cat states are passively preserved due to the vanishing Kerr effect. We are able to prepare a 2-component cat state in our chip-based device with a fidelity reaching 89.1% under a 96 ns gate time. Our scheme shows an excellent route to constructing a chip-based bosonic quantum processor., Comment: 15 pages,12 figures

Published

2023

12. Modeling and Harmonic Balance Analysis of Parametric Amplifiers for Qubit Read-out

Author

Shiri, Daryoush, Nilsson, Hampus Renberg, Telluri, Pavan, Roudsari, Anita Fadavi, Shumeiko, Vitaly, Fager, Christian, and Delsing, Per

Subjects

Quantum Physics, Condensed Matter - Superconductivity, Electrical Engineering and Systems Science - Signal Processing, Nonlinear Sciences - Pattern Formation and Solitons

Abstract

Predicting the performance of traveling-wave parametric amplifiers (TWPAs) based on nonlinear elements like superconducting Josephson junctions (JJs) is vital for qubit read-out in quantum computers. The purpose of this article is twofold: (a) to demonstrate how nonlinear inductors based on combinations of JJs can be modeled in commercial circuit simulators, and (b) to show how the harmonic balance (HB) is used in the reliable prediction of the amplifier performance e.g., gain and pump harmonic power conversion. Experimental characterization of two types of TWPA architectures is compared with simulations to showcase the reliability of the HB method. We disseminate the modeling know-how and techniques to new designers of parametric amplifiers., Comment: 38 pages, 19 figures

Published

2023

13. Automated and Secure Onboarding for System of Systems

Author

Maksuti, Silia, Bicaku, Ani, Zsilak, Mario, Ivkić, Igor, Péceli, Bálint, Singler, Gábor, Kovács, Kristóf, Tauber, Markus, and Delsing, Jerger

Subjects

Computer Science - Cryptography and Security

Abstract

The Internet of Things (IoT) is rapidly changing the number of connected devices and the way they interact with each other. This increases the need for an automated and secure onboarding procedure for IoT devices, systems and services. Device manufacturers are entering the market with internet connected devices, ranging from small sensors to production devices, which are subject of security threats specific to IoT. The onboarding procedure is required to introduce a new device in a System of Systems (SoS) without compromising the already onboarded devices and the underlying infrastructure. Onboarding is the process of providing access to the network and registering the components for the first time in an IoT/SoS framework, thus creating a chain of trust from the hardware device to its hosted software systems and their provided services. The large number and diversity of device hardware, software systems and running services raises the challenge to establish a generic onboarding procedure. In this paper, we present an automated and secure onboarding procedure for SoS. We have implemented the onboarding procedure in the Eclipse Arrowhead framework. However, it can be easily adapted for other IoT/SoS frameworks that are based on Service-oriented Architecture (SoA) principles. The automated onboarding procedure ensures a secure and trusted communication between the new IoT devices and the Eclipse Arrowhead framework. We show its application in a smart charging use case and perform a security assessment., Comment: IEEE Access

Published

2023

14. Quantum process tomography of continuous-variable gates using coherent states

Author

Kervinen, Mikael, Ahmed, Shahnawaz, Kudra, Marina, Eriksson, Axel, Quijandría, Fernando, Kockum, Anton Frisk, Delsing, Per, and Gasparinetti, Simone

Subjects

Quantum Physics

Abstract

Encoding quantum information into superpositions of multiple Fock states of a harmonic oscillator can provide protection against errors, but it comes with the cost of requiring more complex quantum gates that need to address multiple Fock states simultaneously. Therefore, characterizing the quantum process fidelity of these gates also becomes more challenging. Here, we demonstrate the use of coherent-state quantum process tomography (csQPT) for a bosonic-mode superconducting circuit. CsQPT uses coherent states as input probes for the quantum process in order to completely characterize the quantum operation for an arbitrary input state. We show results for this method by characterizing a logical quantum gate constructed using displacement and SNAP operations on an encoded qubit. With csQPT, we are able to reconstruct the Kraus operators for the larger Hilbert space rather than being limited to the logical subspace. This allows for a more accurate determination of the different error mechanisms that lead to the gate infidelity.

Published

2023

15. Experimental realization of deterministic and selective photon addition in a bosonic mode assisted by an ancillary qubit

Author

Kudra, Marina, Abad, Tahereh, Kervinen, Mikael, Eriksson, Axel M., Quijandría, Fernando, Delsing, Per, and Gasparinetti, Simone

Subjects

Quantum Physics

Abstract

Bosonic quantum error correcting codes are primarily designed to protect against single-photon loss. To correct for this type of error, one can encode the logical qubit in code spaces with a definite photon parity, such as cat codes or binomial codes. Error correction requires a recovery operation that maps the error states -- which have opposite parity -- back onto the code states. Here, we realize a collection of photon-number-selective, simultaneous photon addition operations on a bosonic mode, a microwave cavity, assisted by a superconducting qubit. These operations are implemented as two-photon transitions that excite the cavity and the qubit at the same time. The additional degree of freedom of the qubit makes it possible to implement a coherent, unidirectional mapping between spaces of opposite photon parity. We present the successful experimental implementation of the drives and the phase control they enable on superpositions of Fock states. The presented technique, when supplemented with qubit reset, is suitable for autonomous quantum error correction in bosonic systems, and, more generally, opens the possibility to realize a range of non-unitary transformations on a bosonic mode.

Published

2022

16. Integration of Neuromorphic AI in Event-Driven Distributed Digitized Systems: Concepts and Research Directions

Author

Nilsson, Mattias, Schelén, Olov, Lindgren, Anders, Bodin, Ulf, Paniagua, Cristina, Delsing, Jerker, and Sandin, Fredrik

Subjects

Computer Science - Neural and Evolutionary Computing, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Emerging Technologies

Abstract

Increasing complexity and data-generation rates in cyber-physical systems and the industrial Internet of things are calling for a corresponding increase in AI capabilities at the resource-constrained edges of the Internet. Meanwhile, the resource requirements of digital computing and deep learning are growing exponentially, in an unsustainable manner. One possible way to bridge this gap is the adoption of resource-efficient brain-inspired "neuromorphic" processing and sensing devices, which use event-driven, asynchronous, dynamic neurosynaptic elements with colocated memory for distributed processing and machine learning. However, since neuromorphic systems are fundamentally different from conventional von Neumann computers and clock-driven sensor systems, several challenges are posed to large-scale adoption and integration of neuromorphic devices into the existing distributed digital-computational infrastructure. Here, we describe the current landscape of neuromorphic computing, focusing on characteristics that pose integration challenges. Based on this analysis, we propose a microservice-based framework for neuromorphic systems integration, consisting of a neuromorphic-system proxy, which provides virtualization and communication capabilities required in distributed systems of systems, in combination with a declarative programming approach offering engineering-process abstraction. We also present concepts that could serve as a basis for the realization of this framework, and identify directions for further research required to enable large-scale system integration of neuromorphic devices.

Published

2022

17. Resolving Fock states near the Kerr-free point of a superconducting resonator

Author

Lu, Yong, Kudra, Marina, Hillmann, Timo, Yang, Jiaying, Li, Hangxi, Quijandría, Fernando, and Delsing, Per

Subjects

Quantum Physics

Abstract

We have designed a tunable nonlinear resonator terminated by a SNAIL (Superconducting Nonlinear Asymmetric Inductive eLement). Such a device possesses a sweet spot in which the external magnetic flux allows to suppress the Kerr interaction. We have excited photons near this Kerr-free point and characterized the device using a transmon qubit. The excitation spectrum of the qubit allows to observe photon-number-dependent frequency shifts about nine times larger than the qubit linewidth. Our study demonstrates a compact integrated platform for continuous-variable quantum processing that combines large couplings, considerable relaxation times and excellent control over the photon mode structure in the microwave domain.

Published

2022

18. Three-wave mixing traveling-wave parametric amplifier with periodic variation of the circuit parameters

Author

Roudsari, Anita Fadavi, Shiri, Daryoush, Nilsson, Hampus Renberg, Tancredi, Giovanna, Osman, Amr, Svensson, Ida-Maria, Kudra, Marina, Rommel, Marcus, Bylander, Jonas, Shumeiko, Vitaly, and Delsing, Per

Subjects

Quantum Physics, Physics - Applied Physics

Abstract

We report the implementation of a near-quantum-limited, traveling-wave parametric amplifier that uses three-wave mixing (3WM). To favor amplification by 3WM, we use the superconducting nonlinear asymmetric inductive element (SNAIL) loops, biased with a dc magnetic flux. In addition, we equip the device with dispersion engineering features to create a stop-band at the second harmonic of the pump and suppress the propagation of the higher harmonics that otherwise degrade the amplification. With a chain of 440 SNAILs, the amplifier provides up to 20 dB gain and a 3-dB bandwidth of 1 GHz. The added noise by the amplifier is found to be less than one photon., Comment: 6 pages, 6 figures

Published

2022

19. Correlated frequency noise in a multimode acoustic resonator

Author

Tubsrinuan, Nuttamas, Cole, Jared H., Delsing, Per, and Andersson, Gustav

Subjects

Quantum Physics

Abstract

Frequency instabilities are a major source of errors in quantum devices. This study investigates frequency fluctuations in a surface acoustic wave (SAW) resonator, where reflection coefficients of 14 SAW modes are measured simultaneously for more than seven hours. We report two distinct noise characteristics. Multimode frequency noise caused by interactions with two-level system (TLS) defects shows significant degrees of correlations that diminish with increased detuning. This finding agrees with the current understanding of the parasitic TLS behavior as one of the dominant noise sources in quantum devices. In addition to the TLS-induced noise, we observe strong anomalous frequency fluctuations with slow, anti-correlated dynamics. These noise bursts resemble signatures of cosmic radiation observed in superconducting quantum systems., Comment: 11 pages, 8 figures (including supplementary information)

Published

2022

20. Transmon qubit readout fidelity at the threshold for quantum error correction without a quantum-limited amplifier

Author

Chen, Liangyu, Li, Hang-Xi, Lu, Yong, Warren, Christopher W., Križan, Christian J., Kosen, Sandoko, Rommel, Marcus, Ahmed, Shahnawaz, Osman, Amr, Biznárová, Janka, Roudsari, Anita Fadavi, Lienhard, Benjamin, Caputo, Marco, Grigoras, Kestutis, Grönberg, Leif, Govenius, Joonas, Kockum, Anton Frisk, Delsing, Per, Bylander, Jonas, and Tancredi, Giovanna

Subjects

Quantum Physics

Abstract

High-fidelity and rapid readout of a qubit state is key to quantum computing and communication, and it is a prerequisite for quantum error correction. We present a readout scheme for superconducting qubits that combines two microwave techniques: applying a shelving technique to the qubit that effectively increases the energy-relaxation time, and a two-tone excitation of the readout resonator to distinguish among qubit populations in higher energy levels. Using a machine-learning algorithm to post-process the two-tone measurement results further improves the qubit-state assignment fidelity. We perform single-shot frequency-multiplexed qubit readout, with a 140ns readout time, and demonstrate 99.5% assignment fidelity for two-state readout and 96.9% for three-state readout - without using a quantum-limited amplifier.

Published

2022

21. Extensive characterization of a family of efficient three-qubit gates at the coherence limit

Author

Warren, Christopher W., Fernández-Pendás, Jorge, Ahmed, Shahnawaz, Abad, Tahereh, Bengtsson, Andreas, Biznárová, Janka, Debnath, Kamanasish, Gu, Xiu, Križan, Christian, Osman, Amr, Roudsari, Anita Fadavi, Delsing, Per, Johansson, Göran, Kockum, Anton Frisk, Tancredi, Giovanna, and Bylander, Jonas

Subjects

Quantum Physics

Abstract

While all quantum algorithms can be expressed in terms of single-qubit and two-qubit gates, more expressive gate sets can help reduce the algorithmic depth. This is important in the presence of gate errors, especially those due to decoherence. Using superconducting qubits, we have implemented a three-qubit gate by simultaneously applying two-qubit operations, thereby realizing a three-body interaction. This method straightforwardly extends to other quantum hardware architectures, requires only a "firmware" upgrade to implement, and is faster than its constituent two-qubit gates. The three-qubit gate represents an entire family of operations, creating flexibility in quantum-circuit compilation. We demonstrate a gate fidelity of $97.90\%$, which is near the coherence limit of our device. We then generate two classes of entangled states, the GHZ and W states, by applying the new gate only once; in comparison, decompositions into the standard gate set would have a two-qubit gate depth of two and three, respectively. Finally, we combine characterization methods and analyze the experimental and statistical errors on the fidelity of the gates and of the target states., Comment: 19 pages, 10 figures

Published

2022

22. Measurement and control of a superconducting quantum processor with a fully-integrated radio-frequency system on a chip

Author

Tholén, Mats O., Borgani, Riccardo, Di Carlo, Giuseppe Ruggero, Bengtsson, Andreas, Križan, Christian, Kudra, Marina, Tancredi, Giovanna, Bylander, Jonas, Delsing, Per, Gasparinetti, Simone, and Haviland, David B.

Subjects

Quantum Physics, Physics - Instrumentation and Detectors

Abstract

We describe a digital microwave platform called Presto, designed for measurement and control of multiple quantum bits (qubits) and based on the third-generation radio-frequency system on a chip. Presto uses direct digital synthesis to create signals up to 9 GHz on 16 synchronous output ports, while synchronously analyzing response on 16 input ports. Presto has 16 DC-bias outputs, 4 inputs and 4 outputs for digital triggers or markers, and two continuous-wave outputs for synthesizing frequencies up to 15 GHz. Scaling to a large number of qubits is enabled through deterministic synchronization of multiple Presto units. A Python application programming interface configures a firmware for synthesis and analysis of pulses, coordinated by an event sequencer. The analysis integrates template matching (matched filtering) and low-latency (184 - 254 ns) feedback to enable a wide range of multi-qubit experiments. We demonstrate Presto's capabilities with experiments on a sample consisting of two superconducting qubits connected via a flux-tunable coupler. We show single-shot readout and active reset of a single qubit; randomized benchmarking of single-qubit gates showing 99.972% fidelity, limited by the coherence time of the qubit; and calibration of a two-qubit iSWAP gate., Comment: v3: peer reviewed, accepted manuscript; v2: correct theoretical gate fidelity in Sec. III C

Published

2022

23. A high gain travelling-wave parametric amplifier based on three-wave mixing

Author

Nilsson, Hampus Renberg, Roudsari, Anita Fadavi, Shiri, Daryoush, Delsing, Per, and Shumeiko, Vitaly

Subjects

Quantum Physics

Abstract

We extend the theory for a Josephson junction travelling wave parametric amplifier (TWPA) operating in the three-wave mixing regime and we propose a scheme for achieving high gain. The continuous three-mode model [P. K. Tien, J. Appl. Phys. 29, 1347 (1958)] is on one hand extended to describe a discrete chain of Josephson junctions at high frequencies close to the spectral cutoff where there is no up-conversion. On the other hand, we also develop a continuous multimode theory for the low-frequency region where the frequency dispersion is close to linear. We find that in both cases the gain is significantly reduced compared to the prediction by the continuous three-mode model as the result of increasingly strong dispersion at the high frequencies and generation of up-converted modes at the low frequencies. The developed theory is in quantitative agreement with experimental observations. To recover the high gain, we propose to engineer a chain with dispersive features to form a two-band frequency spectrum and to place the pump frequency within the upper band close to the spectral cutoff. We prove that there exists a sweet spot, where the signal and the pump are phase matched, while the up-conversion is inhibited. This results in a high gain which grows exponentially with the length of the TWPA.

Published

2022

24. Robust preparation of Wigner-negative states with optimized SNAP-displacement sequences

Author

Kudra, Marina, Kervinen, Mikael, Strandberg, Ingrid, Ahmed, Shahnawaz, Scigliuzzo, Marco, Osman, Amr, Lozano, Daniel Pérez, Tholén, Mats O., Borgani, Riccardo, Haviland, David B., Ferrini, Giulia, Bylander, Jonas, Kockum, Anton Frisk, Quijandría, Fernando, Delsing, Per, and Gasparinetti, Simone

Subjects

Quantum Physics

Abstract

Hosting non-classical states of light in three-dimensional microwave cavities has emerged as a promising paradigm for continuous-variable quantum information processing. Here we experimentally demonstrate high-fidelity generation of a range of Wigner-negative states useful for quantum computation, such as Schr\"{o}dinger-cat states, binomial states, Gottesman-Kitaev-Preskill (GKP) states, as well as cubic phase states. The latter states have been long sought after in quantum optics and were never achieved experimentally before. To do so, we use a sequence of interleaved selective number-dependent arbitrary phase (SNAP) gates and displacements. We optimize the state preparation in two steps. First we use a gradient-descent algorithm to optimize the parameters of the SNAP and displacement gates. Then we optimize the envelope of the pulses implementing the SNAP gates. Our results show that this way of creating highly non-classical states in a harmonic oscillator is robust to fluctuations of the system parameters such as the qubit frequency and the dispersive shift.

Published

2021

25. Nonequilibrium heat transport and work with a single artificial atom coupled to a waveguide: emission without external driving

Author

Lu, Yong, Lambert, Neill, Kockum, Anton Frisk, Funo, Ken, Bengtsson, Andreas, Gasparinetti, Simone, Nori, Franco, and Delsing, Per

Subjects

Quantum Physics

Abstract

We observe the continuous emission of photons into a waveguide from a superconducting qubit without the application of an external drive. To explain this observation, we build a two-bath model where the qubit couples simultaneously to a cold bath (the waveguide) and a hot bath (a secondary environment). Our results show that the thermal-photon occupation of the hot bath is up to 0.14 photons, 35 times larger than the cold waveguide, leading to nonequilibrium heat transport with a power of up to 132 zW, as estimated from the qubit emission spectrum. By adding more isolation between the sample output and the first cold amplifier in the output line, the heat transport is strongly suppressed. Our interpretation is that the hot bath may arise from active two-level systems being excited by noise from the output line. We also apply a coherent drive, and use the waveguide to measure thermodynamic work and heat, suggesting waveguide spectroscopy is a useful means to study quantum heat engines and refrigerators. Finally, based on the theoretical model, we propose how a similar setup can be used as a noise spectrometer which provides a new solution for calibrating the background noise of hybrid quantum systems.

Published

2021

26. Extensible quantum simulation architecture based on atom-photon bound states in an array of high-impedance resonators

Author

Scigliuzzo, Marco, Calajò, Giuseppe, Ciccarello, Francesco, Lozano, Daniel Perez, Bengtsson, Andreas, Scarlino, Pasquale, Wallraff, Andreas, Chang, Darrick, Delsing, Per, and Gasparinetti, Simone

Subjects

Quantum Physics

Abstract

Engineering the electromagnetic environment of a quantum emitter gives rise to a plethora of exotic light-matter interactions. In particular, photonic lattices can seed long-lived atom-photon bound states inside photonic band gaps. Here we report on the concept and implementation of a novel microwave architecture consisting of an array of compact, high-impedance superconducting resonators forming a 1 GHz-wide pass band, in which we have embedded two frequency-tuneable artificial atoms. We study the atom-field interaction and access previously unexplored coupling regimes, in both the single- and double-excitation subspace. In addition, we demonstrate coherent interactions between two atom-photon bound states, in both resonant and dispersive regimes, that are suitable for the implementation of SWAP and CZ two-qubit gates. The presented architecture holds promise for quantum simulation with tuneable-range interactions and photon transport experiments in nonlinear regime.

Published

2021

27. Quantum efficiency, purity and stability of a tunable, narrowband microwave single-photon source

Author

Lu, Yong, Bengtsson, Andreas, Burnett, Jonathan J., Suri, Baladitya, Sathyamoorthy, Sankar Raman, Nilsson, Hampus Renberg, Scigliuzzo, Marco, Bylander, Jonas, Johansson, Göran, and Delsing, Per

Subjects

Quantum Physics

Abstract

We demonstrate an on-demand source of microwave single photons with 71--99\% intrinsic quantum efficiency. The source is narrowband (300\unite{kHz}) and tuneable over a 600 MHz range around 5.2 GHz. Such a device is an important element in numerous quantum technologies and applications. The device consists of a superconducting transmon qubit coupled to the open end of a transmission line. A $\pi$-pulse excites the qubit, which subsequently rapidly emits a single photon into the transmission line. A cancellation pulse then suppresses the reflected $\pi$-pulse by 33.5 dB, resulting in 0.005 photons leaking into the photon emission channel. We verify strong antibunching of the emitted photon field and determine its Wigner function. Non-radiative decay and $1/f$ flux noise both affect the quantum efficiency. We also study the device stability over time and identify uncorrelated discrete jumps of the pure dephasing rate at different qubit frequencies on a time scale of hours, which we attribute to independent two-level system defects in the device dielectrics, dispersively coupled to the qubit.

Published

2021

28. On Capital Allocation for a Risk Measure Derived from Ruin Theory

Author

Delsing, Guusje, Mandjes, Michel, Spreij, Peter, and Winands, Erik

Subjects

Quantitative Finance - Mathematical Finance

Abstract

This paper addresses allocation methodologies for a risk measure inherited from ruin theory. Specifically, we consider a dynamic value-at-risk (VaR) measure defined as the smallest initial capital needed to ensure that the ultimate ruin probability is less than a given threshold. We introduce an intuitively appealing, novel allocation method, with a focus on its application to capital reserves which are determined through the dynamic value-at-risk (VaR) measure. Various desirable properties of the presented approach are derived including a limit result when considering a large time horizon and the comparison with the frequently used gradient allocation method. In passing, we introduce a second allocation method and discuss its relation to the other allocation approaches. A number of examples illustrate the applicability and performance of the allocation approaches.

Published

2021

29. Behavioral Classroom Norms in Special Education: Associations with Peer Acceptance and Rejection

Author

de Swart, Fanny, Scholte, Ron H. J., Delsing, Marc J. M. H., van Efferen, Esther, der Stege, Heleen van, Nelen, Wendy, and Burk, William J.

Abstract

This study investigated the role of behavioral norms on concurrent links between problem behaviors (externalizing problems, internalizing problems, attention-hyperactivity problems) and social status (acceptance, rejection) in special education classrooms at four time points within and across school years. Two opposing models were considered, the "person-group similarity model," suggesting moderation of behavioral norms, and the "social skill model," suggesting no moderation. The sample included a total of 580 pupils (88% boys, M[subscript age Time1] = 10.82 years, SD = 0.86) attending 37 classrooms from 13 Dutch schools for special education. Multilevel analyses revealed that the data generally supported a "social skill model," meaning that higher individual levels of attention-hyperactivity problems and externalizing problems were related to lower acceptance and higher rejection, independent of behavioral norms. Support for behavioral norms as moderators of the link between individual behaviors and social status was limited to pupils with attention-hyperactivity problems being less rejected in classrooms in which this behavior was normative. In sum, these results provide an initial exploration of the role of behavioral norms in special education. Various explanations for the results, including special education characteristics and the value of behavioral norms, are discussed.

Published

2022

30. Propagating Wigner-Negative States Generated from the Steady-State Emission of a Superconducting Qubit

Author

Lu, Yong, Strandberg, Ingrid, Quijandría, Fernando, Johansson, Göran, Gasparinetti, Simone, and Delsing, Per

Subjects

Quantum Physics

Abstract

We experimentally demonstrate the steady-state generation of propagating Wigner-negative states from a continuously driven superconducting qubit. We reconstruct the Wigner function of the radiation emitted into propagating modes defined by their temporal envelopes, using digital filtering. For an optimized temporal filter, we observe a large Wigner logarithmic negativity, in excess of 0.08, in agreement with theory. The fidelity between the theoretical predictions and the states generated experimentally is up to 99%, reaching state-of-the-art realizations in the microwave frequency domain. Our results provide a new way to generate and control nonclassical states, and may enable promising applications such as quantum networks and quantum computation based on waveguide quantum electrodynamics., Comment: 15

Published

2021

31. Deterministic loading and phase shaping of microwaves onto a single artificial atom

Author

Lin, W. -J., Lu, Y., Wen, P. Y., Cheng, Y. -T., Lee, C. -P., Lin, K. -T., Chiang, K. -H., Hsieh, M. C., Chen, J. C., Chuu, C. -S., Nori, F., Kockum, A. F., Lin, G. -D., Delsing, P., and Hoi, I. -C.

Subjects

Quantum Physics

Abstract

Loading quantum information deterministically onto a quantum node is an important step towards a quantum network. Here, we demonstrate that coherent-state microwave photons, with an optimal temporal waveform, can be efficiently loaded onto a single superconducting artificial atom in a semi-infinite one-dimensional (1D) transmission-line waveguide. Using a weak coherent state (average photon number N<<1 with an exponentially rising waveform, whose time constant matches the decoherence time of the artificial atom, we demonstrate a loading efficiency of above 94% from 1D semi-free space to the artificial atom. We also show that Fock-state microwave photons can be deterministically loaded with an efficiency of 98.5%. We further manipulate the phase of the coherent state exciting the atom, enabling coherent control of the loading process. Our results open up promising applications in realizing quantum networks based on waveguide quantum electrodynamics (QED).

Published

2020

32. Ultimate quantum limit for amplification: a single atom in front of a mirror

Author

Wiegand, Emely, Wen, Ping-Yi, Delsing, Per, Hoi, Io-Chun, and Kockum, Anton Frisk

Subjects

Quantum Physics

Abstract

We investigate three types of amplification processes for light fields coupling to an atom near the end of a one-dimensional semi-infinite waveguide. We consider two setups where a drive creates population inversion in the bare or dressed basis of a three-level atom and one setup where the amplification is due to higher-order processes in a driven two-level atom. In all cases, the end of the waveguide acts as a mirror for the light. We find that this enhances the amplification in two ways compared to the same setups in an open waveguide. Firstly, the mirror forces all output from the atom to travel in one direction instead of being split up into two output channels. Secondly, interference due to the mirror enables tuning of the ratio of relaxation rates for different transitions in the atom to increase population inversion. We quantify the enhancement in amplification due to these factors and show that it can be demonstrated for standard parameters in experiments with superconducting quantum circuits.

Published

2020

33. Squeezing and multimode entanglement of surface acoustic wave phonons

Author

Andersson, Gustav, Jolin, Shan W., Scigliuzzo, Marco, Borgani, Riccardo, Tholén, Mats O., Hernández, J. C. Rivera, Shumeiko, Vitaly, Haviland, David B., and Delsing, Per

Subjects

Quantum Physics

Abstract

Exploiting multiple modes in a quantum acoustic device could enable applications in quantum information in a hardware-efficient setup, including quantum simulation in a synthetic dimension and continuous-variable quantum computing with cluster states.We develop a multimode surface acoustic wave (SAW) resonator with a superconducting quantum interference device (SQUID) integrated in one of the Bragg reflectors. The interaction with the SQUID-shunted mirror gives rise to coupling between the more than 20 accessible resonator modes. We exploit this coupling to demonstrate two-mode squeezing of SAW phonons, as well as four-mode multipartite entanglement. Our results open avenues for continuous-variable quantum computing in a compact hybrid quantum system.

Published

2020

34. High Quality 3-Dimensional Aluminum Microwave Cavities

Author

Kudra, M., Biznárová, J., Roudsari, F., Burnett, J. J., Niepce, D., Gasparinetti, S., Wickman, B., and Delsing, P.

Subjects

Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We present a comprehensive study of internal quality factors in superconducting stub-geometry 3-dimensional cavities made of aluminum. We use wet etching, annealing and electrochemichal polishing to improve the as machined quality factor. We find that the dominant loss channel is split between two-level system loss and an unknown source with 60:40 proportion. A total of 17 cavities of different purity, resonance frequency and size were studied. Our treatment results in reproducible cavities, with ten of them showing internal quality factors above 80 million at a power corresponding to an average of a single photon in the cavity. The best cavity has an internal quality factor of 115 million at single photon level.

Published

2020

35. A transient Cram\'er-Lundberg model with applications to credit risk

Author

Delsing, Guusje and Mandjes, Michel

Subjects

Mathematics - Probability, 60G51

Abstract

This paper considers a variant of the classical Cram\'er-Lundberg model that is particularly appropriate in the credit context, with the distinguishing feature that it corresponds to a finite number of obligors. The focus is on computing the ruin probability, i.e., the probability that the initial reserve, increased by the interest received from the obligors and decreased by the losses due to defaults, drops below zero. Besides an exact analysis (in terms of transforms) of this ruin probability, also an asymptotic analysis is performed, including an efficient importance-sampling based simulation approach. The base model is extended in multiple dimensions: (i) we consider a model in which there may, in addition, be losses that do not correspond to defaults, (ii) then we analyze a model in which the individual obligors are coupled through a regime-switching mechanism, (iii) then we extend the model such that between the losses the reserve process behaves as a Brownian motion rather than a deterministic drift, and (iv) we finally consider a set-up with multiple groups of statistically identical obligors.

Published

2020

36. Primary thermometry of propagating microwaves in the quantum regime

Author

Scigliuzzo, Marco, Bengtsson, Andreas, Besse, Jean-Claude, Wallraff, Andreas, Delsing, Per, and Gasparinetti, Simone

Subjects

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

Abstract

The ability to control and measure the temperature of propagating microwave modes down to very low temperatures is indispensable for quantum information processing, and may open opportunities for studies of heat transport at the nanoscale, also in the quantum regime. Here we propose and experimentally demonstrate primary thermometry of propagating microwaves using a transmon-type superconducting circuit. Our device operates continuously, with a sensitivity down to $4\times 10^{-4}$ photons/$\sqrt{\mbox{Hz}}$ and a bandwidth of 40 MHz. We measure the thermal occupation of the modes of a highly attenuated coaxial cable in a range of 0.001 to 0.4 thermal photons, corresponding to a temperature range from 35 mK to 210 mK at a frequency around 5 GHz. To increase the radiation temperature in a controlled fashion, we either inject calibrated, wideband digital noise, or heat the device and its environment. This thermometry scheme can find applications in benchmarking and characterization of cryogenic microwave setups, temperature measurements in hybrid quantum systems, and quantum thermodynamics.

Published

2020

37. Acoustic spectral hole-burning in a two-level system ensemble

Author

Andersson, Gustav, Bilobran, André Luiz Oliveira, Scigliuzzo, Marco, de Lima, Mauricio M., Cole, Jared H., and Delsing, Per

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Microscopic two-level system (TLS) defects at dielectric surfaces and interfaces are among the dominant sources of loss in superconducting quantum circuits, and their properties have been extensively probed using superconducting resonators and qubits. We report on spectroscopy of TLSs coupling to the strain field in a surface acoustic wave (SAW) resonator. The narrow free spectral range of the resonator allows for two-tone spectroscopy where a strong pump is applied at one resonance while a weak signal is used to probe a different mode. We map the spectral hole burnt by the pump tone as a function of frequency and extract parameters of the TLS ensemble. Our results suggest that detuned acoustic pumping can be used to enhance the coherence of superconducting devices by saturating TLSs.

Published

2020

38. Resolving Fock states near the Kerr-free point of a superconducting resonator

Author

Lu, Yong, Kudra, Marina, Hillmann, Timo, Yang, Jiaying, Li, Hang-Xi, Quijandría, Fernando, and Delsing, Per

Published

2023

39. Fast generation of Schrödinger cat states using a Kerr-tunable superconducting resonator

Author

He, X. L., Lu, Yong, Bao, D. Q., Xue, Hang, Jiang, W. B., Wang, Z., Roudsari, A. F., Delsing, Per, Tsai, J. S., and Lin, Z. R.

Published

2023

40. Extensive characterization and implementation of a family of three-qubit gates at the coherence limit

Author

Warren, Christopher W., Fernández-Pendás, Jorge, Ahmed, Shahnawaz, Abad, Tahereh, Bengtsson, Andreas, Biznárová, Janka, Debnath, Kamanasish, Gu, Xiu, Križan, Christian, Osman, Amr, Fadavi Roudsari, Anita, Delsing, Per, Johansson, Göran, Frisk Kockum, Anton, Tancredi, Giovanna, and Bylander, Jonas

Published

2023

41. Transmon qubit readout fidelity at the threshold for quantum error correction without a quantum-limited amplifier

Author

Chen, Liangyu, Li, Hang-Xi, Lu, Yong, Warren, Christopher W., Križan, Christian J., Kosen, Sandoko, Rommel, Marcus, Ahmed, Shahnawaz, Osman, Amr, Biznárová, Janka, Fadavi Roudsari, Anita, Lienhard, Benjamin, Caputo, Marco, Grigoras, Kestutis, Grönberg, Leif, Govenius, Joonas, Kockum, Anton Frisk, Delsing, Per, Bylander, Jonas, and Tancredi, Giovanna

Published

2023

42. Author Correction: Transmon qubit readout fidelity at the threshold for quantum error correction without a quantum-limited amplifier

Author

Chen, Liangyu, Li, Hang-Xi, Lu, Yong, Warren, Christopher W., Križan, Christian J., Kosen, Sandoko, Rommel, Marcus, Ahmed, Shahnawaz, Osman, Amr, Biznárová, Janka, Fadavi Roudsari, Anita, Lienhard, Benjamin, Caputo, Marco, Grigoras, Kestutis, Grönberg, Leif, Govenius, Joonas, Kockum, Anton Frisk, Delsing, Per, Bylander, Jonas, and Tancredi, Giovanna

Published

2023

43. Alliance between Therapist and Multi-Stressed Families during the COVID-19 Pandemic: The Effect of Family-Based Videoconferencing

Author

Lange, Aurelie M. C., Delsing, Marc J. M. H., van Geffen, Marieke, and Scholte, Ron. H. J.

Abstract

Background: A strong therapeutic alliance or working relationship is essential for effective face-to-face family-based psychotherapy. However, little is known about the use of VC on alliance in family-based therapy. The recent COVID-19 pandemic led to a national lockdown during which most family-based therapy transferred to VC. Objective: The current study analyzed the development and strength of alliance prior and during lockdown for multi-stressed families participating in Multisystemic Therapy (MST). Method: Alliance with the therapist was reported monthly by 846 caregivers (81% female). Using latent growth curve models (longitudinal approach), the development of alliance was estimated for families participating in MST prior to the lockdown, transferring to VC early in treatment or late in treatment. Using regression analyses (cross-sectional approach), lockdown (yes/no) was included as predictor of alliance. In these analyses, type of family (regular; intellectual disability; concerns regarding child abuse or neglect) and gender of caregiver were included as moderators. Results: Both analytical approaches showed that alliance was not affected by VC, except for families with concerns of child abuse, who reported lower alliances during lockdown. However, these results where no longer significant when controlling for multiple testing. Conclusions: Strong alliances can be developed and maintained during family-based VC sessions with multi-stressed families. However, for some subgroups, such as families with concerns of child abuse, VC might not be suitable or sufficient. Future research needs to investigate the potential and limitations of using VC with families.

Published

2022

44. Improved success probability with greater circuit depth for the quantum approximate optimization algorithm

Author

Bengtsson, Andreas, Vikstål, Pontus, Warren, Christopher, Svensson, Marika, Gu, Xiu, Kockum, Anton Frisk, Krantz, Philip, Križan, Christian, Shiri, Daryoush, Svensson, Ida-Maria, Tancredi, Giovanna, Johansson, Göran, Delsing, Per, Ferrini, Giulia, and Bylander, Jonas

Subjects

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

Abstract

Present-day, noisy, small or intermediate-scale quantum processors---although far from fault-tolerant---support the execution of heuristic quantum algorithms, which might enable a quantum advantage, for example, when applied to combinatorial optimization problems. On small-scale quantum processors, validations of such algorithms serve as important technology demonstrators. We implement the quantum approximate optimization algorithm (QAOA) on our hardware platform, consisting of two superconducting transmon qubits and one parametrically modulated coupler. We solve small instances of the NP-complete exact-cover problem, with 96.6% success probability, by iterating the algorithm up to level two., Comment: 9 pages, 7 figures

Published

2019

45. Phononic loss in superconducting resonators on piezoelectric substrates

Author

Scigliuzzo, Marco, Bruhat, Laure E., Bengtsson, Andreas, Burnett, Jonathan J., Roudsari, Anita Fadavi, and Delsing, Per

Subjects

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

Abstract

We numerically and experimentally investigate the phononic loss for superconducting resonators fabricated on a piezoelectric substrate. With the help of finite element method simulations, we calculate the energy loss due to electromechanical conversion into bulk and surface acoustic waves. This sets an upper limit for the resonator internal quality factor $Q_i$. To validate the simulation, we fabricate quarter wavelength coplanar waveguide resonators on GaAs and measure $Q_i$ as function of frequency, power and temperature. We observe a linear increase of $Q_i$ with frequency, as predicted by the simulations for a constant electromechanical coupling. Additionally, $Q_i$ shows a weak power dependence and a negligible temperature dependence around 10$\,$mK, excluding two level systems and non-equilibrium quasiparticles as the main source of losses at that temperature.

Published

2019

46. Characterizing decoherence rates of a superconducting qubit by direct microwave scattering

Author

Lu, Yong, Bengtsson, Andreas, Burnett, Jonathan J., Wiegand, Emely, Suri, Baladitya, Krantz, Philip, Roudsari, Anita Fadavi, Kockum, Anton Frisk, Gasparinetti, Simone, Johansson, Göran, and Delsing, Per

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We experimentally investigate a superconducting qubit coupled to the end of an open transmission line, in a regime where the qubit decay rates to the transmission line and to its own environment are comparable. We perform measurements of coherent and incoherent scattering, on- and off-resonant fluorescence, and time-resolved dynamics to determine the decay and decoherence rates of the qubit. In particular, these measurements let us discriminate between non-radiative decay and pure dephasing. We combine and contrast results across all methods and find consistent values for the extracted rates. The results show that the pure dephasing rate is one order of magnitude smaller than the non-radiative decay rate for our qubit. Our results indicate a pathway to benchmark decoherence rates of superconducting qubits in a resonator-free setting., Comment: 13 pages, 6 figures

Published

2019

47. Electromagnetically induced acoustic transparency with a superconducting circuit

Author

Andersson, Gustav, Ekström, Maria K., and Delsing, Per

Subjects

Quantum Physics

Abstract

We report the observation of Electromagnetically Induced Transparency (EIT) of a mechanical field, where a superconducting artificial atom is coupled to a 1D-transmission line for surface acoustic waves. An electromagnetic microwave drive is used as the control field, rendering the superconducting transmon qubit transparent to the acoustic probe beam. The strong frequency dependence of the acoustic coupling enables EIT in a ladder configuration due to the suppressed relaxation of the upper level. Our results show that superconducting circuits can be engineered to interact with acoustic fields in parameter regimes not readily accessible to purely electromagnetic systems.

Published

2019

48. Towards phonon routing: Controlling propagating acoustic waves in the quantum regime

Author

Ekström, M K, Aref, T, Ask, A, Andersson, G, Suri, B, Sanada, H, Johansson, G, and Delsing, P

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We explore routing of propagating phonons in analogy with previous experiments on photons. Surface acoustic waves (SAWs) in the microwave regime are scattered by a superconducting transmon qubit. The transmon can be tuned on or off resonance with the incident SAW field using an external magnetic field or the Autler-Townes effect, and thus the reflection and transmission of the SAW field can be controlled in time. We observe 80% extinction in the transmission of the low power continuous signal and a 40 ns rise time of the router. The slow propagation speed of SAWs on solid surfaces allows for in-flight manipulations of the propagating phonons. The ability to route short, 100 ns, pulses enables new functionality, for instance to catch an acoustic phonon between two qubits and then release it in a controlled direction., Comment: 10 pages, 11 figures put into 4 figures, 1 table

Published

2019

49. A ruin model with a resampled environment

Author

Constantinescu, Corina, Delsing, Guusje, Mandjes, Michel, and Nandayapa, Leonardo Rojas

Subjects

Mathematics - Probability

Abstract

This paper considers a Cram\'er-Lundberg risk setting, where the components of the underlying model change over time. These components could be thought of as the claim arrival rate, the claim-size distribution, and the premium rate, but we allow the more general setting of the cumulative claim process being modelled as a spectrally positive L\'evy process. We provide an intuitively appealing mechanism to create such parameter uncertainty: at Poisson epochs we resample the model components from a finite number of $d$ settings. It results in a setup that is particularly suited to describe situations in which the risk reserve dynamics are affected by external processes (such as the state of the economy, political developments, weather or climate conditions, and policy regulations). We extend the classical Cram\'er-Lundberg approximation (asymptotically characterizing the all-time ruin probability in a light-tailed setting) to this more general setup. In addition, for the situation that the driving L\'evy processes are sums of Brownian motions and compound Poisson processes, we find an explicit uniform bound on the ruin probability, which can be viewed as an extension of Lundberg's inequality; importantly, here it is not required that the L\'evy processes be spectrally one-sided. In passing we propose an importance-sampling algorithm facilitating efficient estimation, and prove it has bounded relative error. In a series of numerical experiments we assess the accuracy of the asymptotics and bounds, and illustrate that neglecting the resampling can lead to substantial underestimation of the risk.

Published

2019

50. Large collective Lamb shift of two distant superconducting artificial atoms

Author

Wen, P. Y., Lin, K. -T., Kockum, A. F., Suri, B., Ian, H., Chen, J. C., Mao, S. Y., Chiu, C. C., Delsing, P., Nori, F., Lin, G. -D., and Hoi, I. -C.

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Virtual photons can mediate interaction between atoms, resulting in an energy shift known as a collective Lamb shift. Observing the collective Lamb shift is challenging, since it can be obscured by radiative decay and direct atom-atom interactions. Here, we place two superconducting qubits in a transmission line terminated by a mirror, which suppresses decay. We measure a collective Lamb shift reaching 0.8% of the qubit transition frequency and exceeding the transition linewidth. We also show that the qubits can interact via the transmission line even if one of them does not decay into it., Comment: 7+5 pages, 4+2 figures

Published

2019