Reconfigurable Josephson Circulator/Directional Amplifier

Circulators and directional amplifiers are crucial non-reciprocal signal routing and processing components involved in microwave readout chains for a variety of applications. They are particularly important in the field of superconducting quantum information, where the devices also need to have minimal photon losses to preserve the quantum coherence of signals. Conventional commercial implementations of each device suffer from losses and are built from very different physical principles, which has led to separate strategies for the construction of their quantum-limited versions. However, as recently proposed theoretically, by establishing simultaneous pairwise conversion and/or gain processes between three modes of a Josephson-junction based superconducting microwave circuit, it is possible to endow the circuit with the functions of either a phase-preserving directional amplifier or a circulator. Here, we experimentally demonstrate these two modes of operation of the same circuit. Furthermore, in the directional amplifier mode, we show that the noise performance is comparable to standard non-directional superconducting amplifiers, while in the circulator mode, we show that the sense of circulation is fully reversible. Our device is far simpler in both modes of operation than previous proposals and implementations, requiring only three microwave pumps. It offers the advantage of flexibility, as it can dynamically switch between modes of operation as its pump conditions are changed. Moreover, by demonstrating that a single three-wave process yields non-reciprocal devices with reconfigurable functions, our work breaks the ground for the development of future, more-complex directional circuits, and has excellent prospects for on-chip integration.

[1]  C. Macklin,et al.  Observing single quantum trajectories of a superconducting quantum bit , 2013, Nature.

[2]  Steven M. Girvin,et al.  Circuit QED: Superconducting Qubits Coupled to Microwave Photons , 2015 .

[3]  A. Metelmann,et al.  Nonreciprocal Photon Transmission and Amplification via Reservoir Engineering , 2015, 1502.07274.

[4]  M. Devoret,et al.  Widely tunable, nondegenerate three-wave mixing microwave device operating near the quantum limit. , 2012, Physical review letters.

[5]  M. Devoret,et al.  Generating entangled microwave radiation over two transmission lines. , 2012, Physical review letters.

[6]  Andrea Alù,et al.  Magnetic-free non-reciprocity and isolation based on parametrically modulated coupled-resonator loops , 2014, Nature Physics.

[7]  H. Leduc,et al.  A wideband, low-noise superconducting amplifier with high dynamic range , 2012, Nature Physics.

[8]  Michel Devoret,et al.  Superconducting quantum bits , 2005 .

[9]  R. Schoelkopf,et al.  Superconducting Circuits for Quantum Information: An Outlook , 2013, Science.

[10]  L. Frunzio,et al.  Josephson directional amplifier for quantum measurement of superconducting circuits. , 2013, Physical review letters.

[11]  Baleegh Abdo,et al.  Nondegenerate three-wave mixing with the Josephson ring modulator , 2012, 1208.3142.

[12]  Shanhui Fan,et al.  Near complete violation of detailed balance in thermal radiation , 2015, 2015 Conference on Lasers and Electro-Optics (CLEO).

[13]  K. B. Whaley,et al.  Supplementary Information for " Observation of measurement-induced entanglement and quantum trajectories of remote superconducting qubits " , 2014 .

[14]  Luigi Frunzio,et al.  Full coherent frequency conversion between two propagating microwave modes. , 2012, Physical review letters.

[15]  R. Kaul,et al.  Microwave engineering , 1989, IEEE Potentials.

[16]  Alexandre Blais,et al.  On-chip superconducting microwave circulator from synthetic rotation , 2015, 1502.06041.

[17]  A. Clerk,et al.  Quantum-limited amplification via reservoir engineering. , 2013, Physical review letters.

[18]  Xiang Zhang,et al.  Resonant phase matching of Josephson junction traveling wave parametric amplifiers , 2015, 2015 Conference on Lasers and Electro-Optics (CLEO).

[19]  I. V. Inlek,et al.  Modular entanglement of atomic qubits using photons and phonons , 2014, Nature Physics.

[20]  Mazyar Mirrahimi,et al.  Persistent control of a superconducting qubit by stroboscopic measurement feedback , 2012, 1301.6095.

[21]  R. J. Schoelkopf,et al.  Phase-preserving amplification near the quantum limit with a Josephson ring modulator , 2009, Nature.

[22]  J. Clarke,et al.  Dispersive magnetometry with a quantum limited SQUID parametric amplifier , 2010, 1003.2466.

[23]  W. C. Snyder,et al.  Thermodynamic Constraints on Reflectance Reciprocity and Kirchhoff's Law. , 1998, Applied optics.

[24]  R. J. Schoelkopf,et al.  Analog information processing at the quantum limit with a Josephson ring modulator , 2008, 0805.3452.

[25]  Jens Koch,et al.  Time-reversal-symmetry breaking in circuit-QED-based photon lattices , 2010, 1006.0762.

[26]  J. Teufel,et al.  Sideband cooling of micromechanical motion to the quantum ground state , 2011, Nature.

[27]  Michael Vissers,et al.  Development of a Broadband NbTiN Traveling Wave Parametric Amplifier for MKID Readout , 2014 .

[28]  Leonardo Ranzani,et al.  Graph-based analysis of nonreciprocity in coupled-mode systems , 2014, 1406.4922.

[29]  H. Leduc,et al.  A broadband superconducting detector suitable for use in large arrays , 2003, Nature.

[30]  R. J. Schoelkopf,et al.  Quantum Back-Action of an Individual Variable-Strength Measurement , 2013, Science.

[31]  R. Barends,et al.  Traveling wave parametric amplifier with Josephson junctions using minimal resonator phase matching , 2015, 1503.04364.

[32]  John Clarke,et al.  Noiseless non-reciprocity in a parametric active device , 2010, 1010.1794.