Cavity-driven Rabi oscillations between Rydberg states of atoms trapped on a superconducting atom chip
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D. Koelle | D. Petrosyan | R. Kleiner | J. Grimmel | A. Günther | H. Hattermann | J. Fort'agh | M. Kaiser | D. Bothner | C. Glaser | L. Ley
[1] A. Clerk,et al. Hybrid quantum systems with circuit quantum electrodynamics , 2020 .
[2] S. Hogan,et al. Coupling Rydberg Atoms to Microwave Fields in a Superconducting Coplanar Waveguide Resonator. , 2019, Physical review letters.
[3] M. Saffman,et al. Microwave to optical conversion with atoms on a superconducting chip , 2019, New Journal of Physics.
[4] M. Saffman,et al. Microwave-to-optical conversion via four-wave mixing in a cold ytterbium ensemble , 2019, Physical Review A.
[5] N. J. Druten,et al. From coherent collective excitation to Rydberg blockade on an atom chip , 2018, Physical Review A.
[6] D. Petrosyan,et al. Faithful state transfer between two-level systems via an actively cooled finite-temperature cavity , 2018, 1801.06362.
[7] D. Koelle,et al. Coupling ultracold atoms to a superconducting coplanar waveguide resonator , 2017, Nature Communications.
[8] Bryan T. Gard,et al. Microwave-to-optical frequency conversion using a cesium atom coupled to a superconducting resonator , 2017, 1705.05700.
[9] Zhimin Liu,et al. Quantum Control via a Genetic Algorithm of the Field Ionization Pathway of a Rydberg Electron , 2017, 1704.01455.
[10] M. Stecker,et al. Ionization spectra of highly Stark-shifted rubidium Rydberg states , 2017, 1703.01258.
[11] J. Shaffer. Electric field cancellation on quartz by Rb adsorbate-induced negative electron affinity , 2016 .
[12] D. Petrosyan,et al. Long-range quantum gate via Rydberg states of atoms in a thermal microwave cavity , 2015, 1509.03444.
[13] J. Grimmel,et al. All-optical measurement of Rydberg-state lifetimes , 2015, 1507.02427.
[14] F. Jessen,et al. Measurement and numerical calculation of Rubidium Rydberg Stark spectra , 2015, 1503.08953.
[15] G. Kurizki,et al. Quantum technologies with hybrid systems , 2015, Proceedings of the National Academy of Sciences.
[16] S. Gleyzes,et al. Long coherence times for Rydberg qubits on a superconducting atom chip , 2014 .
[17] R. Dumke,et al. Adsorbate electric fields on a cryogenic atom chip. , 2013, Physical review letters.
[18] M. Saffman,et al. Hybrid atom-photon quantum gate in a superconducting microwave resonator , 2013, 1310.3910.
[19] W. Munro,et al. Towards realizing a quantum memory for a superconducting qubit: storage and retrieval of quantum states. , 2013, Physical review letters.
[20] D. Koelle,et al. Inductively coupled superconducting half wavelength resonators as persistent current traps for ultracold atoms , 2013, 1305.4249.
[21] Serge Haroche,et al. Controlling photons in a box and exploring the quantum to classical boundary , 2013, Angewandte Chemie.
[22] R. Schoelkopf,et al. Superconducting Circuits for Quantum Information: An Outlook , 2013, Science.
[23] D. Koelle,et al. Manipulation and coherence of ultra-cold atoms on a superconducting atom chip , 2013, Nature Communications.
[24] F. Jessen,et al. Detrimental adsorbate fields in experiments with cold Rydberg gases near surfaces , 2012, 1208.0680.
[25] F. Nori,et al. Hybrid quantum circuits: Superconducting circuits interacting with other quantum systems , 2012, 1204.2137.
[26] E. Lucero,et al. Planar Superconducting Resonators with Internal Quality Factors above One Million , 2012, 1201.3384.
[27] T. Umeda,et al. Hybrid quantum circuit with a superconducting qubit coupled to a spin ensemble. , 2011, Physical review letters.
[28] Kae Nemoto,et al. Coherent coupling of a superconducting flux qubit to an electron spin ensemble in diamond , 2011, Nature.
[29] S. Filipp,et al. Driving Rydberg-Rydberg transitions from a coplanar microwave waveguide. , 2011, Physical review letters.
[30] R. Spreeuw,et al. Spatially resolved excitation of Rydberg atoms and surface effects on an atom chip , 2010, 1004.3230.
[31] B. Sanders,et al. Optical quantum memory , 2009, 1002.4659.
[32] C. Zimmermann,et al. Observing quantum gases in real time: Single-atom detection on a chip , 2009 .
[33] D. B. Tretyakov,et al. Quasiclassical calculations of blackbody-radiation-induced depopulation rates and effective lifetimes of Rydberg nS , nP , and nD alkali-metal atoms with n≤80 , 2009 .
[34] G. Kurizki,et al. Reversible state transfer between superconducting qubits and atomic ensembles , 2009, 0902.0881.
[35] J. Schmiedmayer,et al. Strong magnetic coupling of an ultracold gas to a superconducting waveguide cavity. , 2008, Physical review letters.
[36] A. Sørensen,et al. Quantum interface between light and atomic ensembles , 2008, 0807.3358.
[37] D. Petrosyan,et al. Quantum information processing with single photons and atomic ensembles in microwave coplanar waveguide resonators. , 2008, Physical review letters.
[38] S. Girvin,et al. Wiring up quantum systems , 2008, Nature.
[39] S. Haroche,et al. Bose-Einstein condensation on a superconducting atom chip , 2008, 0801.3538.
[40] H. Rubinsztein-Dunlop,et al. Calibration of a single-atom detector for atomic microchips , 2007, quant-ph/0702132.
[41] József Fortágh,et al. Magnetic microtraps for ultracold atoms , 2007 .
[42] D. Petrosyan,et al. Fundamentals of quantum optics and quantum information , 2006 .
[43] P. Zoller,et al. Hybrid quantum processors: molecular ensembles as quantum memory for solid state circuits. , 2006, Physical review letters.
[44] J. Marangos,et al. Electromagnetically induced transparency : Optics in coherent media , 2005 .
[45] W. J. Zande,et al. ℓ-state selective field ionization of rubidium Rydberg states , 2004 .
[46] S. Girvin,et al. Cavity quantum electrodynamics for superconducting electrical circuits: An architecture for quantum computation , 2004, cond-mat/0402216.
[47] T. Hänsch,et al. Coherence in microchip traps. , 2003, Physical review letters.
[48] P. Zoller,et al. Interfacing quantum-optical and solid-state qubits. , 2003, Physical review letters.
[49] D. Kleppner,et al. Stark structure of the Rydberg states of alkali-metal atoms , 1979 .