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Équipe de Recherche en Physique de l'Information Quantique



Publications


2019
[17]
A. Gyenis, P. S. Mundada, A. Di Paolo, T. Hazard, X. You, D. Schuster, J. Koch,A. Blais, A. A. Houck,
Experimental realization of an intrinsically error-protected superconducting qubit,
arXiv e-prints, (arXiv:1910.07542), 2019,
[bib] [pdf] [eprint]
[16]
Agustin Di Paolo, Arne L Grimsmo, Peter Groszkowski, Jens Koch and Alexandre Blais,
Control and coherence time enhancement of the 0 extendash$uppi$ qubit,
New Journal of Physics, 21, (043002), 2019,
[bib] [pdf] [url]
[15]
Agustin Di Paolo, Panagiotis Kl. Barkoutsos, Ivano Tavernelli and Alexandre Blais,
Variational Quantum Simulation of Ultrastrong Light-Matter Coupling,
2019,
[bib] [pdf] [eprint]
[14]
Anirudh Krishna and David Poulin,
Topological wormholes,
2019,
[bib] [pdf] [eprint]
[13]
Anirudh Krishna and David Poulin,
Fault-tolerant gates on hypergraph product codes,
2019,
[bib] [pdf] [eprint]
[12]
Ben Sussman, Paul Corkum, Alexandre Blais, David Cory and Andrea Damascelli,
Quantum Canada,
Quantum Science and Technology, 4, (020503), 2019,
[bib] [pdf] [url]
[11]
C. Walsh and P. Sémon and D. Poulin and G. Sordi and A. -M. S. Tremblay,
Thermodynamic and information-theoretic description of the Mott transition in the two-dimensional Hubbard model,
Phys. Rev. B, 99, (075122), 2019,
[bib] [pdf] [eprint]
[10]
C. Walsh and P. Sémon and D. Poulin and G. Sordi and A. -M. S. Tremblay,
Entanglement entropy and mutual information across the Mott transition in the two-dimensional Hubbard model,
Phys. Rev. Lett., 122, (067203), 2019,
[bib] [pdf] [eprint]
[9]
Christian Kraglund Andersen, Archana Kamal, Nicholas A. Masluk, Ioan M. Pop, Alexandre Blais and Michel H. Devoret,
Quantum versus classical switching dynamics of driven-dissipative Kerr resonators,
arXiv e-prints, (arXiv:1906.10022), 2019,
[bib] [pdf] [eprint]
[8]
David Poulin and Roger G. Melko and Matthew B. Hastings,
Self-correction in Wegner’s 3D Ising lattice gauge theory,
Phys. Rev. B, 99, (094103), 2019,
[bib] [pdf] [eprint]
[7]
K. Kalashnikov, W.T. Hsieh, W. Zhang, W.-S. Lu, P. Kamenov, A. Di Paolo, A. Blais, M.W. Gershenson and M. Bell,
Bifluxon: Fluxon-Parity-Protected Superconducting Qubit,
arXiv e-prints, (arXiv:1910.03769), 2019,
[bib] [pdf] [eprint]
[6]
P. Kurpiers, M. Pechal, B. Royer, P. Magnard, T. Walter, J. Heinsoo, Y. Salathé, A. Akin, S. StorzJ.-C. Besse, S. Gasparinetti, A. Blais and A. Wallraff,
Quantum Communication with Time-Bin Encoded Microwave Photons,
Phys. Rev. Applied, 12, (044067), 2019,
[bib] [pdf] [url]
[5]
S. Puri, L. St-Jean, J. Gross, A. Grimm, N.E. Frattini, P. Iyer, A. Krishna, S. Touzard, L. Jiang, A. Blais, S. Flammia, S.M. Girvin,
Bias-preserving gates with stabilized cat qubits,
arXiv e-prints, (arXiv:1905.00450), 2019,
[bib] [pdf] [eprint]
[4]
Scarlino, P. and van Woerkom, D. J. and Mendes, U. C. and Koski, J. V. and Landig, A. J. and Andersen, C. K. and Gasparinetti, S. and Reichl, C. and Wegscheider, W. and Ensslin, K. and Ihn, T. and Blais, A. and Wallraff, A.,
Coherent microwave-photon-mediated coupling between a semiconductor and a superconducting qubit,
Nature Communications, 10, (3011), 2019,
[bib] [pdf] [url]
[3]
T. M Hazard, A. Gyenis, A. Di Paolo, A. T. Asfaw, S. A Lyon, A. Blais, A. A. Houck,
Nanowire Superinductance Fluxonium Qubit,
Phys. Rev. Lett., 122, (010504), 2019,
[bib] [pdf] [url]
[2]
U.C. Mendes, S. Jezouin, P. Joyez, B. Reulet, A. Blais, F. Portier, C. Mora and C. Altimiras,
Parametric amplification and squeezing with an ac- and dc-voltage biased superconducting junction,
Phys. Rev. Applied, 11, (034035), 2019,
[bib] [pdf] [url]
[1]
Ye-Hua Liu and David Poulin,
Neural Belief-Propagation Decoders for Quantum Error-Correcting Codes,
Phys. Rev. Lett., 122, (200501), 2019,
[bib] [pdf] [eprint]