Noise spectroscopy with qubits

19) K. Roszak and Ł. Cywiński,
Qubit-environment entanglement generation and the spin echo
Phys. Rev. A 103, 032208 (2021)
arXiv:2007.02656

18) P. Szańkowski and Ł. Cywiński,
Noise representations of open system dynamics
Sci. Rep. 10, 22189 (2021)
arXiv:2003.09688

17) D. Kwiatkowski, P. Szańkowski, and Ł. Cywiński,
Influence of nuclear spin polarization on spin-echo signal of an NV-center qubit
Phys. Rev. B 101, 155412 (2020)
arXiv:1909.06438

16) F. Sakuldee and Ł. Cywiński
Relationship between subjecting the qubit to dynamical decoupling and to a sequence of projective measurements
Phys. Rev. A 101, 042329 (2020)
arXiv:1907.05165

15) F. Sakuldee and Ł. Cywiński
Spectroscopy of classical environmental noise with a qubit subjected to projective measurements
Phys. Rev. A 101, 012314 (2020)
arXiv:1907.01784

14) F. Sakuldee and Ł. Cywiński
Characterization of a quasistatic environment with a qubit
Phys. Rev. A 99, 062113 (2019)
arXiv:1903.06463

13) K. Roszak, D. Kwiatkowski, and Ł. Cywiński
How to detect qubit-environment entanglement generated during qubit dephasing
Phys. Rev. A 100, 022318 (2019)
arXiv:1810.09217

12) J. Krzywda, P. Szańkowski, and Ł. Cywiński
The dynamical-decoupling-based spatiotemporal noise spectroscopy
New J. Phys. 21, 043034 (2019)
arXiv:1809.02972

11) J. Krzywda, P. Szańkowski, J. Chwedeńczuk, and Ł. Cywiński
Decoherence-assisted detection of entanglement of bipartite states
Phys. Rev. A 98, 022329 (2018)
arXiv:1806.08728

10) D. Kwiatkowski and Ł. Cywiński
Decoherence of two entangled spin qubits coupled to an interacting sparse nuclear spin bath: application to nitrogen vacancy centers
Phys. Rev. B 98, 155202 (2018)
arXiv:1806.06845

9) P. Szańkowski and Ł. Cywiński
Accuracy of dynamical decoupling based spectroscopy of Gaussian noise
Phys. Rev. A 97, 032101 (2018)
arXiv:1708.05535

8) J. Krzywda, Ł. Cywiński, and P. Szańkowski
Localization of a magnetic moment using a two-qubit probe
Phys. Rev. A 96, 042108 (2017)
arXiv:1706.02948

7) P. Szańkowski, G. Ramon, J. Krzywda, D. Kwiatkowski, and Ł. Cywiński
Environmental noise spectroscopy with qubits subjected to dynamical decoupling
J. Phys.: Condens. Matter. 29, 333001 (2017)
arXiv:1705.02262

6) F. K. Malinowski, F. Martins, Ł. Cywiński, M. S. Rudner, P. D. Nissen, S. Fallahi, G. C. Gardner, M. J. Manfra, C. M. Marcus, and F. Kuemmeth
Spectrum of the Nuclear Environment for GaAs Spin Qubits
Phys. Rev. Lett. 118, 177702 (2017)
arXiv:1701.01855

5) F. K. Malinowski, F. Martins, P. D. Nissen, E. Barnes, Ł. Cywiński, M. S. Rudner, S. Fallahi, G. C. Gardner, M. J. Manfra, C. M. Marcus, and F. Kuemmeth
Notch filtering the nuclear environment of a spin qubit
Nature Nanotechnology 12, 16  (2017)
arXiv:1601.06677

4) P. Szańkowski, M. Trippenbach,  and Ł. Cywinski
Spectroscopy of cross-correlations of environmental noises with two qubits
Phys. Rev. A 94, 012109 (2016)
arXiv:1507.03897

3) Ł. Cywiński
Dynamical-decoupling noise spectroscopy at an optimal working point of a qubit
Phys. Rev. A 90, 042307 (2014)
arXiv:1308.3102

2) J. Medford, Ł. Cywiński, C. Barthel, C.M. Marcus, M.P. Hanson, and A.C. Gossard
Scaling of Dynamical Decoupling for Spin Qubits
Phys. Rev. Lett. 108, 086802 (2012)
arXiv:1108.3682

1) Ł. Cywiński, R.M. Lutchyn, C.P. Nave, and S. Das Sarma
How to enhance dephasing time in superconducting qubits
Phys. Rev. B 77, 174509 (2008)
arXiv:0712.2225