Dynamical decoupling

“Better-than-classical Grover search via quantum error detection and suppression”, npj Quantum Information volume 10, 23 (2024), by B. Pokharel and D. A. Lidar. [link]

“Modeling low- and high-frequency noise in transmon qubits with resource-efficient measurement”, PRX Quantum 5, 010320 (2024), by V. Tripathi, H. Chen, E. M. Levenson-Falk and D. A. Lidar [link]

“Demonstration of Algorithmic Quantum Speedup for an Abelian Hidden Subgroup Problem”, [2401.07934] by P. Singkanipa, V. Kasatkin, Z. Zhou, G. Quiroz, D.A. Lidar.

“Dynamical decoupling for superconducting qubits: A performance survey”, Phys. Rev. Applied 20, 064027, (2023) by N. Ezzell, B. Pokharel, L. Tewala, G. Quiroz and D. A. Lidar [link]

“Suppression of crosstalk in superconducting qubits using dynamical decoupling”, Phys. Rev. Applied 18, 024068 (2022), by V. Tripathi, H. Chen, M. Khezri, Ka-Wa Yip, E. M. Levenson-Falk, D. A. Lidar [link]

“Completely positive master equation for arbitrary driving and small level spacing”, Quantum 4, 227 (2020), by E. Mozgunov and D. A. Lidar [link]

“Demonstration of fidelity improvement using dynamical decoupling with superconducting qubits”, Phys. Rev. Lett. 121, 220502 (2018), by B. Pokharel, N. Anand, B Fortman and D. A. Lidar [link]

“Suppression of effective noise in Hamiltonian simulations”, Phys. Rev. A 96, 052328 (2017) , by M. Marvian, T. Brun and D. A. Lidar [link]

“Review of Decoherence Free Subspaces, Noiseless Subsystems, and Dynamical Decoupling”, Quant. Info. & Comp. for Chem., Vol 154, pp. 295-354, by D. Lidar [link]

“Optimally Combining Dynamical Decoupling and Quantum Error Correction”, Scientific Reports 3, 1530 (2013), by G.A. Paz Silva and D.A. Lidar. [link]

“Optimized Dynamical Decoupling via Genetic Algorithms”, Phys. Rev. A 88, 052306 (2013), by G. Quiroz and D.A. Lidar. [link]

“Universality Proof and Analysis of Generalized Nested Uhrig Dynamical Decoupling”, J. Math. Phys. 53, 122207 (2012), by W.J. Kuo, G. Quiroz, G. Paz Silva, D.A. Lidar. [link]

“High-Fidelity Adiabatic Quantum Computation via Dynamical Decoupling”, Phys. Rev. A 86, 042333 (2012), by G. Quiroz and D.A. Lidar. [link]

“Decoherence-Protected Quantum Gates for a Hybrid Solid-State Spin Register”, Nature 484, 82 (2012), by T. van der Sar, Z.H. Wang, M.S. Blok, H. Bernien, T.H. Taminiau, D.M. Toyli, D.A. Lidar, D.D. Awschalom, R. Hanson, and V.V. Dobrovitski [link]

“Rigorous Performance Bounds for Quadratic and Nested Dynamical Decoupling”, Phys. Rev.A 84, 062332 (2011), by Y. Xia, G. S. Uhrig, D.A. Lidar. [link]

“Quadratic Dynamical Decoupling: Universality Proof and Error Analysis”, Phys. Rev. A 84, 042329 (2011), by W. Kuo and D.A. Lidar. [link]

“Quadratic Dynamical Decoupling with Nonuniform Error Suppression”, Phys. Rev. A 84, 042328 (2011), by G. Quiroz and D.A. Lidar. [link]

“High Fidelity Quantum Memory via Dynamical Decoupling: Theory and Experiment”, J. Phys. B 44, 154003 (2011), by X. Peng, D. Suter, and D.A Lidar. [link]

“Combining Dynamical Decoupling with Fault-Tolerant Quantum Computation”, Phys. Rev. A 84, 012305 (2011), by H.K. Ng, D.A. Lidar, and J. Preskill. [link]

“High Fidelity Quantum Gates via Dynamical Decoupling”, Phys. Rev. Lett 105, 230503 (2010), by J.R. West, D.A. Lidar, B. H. Fong, and M.F. Gyure. [link]

“Rigorous Bounds for Optimal Dynamical Decoupling”, Phys. Rev. A 82, 012301 (2010), by G.S. Uhrig and D.A. Lidar. [link]

“Near-Optimal Dynamical Decoupling of a Qubit”, Phys. Rev. Lett 104, 130501 (2010), by J.R. West, B.H. Fong, and D.A. Lidar. [link]

“Arbitrarily Accurate Dynamical Control in Open Quantum Systems”, Phys. Rev. Lett 104, 090501 (2010), by K. Khodjasteh, D.A. Lidar, and L. Viola. [link]

“Rigorous Bounds on the Performance of a Hybrid Dynamical Decoupling-Quantum Computing Scheme”, Phys. Rev. A 78, 012355 (2008), by K. Khodjasteh, and D.A. Lidar [link]

“Distance Bounds on Quantum Dynamics”, Phys. Rev. A 78, 012308 (2008), by D.A. Lidar, P. Zanardi, and K. Khodjasteh [link]

“Bang-Bang Control of a Qubit Coupled to a Quantum Critical Spin Bath”, Phys. Rev. A 77, 052112 (2008), by D. Rossini, P. Facchi, R. Fazio, G. Florio, D.A. Lidar, S. Pascazio, F. Plastina, and P. Zanardi [link]

“Towards Fault Tolerant Adiabatic Quantum Computation”, Phys. Rev. Lett. 100, 160506 (2008), by D.A. Lidar [link]

“Performance of Deterministic Dynamical Decoupling Schemes: Concatenated and Periodic Pulse Sequences”, Phys. Rev. A 75, 062310 (2007), by K. Khodjasteh and D.A. Lidar. [link] ;  “Erratum:  Performance of Deterministic Dynamical Decoupling Schemes: Concatenated and Periodic Pulse Sequences”, Phys Rev A 79, 069901(E) (2009).  

“Robust Transmission of Non-Gaussian Entanglement Over Optical Fibers”, Phys. Rev. A 74, 062303 (2006), by A. Biswas and D.A. Lidar [link]

“Fault-Tolerant Quantum Dynamical Decoupling”, Phys. Rev. Lett. 95, 180501 (2005), by K. Khodjasteh and D.A. Lidar [pdf]

“Universal Leakage Elimination”, Phys. Rev. A 71, 052301 (2005), by M.S. Byrd, D.A. Lidar, L.A. Wu, and P. Zanardi [pdf]

“Control of Decoherence: Analysis and Comparison of Three Different Strategies”, Phys. Rev. A 71, 022302 (2005), by P. Facchi, S. Tasaki, S. Pascazio, H. Nakazato, A. Tokuse, and D.A. Lidar [pdf]

“Overview of Quantum Error Prevention and Leakage Elimination”, J. Mod. Optics 51, 2449 (2004), by M.S. Byrd, L.-A. Wu, and D. Lidar [pdf]

“Overcoming Quantum Noise in Optical Fibers”, Phys. Rev. A 70, 062310 (2004), by L.-A. Wu and D. Lidar [pdf]

“Unification of Dynamical Decoupling and the Quantum Zeno Effect”, Phys. Rev. A 69, 032314 (2004), by P. Facchi, D.A. Lidar, and S. Pascazio [pdf]

“Dynamical Decoupling Using Slow Pulses: Efficient Suppression of 1/f Noise”, Phys. Rev. A Rapid Comm. 69, 030302 (2004), by K. Shiokawa and D.A. Lidar [pdf]

“Quantum Computing in the Presence of Spontaneous Emission by a Combined Dynamical Decoupling and Quantum-Error-Correction Strategy”, Phys. Rev. A 68, 022322 (2003), by K. Khodjasteh and D.A. Lidar. [pdf] ;  “Erratum: Quantum computing in the presence of spontaneous emission by a combined dynamical decoupling and quantum-error-correction strategy”, Phys. Rev. A 72, 029905 (2005) [link]

“Combined Error Correction Techniques for Quantum Computing Architectures”, J. Mod. Optics 50, 1285 (2003), by M.S. Byrd and D.A. Lidar [pdf]

“Encoded Recoupling and Decoupling: An Alternative to Quantum Error-Correcting Codes Applied to Trapped-Ion Quantum Computation”, Phys. Rev. A 67, 032313 (2003), by D.A. Lidar and L.-A. Wu [pdf]

“Empirical Determination of Dynamical Decoupling Operations”, Phys. Rev. A 67, 012324 (2003), by M.S. Byrd and D.A. Lidar [pdf]

“Efficient Universal Leakage Elimination for Physical and Encoded Qubits”, Phys. Rev. Lett. 89, 127901 (2002), by L.-A. Wu, M.S. Byrd, and D.A. Lidar [pdf]

“Bang-Bang Operations from a Geometric Perspective”, Quant. Info. Proc. 1, 19 (2002), by M.S. Byrd and D.A. Lidar [pdf]

“Comprehensive Encoding and Decoupling Solution to Problems of Decoherence and Design in Solid-State Quantum Computing”, Phys. Rev. Lett. 89, 047901 (2002), by M.S. Byrd and D.A. Lidar [pdf]

“Creating Decoherence-Free Subspaces Using Strong and Fast Pulses”, Phys. Rev. Lett. 88, 207902 (2002), by L.-A. Wu and D.A. Lidar [pdf]

“Reducing Constraints on Quantum Computer Design by Encoded Selective Recoupling”, Phys. Rev. Lett. 88, 017905 (2002), by D.A. Lidar and L.-A. Wu [pdf]