Open quantum systems

“Families of d=2 2D subsystem stabilizer codes for universal Hamiltonian quantum computation with two-body interactions”, [2412.06744] by P. Singkanipa, Z. Xia, D. A. Lidar

“Quantum Property Preservation”, [2408.11262] by K. Saurav, D. A. Lidar.

“Dynamically Generated Decoherence-Free Subspaces and Subsystems on Superconducting Qubits”, Reports on Progress in Physics 87, 097601, G. Quiroz, B. Pokharel, J. Boen, L. Tewala, V. Tripathi, D. Williams, L. Wu, P. Titum, K. Schultz, and D. A. Lidar. [link]

“Deterministic Benchmarking of Quantum Gates”, [2407.09942] by V. Tripathi, D. Kowsari, K. Saurav, H. Zhang, E. M. Levenson-Falk, D. A. Lidar.

“Markovian and non-Markovian master equations versus an exactly solvable model of a qubit in a cavity”, Phys. Rev. Applied 22, 014028, Z. Xia, J. Garcia-Nila, D. A. Lidar. [link]

“Error budget of a parametric resonance entangling gate with a tunable coupler”, Phys. Rev. Applied 22, 014059 (2024), by E. A. Sete, V. Tripathi, J. A. Valery, D. A. Lidar, J. Y. Mutus. [link]

“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]

“Beyond unital noise in variational quantum algorithms: noise-induced barren plateaus and fixed points”, [2402.08721] by P. Singkanipa, D.A. Lidar.

“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]

“Boundaries of quantum supremacy via random circuit sampling”, npj Quantum Information, 9, 36 (2023), by A. Zlokapa, S. Boixo, and D. A. Lidar [link]

“Demonstration of Error-Suppressed Quantum Annealing Via Boundary Cancellation”, Phys. Rev. Applied 19 , 034095 (2023), by H. Munoz-Bauza, L. Campos Venuti, and D. A. Lidar [link]

“Which differential equations correspond to the Lindblad equation?”, Phys. Rev. Research 5, 043163 (2023), by V. Kasatkin, L. Gu 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]

“Breakdown of the weak coupling limit in quantum annealing”, Phys. Rev. Applied 17, 054033 (2022), by Y. Bando, Ka-Wa Yip, H. Chen, D. A. Lidar, H. Nishimori [link]

“Predicting non-Markovian superconducting qubit dynamics from tomographic reconstruction”, Phys. Rev. Applied 17, 054018 (2022), by H. Zhang, B. Pokharel, E. M. Levenson-Falk and D. A. Lidar [link]

“HOQST: Hamiltonian Open Quantum System Toolkit”, Communications Physics (2022)5:11, by H. Chen and D. A. Lidar [link]

“Anneal-path correction in flux qubits”, npj Quantum Information 7, 36 (2021), by M. Khezri, J. Grover, J. Basham, S. Disseler, H. Chen, S. Novikov, K. Zick, D. A. Lidar [link]

“Limitations of error corrected quantum annealing in improving the performance of Boltzmann machines”, Quantum Science and Technology 5, 045010 (2020), by R. Li, T. Albash and D. A. Lidar [link]

“Why and when is pausing beneficial in quantum annealing?”, Phys. Rev. Applied 14, 014100 (2020),  by H. Chen and D. A. Lidar [link]

“Probing the Universality of Topological Defect Formation in a Quantum Annealer: Kibble-Zurek Mechanism and Beyond”, Phys. Rev. Research 2, 033369 (September 2020), by Y. Bando, Y. Susa, H. Oshiyama, N. Shibata, M. Ohzeki, F. J. G´omez-Ruiz, D. A. Lidar, A. del Campo, S. Suzuki, and H. Nishimori [link]

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

“Analog Errors in Quantum Annealing: Doom and Hope” npj Quantum Information 5, 107 (2019), by A. Pearson, A. Mishra, I. Hen and D. A. Lidar [link]

“Nested Quantum Annealing Correction at Finite Temperature: p-spin models”, Phys. Rev. A 99, 062307 (2019), by S. Matsuura, H. Nishimori, W. Vinci, D. A. Lidar [link]

“A Double-Slit Proposal for Quantum Annealing”, npj Quantum Information 5, 2 (2019), by H. Munoz-Bauza, H. Chen, D. A. Lidar [link]

“Sensitivity of quantum speedup by quantum annealing to a noisy oracle”, Phys. Rev. A 99, 032324 (2019), by S. Muthukrishnan, T. Albash and D. A. Lidar [link]

“Non-Markovianity of the Post Markovian Master Equation”, Phys. Rev. A 98, 042119 (2018), by C. Sutherland, T. A. Brun and D. A. Lidar [link]

“Error Reduction in Quantum Annealing using Boundary Cancellation: Only the End Matters”, Phys. Rev. A 98, 022315 (2018) , by L. Campos Venuti and D. A. Lidar [link]

“Finite temperature quantum annealing solving exponentially small gap problem with non-monotonic success probability”, Nature Comm92917 (2018), by A. Mishra, T. Albash and D. A. Lidar [link]

“Test-driving 1000 qubits”, Quantum Science & Technology 3, 030501 (2018). Special issue on “What would you do with 1000 qubits” , by J. Job and D. A. Lidar [link]

“Quantum trajectories for time-dependent adiabatic master equations”, Phys. Rev. A 97, 022116 (2018), by K. W. Yip, T. Albash, D. A. Lidar [link]

“Scalable effective temperature reduction for quantum annealers via nested quantum annealing correction”, Phys. Rev. A 97, 022308 (2018), by W. Vinci 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]

“Relaxation vs. adiabatic quantum steady state preparation: which wins?”, Phys. Rev. A 95, 042302 (2017), by L. Campos Venuti, T. Albash, M. Marvian, D. A. Lidar, and P. Zanardi [link]

“Error Suppression for Hamiltonian Quantum Computing in Markovian Environments”, Phys. Rev. A 95, 032302 (2017), by M. Marvian and D. A. Lidar [link]

“Quantum annealing correction at finite temperature: ferromagnetic p-spin models”, Phys. Rev. A 95, 022308 (2017), by S. Matsuura, H. Nishimori, W. Vinci, T. Albash, and D. A. Lidar [link]

“Error suppression for Hamiltonian-based quantum computation using subsystem codes”, Phys. Rev. Lett. 118, 030504 (2017), by M. Marvian and D. A. Lidar [link]

“Evolution Prediction from Tomography”, Q. Info. Proc. 16(3), 1 (2017), by J. Dominy, L. Campos-Venuti, A. Shabani, and D.A. Lidar [link]

“Simulated Quantum Annealing with Two All-to-All Connectivity Schemes”, Phys. Rev. A 94, 022327 (2016), by T. Albash, W. Vinci, and D. A. Lidar [link]

“Adiabaticity in open quantum systems”, Phys. Rev. A 93, 032118 (2016), by L.C. Venuti, T. Albash, D. A. Lidar, and P. Zanardi [link]

Beyond Complete Positivity”, Quant. Info. Proc. 15, 1, pp 1349 (2016), by J. Dominy and D.A. Lidar [link]

“A General Framework for Complete Positivity”, Quant. Info. Proc. 15, 1, pp. 1 (2016), by J. Dominy, A. Shabani, and D.A. Lidar. [link]

“Quantum speed limits for leakage and decoherence”, Phys. Rev. Lett. 115, 210402 (2015), by I. Marvian, D.A. Lidar [link]

“Consistency tests of classical and quantum models for a quantum annealer”, Phys. Rev. A 91, 042314 (2015), by T. Albash, W. Vinci, A. Mishra, P.A. Warburton, and D.A. Lidar [link]

“Decoherence in adiabatic quantum computation”, Phys. Rev. A 91, 062320 (2015), by T. Albash and D.A. Lidar [link]

“Reexamining classical and quantum models for the D-Wave One processor”, The European Physics Journal, Special Topics 224, 111 (special issue on quantum annealing) (2015), by T. Albash, T. Ronnow, M. Troyer, D.A. Lidar [link]

“Quantum error suppression with commuting Hamiltonians: Two-local is too local”, Phys. Rev. Lett. 113, 260504 (2014), by I. Marvian and D.A. Lidar [link]

“From Completely Positive Maps to the Quantum Markovian Semigroup Master Equation”, Chemical Physics 268, 35 (2001), D.A. Lidar, Z. Bihary, and K.B. Whaley, special issue on Dynamics of Open Quantum Systems [pdf]

“Abelian and Non-Abelian Geometric Phases in Adiabatic Open Quantum Systems”, Phys. Rev. A 73, 062101 (2006), by M.S. Sarandy and D.A. Lidar [link]

“Adiabatic Approximation in Open Quantum Systems”, Phys. Rev. A 71, 012331 (2005), by M.S. Sarandy and D.A. Lidar [pdf]

“Coarse Graining Can Beat the Rotating-Wave Approximation in Quantum Markovian Master Equations”, Phys. Rev. A 88, 012103 (2013), by C. Majenz, T. Albash, H.P. Breuer, and D.A. Lidar. [link]

“Completely Positive Post-Markovian Master Equation via a Measurement Approach”, Phys. Rev. A Rapid Comm. 71, 020101 (2005), by A. Shabani and D.A. Lidar [pdf]

“Conditions for Strictly Purity-Decreasing Quantum Markovian Dynamics”, Chemical Physics 322, 82 (2006), the special issue “Real-Time Dynamics in Complex Quantum Systems” in honor of Phil Pechukas, by D.A. Lidar, A. Shabani, and R. Alicki [link]

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

“Fluctuation Theorems for Quantum Processes”, Phys. Rev. E 88, 032146 (2013), by T. Albash, D.A. Lidar, M. Marvian, P. Zanardi. [link]

“Internal Consistency of Fault-Tolerant Quantum Error Correction in Light of Rigorous Derivations of the Quantum Markovian Limit”, Phys. Rev. A 73, 052311 (2006), by R. Alicki, D.A Lidar, and P. Zanardi [link]

“Non-Markovian Dynamics of a Qubit Coupled to an Ising Spin Bath”, Phys. Rev. A 76, 052117 (2007), by H. Krovi, O. Oreshkov, M. Ryazanov, and D.A. Lidar [link]

“Purity and State Fidelity of Quantum Channels”, Phys. Rev. A 70, 012315 (2004), by P. Zanardi and D. Lidar [pdf]

“Quantum Adiabatic Markovian Master Equations”, New J. of Physics 14, 123016 (2012), by T. Albash, S. Boixo, D.A. Lidar, and P. Zanardi. [link]

“Robustness of Multiqubit Entanglement in the Independent Decoherence Model”, Phys. Rev. A 72, 042339 (2005), by S. Bandyopadhyay and D.A. Lidar [pdf]