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

“Non-stoquastic Hamiltonians in quantum annealing via geometric phases”, Nature Quant. Info. **3**, 38 (2017), by W. Vinci and D. A. Lidar [link]

“Test-driving 1000 qubits”, [1706.07124], by J. Job and D. A. Lidar

“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]

“Reexamination of the evidence for entanglement in the D-Wave processor”, Phys. Rev. A **92, **062328 (2015) , by T. Albash, I. Hen, F. M. Spedalieri, 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]

“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]

“Defining and Detecting Quantum Speedup”, *Science* **345**, 420 (2014), by T.F. Ronnow, Z. Wang, J. Job, S.V. Isakov, D. Wecker, J.M. Martinis, D.A. Lidar, and M. Troyer.[link]

“MAX 2-SAT with up to 108 Qubits”, New J. Phys. **16**, 045006 (2014), by S. Santra, G. Quiroz, G. Ver Steeg, and D.A. Lidar. [link]

“Error Corrected Quantum Annealing with Hundreds of Qubits”, Nature Communications **5**, 3243 (2014), by K.P. Pudenz, T. Albash, and D.A. Lidar. [link][sup-mat]

“Evidence for Quantum Annealing with More Than One Hundred Qubits”, Nature Physics **10**, 218 (2014), by S. Boixo, T. Ronnow, S. Isakov, Z. Wang, D. Wecker, D.A. Lidar, J. Martinis, and M. Troyer. [link][sup-mat]

“Adiabatic Quantum Optimization with the Wrong Hamiltonian”, Phys. Rev. A **88**, 062314 (2013), by K.C. Young, R. Blume-Kohout, D.A. Lidar. [link]

“The Manipulation of Massive Ro-vibronic Superpositions Using Time-Frequency-Resolved Coherent Anti-Stokes Raman Scattering (TFRCARS): from Quantum Control to Quantum Computing”, Chemical Physics **266**, 323 (2001), R. Zadoyan, D. Kohen, D.A. Lidar, and V.A. Apkarian [pdf]

“An Implementation of the Deutsch-Jozsa Algorithm on Molecular Vibronic Coherences Through Four-Wave Mixing: a Theoretical Study”, Chem. Phys. Lett. **360**, 459 (2002), by Z. Bihary, D.R. Glenn, D.A. Lidar, and V.A. Apkarian [pdf]

“Comment on “Quantum Waveguide Array Generator for Performing Fourier Transforms: Alternate Route to Quantum Computing’’ [Appl. Phys. Lett. **79**, 2823 (2001)]”, Appl. Phys. Lett. 80, 2419 (2002), by D.A. Lidar [pdf]

“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]

“Dressed Qubits”, Phys. Rev. Lett. **91**, 097904 (2003), by L.-A. Wu and D.A. Lidar [pdf]

“Efficient Multiqubit Entanglement via a Spin-Bus”, Phys. Rev. Lett. **98**, 230503 (2007), by M. Friesen, A. Biswas, X. Hu, D.A. Lidar [link]

“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]

“Encoding a Qubit into Multilevel Subspaces”, New J. Phys. **8**, 35 (2006), by M. Grace, C. Brif, H. Rabitz, I. Walmsley, R. Kosut, and D.A. Lidar [link]

“Exchange Interaction Between Three and Four Coupled Quantum Dots: Theory and Applications to Quantum Computing”, Phys. Rev. B **70**, 115310 (2004), by A. Mizel and D. Lidar [pdf]

“Experimental Signature of Programmable Quantum Annealing”, Nature Communications **4**, 2067 (2013), by S. Boixo, T. Albash, F. Spedalieri, N. Chancellor, D.A. Lidar. [link]

“Exponentially Localized Magnetic Fields for Single-Spin Quantum Logic Gates”, J. Appl. Phys. **96**, 754 (2004), by D.A. Lidar and J.H. Thywissen [pdf]

“Fault-Tolerant Quantum Computation via Exchange Interactions”, Phys. Rev. Lett. **94**, 040507 (2005), by M. Mohseni and D.A. Lidar [pdf]

“Few-Body Spin Couplings and Their Implications for Universal Quantum Computation”, J. Phys. Cond. Mat. **18**, S721 (2006), special issue on quantum computing in solid state, by R. Woodworth, A. Mizel, and D.A. Lidar [link]

“No-Go Theorem for Passive Single-rail Linear Optical Quantum Computing”, Scientific Reports **3**, 1394 (2013), by L. Wu, P. Walther, and D.A. Lidar. [link]

“One-Spin Quantum Logic Gates from Exchange Interactions and a Global Magnetic Field”, Phys. Rev. Lett. **93**, 030501 (2004), by L.-A. Wu, D. Lidar, and M. Friesen [pdf]

“Power of Anisotropic Exchange Interactions: Universality and Efficient Codes for Quantum Computing”, Phys. Rev. A **65**, 042318 (2002), by L.-A. Wu and D.A. Lidar [pdf]

“Quantum Codes for Simplifying Design and Suppressing Decoherence in Superconducting Phase-Qubits”, Quant. Info. Proc. **1**, 155 (2002), by D.A. Lidar, L.-A. Wu, and A. Blais [pdf]

“Quantum Computing with Quantum Dots on Quantum Linear Supports”, Phys. Rev. A **65**, 012307 (2002), by K.R. Brown, D.A. Lidar, and K.B. Whaley [pdf]

“Quantum Logic Gates in Iodine Vapor Using Time-Frequency Resolved Coherent Anti-Stokes Raman Scattering: A Theoretical Study”, Mol. Phys. **104**, 1249 (2006), special issue in honor of Robert Harris, by D.R. Glenn, D.A. Lidar, and V.A. Apkarian [link]

“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]

“The Spin Density Matrix of a two-electron system. I : General Theory and Exact Master Equations”, Phys. Rev. B **77**, 045319 (2008), by S.D. Kunikeev and D.A. Lidar [link]

“The Spin Density Matrix of a two-electron system. II : Application to a System of Two Quantum Dots”, Phys. Rev. B **77**, 045320 (2008), by S.D. Kunikeev and D.A. Lidar [link]

“Three and Four-Body Interactions in Spin-Based Quantum Computers”, Phys. Rev. Lett. **92**, 077903 (2004), by A. Mizel and D.A. Lidar [pdf]

“Universal Quantum Computation Using Exchange Interactions and Measurements of Single- and Two-Spin Observables”, Phys. Rev. A Rapid Comm. **67**, 050303 (2003), by L.-A. Wu and D.A. Lidar [pdf]

“Universal Quantum Logic from Zeeman and Anisotropic Exchange Interactions”, Phys. Rev. A **66**, 062314 (2002), by L.-A. Wu and D.A. Lidar [pdf]