Observation of dipolar spin-exchange interactions with lattice-confined polar molecules B Yan, SA Moses, B Gadway, JP Covey, KRA Hazzard, AM Rey, DS Jin, ... Nature 501 (7468), 521-525, 2013 | 971 | 2013 |
Demonstration of the trapped-ion quantum CCD computer architecture JM Pino, JM Dreiling, C Figgatt, JP Gaebler, SA Moses, MS Allman, ... Nature 592 (7853), 209-213, 2021 | 597 | 2021 |
Long-lived dipolar molecules and Feshbach molecules in a 3D optical lattice A Chotia, B Neyenhuis, SA Moses, B Yan, JP Covey, M Foss-Feig, ... Physical review letters 108 (8), 080405, 2012 | 325 | 2012 |
New frontiers for quantum gases of polar molecules SA Moses, JP Covey, MT Miecnikowski, DS Jin, J Ye Nature Physics 13 (1), 13-20, 2017 | 279 | 2017 |
Many-body dynamics of dipolar molecules in an optical lattice KRA Hazzard, B Gadway, M Foss-Feig, B Yan, SA Moses, JP Covey, ... Physical review letters 113 (19), 195302, 2014 | 237 | 2014 |
Creation of a low-entropy quantum gas of polar molecules in an optical lattice SA Moses, JP Covey, MT Miecnikowski, B Yan, B Gadway, J Ye, DS Jin Science 350 (6261), 659-662, 2015 | 232 | 2015 |
A race-track trapped-ion quantum processor SA Moses, CH Baldwin, MS Allman, R Ancona, L Ascarrunz, C Barnes, ... Physical Review X 13 (4), 041052, 2023 | 188 | 2023 |
Suppressing the loss of ultracold molecules via the continuous quantum Zeno effect B Zhu, B Gadway, M Foss-Feig, J Schachenmayer, ML Wall, ... Physical review letters 112 (7), 070404, 2014 | 173 | 2014 |
In situ nanostructure generation and evolution within a bulk thermoelectric material to reduce lattice thermal conductivity SN Girard, J He, C Li, S Moses, G Wang, C Uher, VP Dravid, ... Nano letters 10 (8), 2825-2831, 2010 | 154 | 2010 |
Anisotropic Polarizability of Ultracold Polar Molecules B Neyenhuis, B Yan, SA Moses, JP Covey, A Chotia, A Petrov, ... Physical review letters 109 (23), 230403, 2012 | 137 | 2012 |
Holographic quantum algorithms for simulating correlated spin systems M Foss-Feig, D Hayes, JM Dreiling, C Figgatt, JP Gaebler, SA Moses, ... Physical Review Research 3 (3), 033002, 2021 | 98 | 2021 |
Non-Abelian topological order and anyons on a trapped-ion processor M Iqbal, N Tantivasadakarn, R Verresen, SL Campbell, JM Dreiling, ... Nature 626 (7999), 505-511, 2024 | 87 | 2024 |
Demonstration of two-atom entanglement with ultrafast optical pulses JD Wong-Campos, SA Moses, KG Johnson, C Monroe Physical Review Letters 119 (23), 230501, 2017 | 86 | 2017 |
Thermoelectric Properties and Nanostructuring in the p-Type Materials NaPb18−xSnxMTe20 (M = Sb, Bi) A Guéguen, PFP Poudeu, CP Li, S Moses, C Uher, J He, V Dravid, ... Chemistry of Materials 21 (8), 1683-1694, 2009 | 82 | 2009 |
Doublon dynamics and polar molecule production in an optical lattice JP Covey, SA Moses, M Gärttner, A Safavi-Naini, MT Miecnikowski, Z Fu, ... Nature communications 7 (1), 11279, 2016 | 61 | 2016 |
Evidence of scaling advantage for the quantum approximate optimization algorithm on a classically intractable problem R Shaydulin, C Li, S Chakrabarti, M DeCross, D Herman, N Kumar, ... Science Advances 10 (22), eadm6761, 2024 | 42 | 2024 |
Entanglement from tensor networks on a trapped-ion quantum computer M Foss-Feig, S Ragole, A Potter, J Dreiling, C Figgatt, J Gaebler, A Hall, ... Physical Review Letters 128 (15), 150504, 2022 | 42 | 2022 |
Suppression of midcircuit measurement crosstalk errors with micromotion JP Gaebler, CH Baldwin, SA Moses, JM Dreiling, C Figgatt, M Foss-Feig, ... Physical Review A 104 (6), 062440, 2021 | 37 | 2021 |
Demonstration of logical qubits and repeated error correction with better-than-physical error rates MP Da Silva, C Ryan-Anderson, JM Bello-Rivas, A Chernoguzov, ... arXiv preprint arXiv:2404.02280, 2024 | 34 | 2024 |
Demonstration of the QCCD trapped-ion quantum computer architecture JM Pino, JM Dreiling, C Figgatt, JP Gaebler, SA Moses, CH Baldwin, ... arXiv preprint arXiv:2003.01293, 1-11, 2020 | 31 | 2020 |