New concepts in basement membrane biology W Halfter, P Oertle, CA Monnier, L Camenzind, M Reyes‐Lua, H Hu, ... The FEBS journal 282 (23), 4466-4479, 2015 | 179 | 2015 |
A hole spin qubit in a fin field-effect transistor above 4 kelvin LC Camenzind, S Geyer, A Fuhrer, RJ Warburton, DM Zumbühl, ... Nature Electronics 5 (3), 178-183, 2022 | 175 | 2022 |
Ultrafast hole spin qubit with gate-tunable spin–orbit switch functionality FNM Froning, LC Camenzind, OAH van der Molen, A Li, EPAM Bakkers, ... Nature Nanotechnology 16 (3), 308-312, 2021 | 159 | 2021 |
Hyperfine-phonon spin relaxation in a single-electron GaAs quantum dot LC Camenzind, L Yu, P Stano, JD Zimmerman, AC Gossard, D Loss, ... Nature communications 9 (1), 3454, 2018 | 89 | 2018 |
Machine learning enables completely automatic tuning of a quantum device faster than human experts H Moon, DT Lennon, J Kirkpatrick, NM van Esbroeck, LC Camenzind, ... Nature communications 11 (1), 4161, 2020 | 83 | 2020 |
Diabetes-induced morphological, biomechanical, and compositional changes in ocular basement membranes M To, A Goz, L Camenzind, P Oertle, J Candiello, M Sullivan, PB Henrich, ... Experimental Eye Research 116, 298-307, 2013 | 74 | 2013 |
Efficiently measuring a quantum device using machine learning DT Lennon, H Moon, LC Camenzind, L Yu, DM Zumbühl, GAD Briggs, ... npj Quantum Information 5 (1), 79, 2019 | 73 | 2019 |
Superior rim stability of the lens capsule following manual over femtosecond laser capsulotomy MR Lua, P Oertle, L Camenzind, A Goz, CH Meyer, K Konieczka, ... Investigative ophthalmology & visual science 57 (6), 2839-2849, 2016 | 44 | 2016 |
Self-aligned gates for scalable silicon quantum computing S Geyer, LC Camenzind, L Czornomaz, V Deshpande, A Fuhrer, ... Applied Physics Letters 118 (10), 2021 | 43 | 2021 |
Quantum device fine-tuning using unsupervised embedding learning NM van Esbroeck, DT Lennon, H Moon, V Nguyen, F Vigneau, ... New Journal of Physics 22 (9), 095003, 2020 | 40 | 2020 |
Ambipolar quantum dots in undoped silicon fin field-effect transistors AV Kuhlmann, V Deshpande, LC Camenzind, DM Zumbühl, A Fuhrer Applied Physics Letters 113 (12), 2018 | 39 | 2018 |
Sensitive radiofrequency readout of quantum dots using an ultra-low-noise SQUID amplifier FJ Schupp, F Vigneau, Y Wen, A Mavalankar, J Griffiths, GAC Jones, ... Journal of Applied Physics 127 (24), 2020 | 28 | 2020 |
Spectroscopy of quantum dot orbitals with in-plane magnetic fields LC Camenzind, L Yu, P Stano, JD Zimmerman, AC Gossard, D Loss, ... Physical review letters 122 (20), 207701, 2019 | 28 | 2019 |
Deep reinforcement learning for efficient measurement of quantum devices V Nguyen, SB Orbell, DT Lennon, H Moon, F Vigneau, LC Camenzind, ... npj Quantum Information 7 (1), 100, 2021 | 25 | 2021 |
Orbital effects of a strong in-plane magnetic field on a gate-defined quantum dot P Stano, CH Hsu, LC Camenzind, L Yu, D Zumbühl, D Loss Physical Review B 99 (8), 085308, 2019 | 22 | 2019 |
Two-qubit logic with anisotropic exchange in a fin field-effect transistor S Geyer, B Hetényi, S Bosco, LC Camenzind, RS Eggli, A Fuhrer, D Loss, ... arXiv preprint arXiv:2212.02308, 2022 | 16 | 2022 |
-factor of electrons in gate-defined quantum dots in a strong in-plane magnetic field P Stano, CH Hsu, M Serina, LC Camenzind, DM Zumbühl, D Loss Physical Review B 98 (19), 195314, 2018 | 16 | 2018 |
Bridging the reality gap in quantum devices with physics-aware machine learning DL Craig, H Moon, F Fedele, DT Lennon, B van Straaten, F Vigneau, ... Physical Review X 14 (1), 011001, 2024 | 14 | 2024 |
Anisotropic exchange interaction of two hole-spin qubits S Geyer, B Hetényi, S Bosco, LC Camenzind, RS Eggli, A Fuhrer, D Loss, ... Nature Physics, 1-6, 2024 | 12 | 2024 |
Phase-driving hole spin qubits S Bosco, S Geyer, LC Camenzind, RS Eggli, A Fuhrer, RJ Warburton, ... Physical Review Letters 131 (19), 197001, 2023 | 12 | 2023 |