Natalia Ares
Natalia Ares
Verified email at materials.ox.ac.uk
Title
Cited by
Cited by
Year
Nature of Tunable Hole Factors in Quantum Dots
N Ares, VN Golovach, G Katsaros, M Stoffel, F Fournel, LI Glazman, ...
Physical review letters 110 (4), 046602, 2013
552013
Sensitive Radio-Frequency Measurements of a Quantum Dot by Tuning to Perfect Impedance Matching
N Ares, FJ Schupp, A Mavalankar, G Rogers, J Griffiths, GAC Jones, ...
Phys. Rev. Applied 5 (3), 034011, 2016
452016
Observation of spin-selective tunneling in SiGe nanocrystals
G Katsaros, VN Golovach, P Spathis, N Ares, M Stoffel, F Fournel, ...
Physical review letters 107 (24), 246601, 2011
402011
A coherent nanomechanical oscillator driven by single-electron tunnelling
Y Wen, N Ares, FJ Schupp, T Pei, GAD Briggs, EA Laird
Nature physics 16 (1), 75-82, 2020
322020
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), 1-8, 2019
322019
Resonant optomechanics with a vibrating carbon nanotube and a radio-frequency cavity
N Ares, T Pei, A Mavalankar, M Mergenthaler, JH Warner, GAD Briggs, ...
Physical review letters 117 (17), 170801, 2016
312016
Displacemon electromechanics: how to detect quantum interference in a nanomechanical resonator
KE Khosla, MR Vanner, N Ares, EA Laird
Physical Review X 8 (2), 021052, 2018
302018
SiGe quantum dots for fast hole spin Rabi oscillations
N Ares, G Katsaros, VN Golovach, JJ Zhang, A Prager, LI Glazman, ...
Applied Physics Letters 103 (26), 263113, 2013
302013
Strong Coupling of Microwave Photons to Antiferromagnetic Fluctuations in an Organic Magnet
EAL Matthias Mergenthaler, Junjie Liu, Jennifer J. Le Roy, Natalia Ares ...
Physical Review Letters 119, 147701, 2017
272017
Loschmidt echo and the local density of states
N Ares, DA Wisniacki
Physical Review E 80 (4), 046216, 2009
242009
Universal response of quantum systems with chaotic dynamics
DA Wisniacki, N Ares, EG Vergini
Physical review letters 104 (25), 254101, 2010
202010
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), 1-10, 2020
182020
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
102020
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), 244503, 2020
82020
Hyperfine and spin-orbit coupling effects on decay of spin-valley states in a carbon nanotube
T Pei, A Pályi, M Mergenthaler, N Ares, A Mavalankar, JH Warner, ...
Physical review letters 118 (17), 177701, 2017
82017
Efficiently measuring a quantum device using machine learning. npj Quantum Inf. 5
DT Lennon, H Moon, LC Camenzind, L Yu, DM Zumbühl, GAD Briggs, ...
62019
Measuring carbon nanotube vibrations using a single-electron transistor as a fast linear amplifier
Y Wen, N Ares, T Pei, GAD Briggs, EA Laird
Applied Physics Letters 113 (15), 153101, 2018
62018
Measuring the thermodynamic cost of timekeeping
AN Pearson, Y Guryanova, P Erker, EA Laird, GAD Briggs, M Huber, ...
Physical Review X 11 (2), 021029, 2021
42021
Radio-frequency optomechanical characterization of a silicon nitride drum
AN Pearson, KE Khosla, M Mergenthaler, GAD Briggs, EA Laird, N Ares
Scientific reports 10 (1), 1-7, 2020
32020
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), 1-9, 2021
22021
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Articles 1–20