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Erik Hebestreit
Erik Hebestreit
Photonics Laboratory, ETH Zurich
Bestätigte E-Mail-Adresse bei ethz.ch
Titel
Zitiert von
Zitiert von
Jahr
GHz rotation of an optically trapped nanoparticle in vacuum
R Reimann, M Doderer, E Hebestreit, R Diehl, M Frimmer, D Windey, ...
Physical review letters 121 (3), 033602, 2018
2272018
Sensing static forces with free-falling nanoparticles
E Hebestreit, M Frimmer, R Reimann, L Novotny
Physical review letters 121 (6), 063602, 2018
1132018
Conductive coupling of split ring resonators: a path to THz metamaterials with ultrasharp resonances
I Al-Naib, E Hebestreit, C Rockstuhl, F Lederer, D Christodoulides, ...
Physical review letters 112 (18), 183903, 2014
1052014
Controlling the net charge on a nanoparticle optically levitated in vacuum
M Frimmer, K Luszcz, S Ferreiro, V Jain, E Hebestreit, L Novotny
Physical Review A 95 (6), 061801, 2017
912017
Calibration and energy measurement of optically levitated nanoparticle sensors
E Hebestreit, M Frimmer, R Reimann, C Dellago, F Ricci, L Novotny
Review of Scientific Instruments 89 (3), 033111, 2018
622018
Measuring the internal temperature of a levitated nanoparticle in high vacuum
E Hebestreit, R Reimann, M Frimmer, L Novotny
Physical Review A 97 (4), 043803, 2018
582018
A cryogenic scattering-type scanning near-field optical microscope
HU Yang, E Hebestreit, EE Josberger, MB Raschke
Review of Scientific Instruments 84 (2), 023701, 2013
572013
The spectral shift between near-and far-field resonances of optical nano-antennas
C Menzel, E Hebestreit, S Mühlig, C Rockstuhl, S Burger, F Lederer, ...
Optics express 22 (8), 9971-9982, 2014
482014
Optical levitation and feedback cooling of a nanoparticle at subwavelength distances from a membrane
R Diehl, E Hebestreit, R Reimann, F Tebbenjohanns, M Frimmer, ...
Physical Review A 98 (1), 013851, 2018
402018
Thermal properties of levitated nanoparticles
E Hebestreit
ETH Zurich, 2017
142017
Extreme coupling: A route towards local magnetic metamaterials
C Menzel, E Hebestreit, R Alaee, M Albooyeh, S Mühlig, S Burger, ...
Physical Review B 89 (15), 155125, 2014
122014
A chemical nanoreactor based on a levitated nanoparticle in vacuum
F Ricci, MT Cuairan, AW Schell, E Hebestreit, RA Rica, N Meyer, ...
ACS nano 16 (6), 8677-8683, 2022
52022
Measuring gravity with optically levitated nanoparticles
E Hebestreit, M Frimmer, R Reimann, L Novotny
Novel Optical Materials and Applications, NoTu4J. 2, 2018
42018
Erratum: GHz Rotation of an Optically Trapped Nanoparticle in Vacuum [Phys. Rev. Lett. 121, 033602 (2018)]
F van der Laan, R Reimann, M Doderer, E Hebestreit, R Diehl, M Frimmer, ...
Physical Review Letters 126 (15), 159901, 2021
12021
Optical potential mapping with a levitated nanoparticle at sub-wavelength distances from a membrane
R Diehl, E Hebestreit, R Reimann, M Frimmer, F Tebbenjohanns, ...
arXiv preprint arXiv:1803.04917, 2018
12018
GHz Rotation of an Optically Trapped Nanoparticle in Vacuum (vol 121, 033602, 2018)
F van der Laan, R Reimann, M Doderer, E Hebestreit, R Diehl, M Frimmer, ...
PHYSICAL REVIEW LETTERS 126 (15), 2021
2021
Towards homogeneous magnetic metamaterials-a comprehensive multipole analysis
C Menzel, E Hebestreit, S Mühlig, S Burger, C Rockstuhl, F Lederer, ...
Proc. META'13, 502-503, 2013
2013
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