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â–º Submitted Articles 23
From Hybrid Quantum - Classical Photonic Neural Networks

Hybrid Quantum-Classical Photonic Neural Networks

[]
Tristan Austin, Simon Bilodeau, Andrew Hayman, Nir Rotenberg, Bhavin Shastri
From Roadmap on Neuromorphic Photonics

Roadmap on Neuromorphic Photonics

[]
D. Brunner, et al.,
â–º 2024 112
Cryogenic microphotoluminescence spectra from nanowire quantum dots

Direct observation of non-linear phase shift induced by a single quantum emitter in a waveguide

[]15, 7583 (2024)
M.J.R. Staunstrup, A. Tiranov, Y. Wang, S. Scholz, A.D. Wieck, A. Ludwig, L. Midolo, N. Rotenberg, P. Lodahl and H. Le Jeannic
A quantum dot acts as a reconfigurable phase shifter

Reconfigurable quantum photonic circuits based on quantum dots

[]13, 2951 (2024)
A. McCaw, J. Ewaniuk, B.J. Shastri, and N. Rotenberg
Group V switching sequence during growth of the dot-in-a-rod section of the nanowire core. Light (dark) grey region indicates rod (dot) growth. Inset shows a transmission electron microscopy image of the corresponding section. The scale bar indicates 20 nm.

Single photon emission in the telecom C-band from nanowire-based quantum dots

[] 124, 044006 (2024)
Andrew N. Wakileh, Lingxi Yu, DoÄŸa Dokuz, Sofiane Haffouz, Xiaohua Wu, Jean Lapointe, David B. Northeast, Robin L. Williams, Nir Rotenberg, Philip J. Poole, Dan Dalacu
â–º 2023 1 2
A new system to independently control two quantum dots coupled to a single photonic waveguide

Independent electrical control of two quantum dots coupled through a photonic crystal waveguide

[] 131, 033606 (2023)
X.-L. Chu, C. Papon, N. Bart, A.D Wieck, A. Ludwig, L. Midolo, N. Rotenberg and P. Lodahl
Do realistic quantum photonic neural networks work? We say yes

Imperfect quantum photonic neural networks

[] 6, 2200125 (2023)
J. Ewaniuk, J. Carolan, B.J. Shastri and N. Rotenberg
â–º 2022 1 2 3 4
If two emitters are coupled, they may response much more slowly (subradiant) or quickly (superradiant) then if they were alone, and this combined response is represented by the Green's tensor (shown here for a photonic crystal waveguide)

Sub-radiant states for imperfect quantum emitters coupled by a nanophotonic waveguide

[] 106, 053702 (2022)
X.-L. Chu, V. Angelopoulou, P. Lodahl and N. Rotenberg
2-time correlation function for 2 photons in a pulse simultaneously scattering from a quantum dot

Dynamical photon-photon interaction mediated by a quantum emitter

[] 18, 1191 (2022)
H. Le Jeannic, A. Tiranov, J. Carolan, T. Ramos, Y. Wang, M.H. Appel, S. Scholz, A.D. Wieck, A. Ludwig, N. Rotenberg, L. Midolo, J.J. García-Ripoll, A. S. Sørensen and P. Lodahl

Featured: News & Views () and phys.org ()
How much can a topological photonic waveguide enhance directional (chiral interactions)? Here, we show the answer, using an efficient, inverse optimization routine.

Optimizing the chiral Purcell factor for unidirectional single photon emitters in  topological photonic crystal waveguides using inverse design

[] 106, 033514 (2022)
E. Nussbaum, N. Rotenberg and S. Hughes
Directionality and emission enhancement of broken symmetry and topological photonic crystal waveguides

Chiral quantum optics in broken-symmetry and topological photonic crystal waveguides

[] 4, 023082 (2022)
N. Hauff, H. Le Jeannic, P. Lodahl, S. Hughes and N. Rotenberg
â–º 2021 1 2
SEM of an Integrated whispering-gallery-mode resonator with embedded quantum dots

An integrated whispering-gallery-mode resonator for solid-state coherent quantum photonics

[] 21, 8707 (2021)
A. Brooks, X.-L. Chu, Z. Liu, R. Schott, A. Ludwig, A.D. Wieck, L. Midolo, P. Lodahl and N. Rotenberg
Experimental reconstruction of the few-photon nonlinear scattering matrix from a single quantum dot in a nanophotonic waveguide

Experimental reconstruction of the few-photon nonlinear scattering matrix from a single quantum dot in a nanophotonic waveguide

[] 126, 023603 (2021)
H. Le Jeannic, T. Ramos, S.F. Simonsen, T. Pregnolato, Z. Liu, R. Schott, A.D. Wieck, A. Ludwig, N. Rotenberg, J. García-Ripoll and P. Lodahl
â–º 2020 1 2
from Advanced Quantum Technologies 2020 paper

Lifetimes and quantum efficiencies of quantum dots deterministically positioned in photonic crystal waveguides

[] , 2000026 (2020)
X.-L. Chu, T. Pregnolato, R. Schott, A.D. Wieck, A. Ludwig, N. Rotenberg and P. Lodahl
From article Deterministic positioning of nanophotonic waveguides around single self-assembled quantum dots

Deterministic positioning of nanophotonic waveguides around single self-assembled quantum dots

[] 5, 086101 (2020)
T. Pregnolato, X.-L. Chu, T. Schröder, R. Schott, A.D. Wieck, A. Ludwig, P. Lodahl and N. Rotenberg
â–º 2019 1 2 3
from the Coherent nonlinear optics of quantum emitters in nanophotonic waveguides publication

Coherent nonlinear optics of quantum emitters in nanophotonic waveguides (Review)

8, 1641 (2019)
P. Türschmann, H. Le Jeannic, S.F. Simonsen, H.R. Haakh, S. Götzinger, V. Sandoghdar, P. Lodahl and N. Rotenberg
from Chiral emission into nanophotonic resonators publication

Chiral emission into nanophotonic resonators

[] 6, 961 (2019)
D.M. Cano, H.R. Haakh, and N. Rotenberg
from A full vectorial mapping of nanophotonic near fields

A full vectorial mapping of nanophotonic near fields

8, 28 (2019)
B. le Feber, J.E. Sipe, L. Kuipers, and N. Rotenberg
â–º 2018 1
article from Quantum optics with near-lifetime-limited quantum-dot transitions in a nanophotonic waveguide

Quantum optics with near-lifetime-limited quantum-dot transitions in a nanophotonic waveguide

[] 18, 1801 (2018)
H. Thyrrestrup, G. Kiršanskė, H. Le Jeannic, T. Pregnolato, L. Zhai, L. Raahauge, L. Midolo, N. Rotenberg, A. Javadi, R. Schott, A, D. Wieck, A. Ludwig, M.C. Löbl, I. Söllner, R.J. Warburton and P. Lodahl
â–º 2017 1 2 3
from article Chip-based all-optical control of single molecules coherently coupled to a nanoguide

Chip-based all-optical control of single molecules coherently coupled to a nanoguide

17, 4791 (2017)
P. Türschmann, N. Rotenberg, J. Renger, I. Harder, O. Lohse, T. Utikal, S. Götzinger and V. Sandoghdar
from article Core-shell plasmonic nanohelices

Core-shell plasmonic nanohelices

4, 1858 (2017)
D. Kosters, A. de Hoogh, H. Zeijlemaker, H. Acar, N. Rotenberg and L. Kuipers
from article Small slot waveguide rings for on-chip quantum optical circuits

Small slot waveguide rings for on-chip quantum optical circuits

25, 5397 (2017)
N. Rotenberg, P. Türschmann, H.R. Haakh, D.M. Cano, S. Götzinger and V. Sandoghdar
â–º 2016 1
from article Harmonic generation from surface plasmon polaritons on single nanowires

Harmonic generation from surface plasmon polaritons on single nanowires (ACS Editor’s Choice Article)

3, 1446 (2016)
A. de Hoogh, A. Opheij, M. Wulf, N. Rotenberg and L. Kuipers
â–º 2015 1 2 3 4
from article Tracking nanoscale electric and magnetic singularities through three-dimensional space

Tracking nanoscale electric and magnetic singularities through three-dimensional space

2, 540 (2015)
N. Rotenberg, B. le Feber, T. D. Visser and L. Kuipers
from article creating and controlling polarization singularities in plasmonic field

Creating and controlling polarization singularities in plasmonic fields (Invited)

Photonics 2, 553 (2015)
A. de Hoogh, T.D. Visser, L. Kuipers and N. Rotenberg
from article Nanophotonic control of circular dipole emission

Nanophotonic control of circular dipole emission

6, 6695 (2015)
B. le Feber, N. Rotenberg and L. Kuipers
from article Triggering extreme events at the nanoscale in photonic seas

Triggering extreme events at the nanoscale in photonic seas (Cover Article)

11, 358 (2015)
C. Liu, R. van der Wel, N. Rotenberg, L. Kuipers, T.F. Krauss, A. di Falco, A. Fratalocchi
â–º 2014 1 2 3 4 5
from article Mapping nanoscale light field

Mapping nanoscale light fields (Review)

8, 918 (2014)
N. Rotenberg and L. Kuipers
from article Ultrafast photonics on gold nanowires: confinement, dispersion and pulse propagation

Ultrafast photonics on gold nanowires: confinement, dispersion and pulse propagation

1, 1173 (2014)
M. Wulf, A. de Hoogh, N. Rotenberg, and L. Kuipers
from article Optical singularities in plasmonic fields near single subwavelength holes

Optical singularities in plasmonic fields near single subwavelength holes (Invited; Selected IOP Highlight of 2014)

16, 114004 (2014)
A. de Hoogh, N. Rotenberg, and L. Kuipers
from article Model symmetries at the nanoscale: a route towards a complete vectorial near-field mapping

Model symmetries at the nanoscale: a route towards a complete vectorial near-field mapping

39, 2802 (2014)
B. le Feber, N. Rotenberg, D. van Oosten, and L. Kuipers
from article Simultaneous measurement of nanoscale electric and magnetic optical fields

Simultaneous measurement of nanoscale electric and magnetic optical fields

8, 43 (2014)
B. le Feber, N. Rotenberg, D.M. Beggs and L. Kuipers
â–º 2013 from article Magnetic and electric response of single subwavelength holes 2 3 4
from article Magnetic and electric response of single subwavelength holes

Magnetic and electric response of single subwavelength holes

88, 241408(R) (2013)
N. Rotenberg, T. L. Krijger, B. le Feber, M. Spasenović, F. J. García de Abajo, and L. Kuipers
from article Ultracompact (3 µm) silicon slow-light optical modulator

Ultracompact (3 µm) silicon slow-light optical modulator

3, 3546 (2013)
A. Opheij, N. Rotenberg, D.M. Beggs, I.H. Rey, T.F. Krauss and L. Kuipers
from article Unraveling nonlinear spectral evolution using nanoscale photonic near-field point-to-point measurements

Unraveling nonlinear spectral evolution using nanoscale photonic near-field point-to-point measurements

13, 5858 (2013)
M. Wulf, D.M. Beggs, N. Rotenberg and L. Kuipers
from article Resonant coupling from a new angle: coherent control through geometry

Resonant coupling from a new angle: coherent control through geometry

21, 16504 (2013)
N. Rotenberg, D. M. Beggs, J. E. Sipe, and L. Kuipers
â–º 2012 from article Ultrafast tunable optical delay line based on indirect photonic transitions from article Plasmon scattering from single subwavelength holes
from article Ultrafast tunable optical delay line based on indirect photonic transitions

Ultrafast tunable optical delay line based on indirect photonic transitions

108, 213901 (2012)
D.M. Beggs, I.H. Rey, T. Kampfrath, N. Rotenberg, L. Kuipers and T.F. Krauss
from article Plasmon scattering from single subwavelength holes

Plasmon scattering from single subwavelength holes

108, 127402 (2012)
N. Rotenberg, M. Spasenović, T.L. Krijger, B. le Feber, F.J. García de Abajo and L. Kuipers
â–º 2011 from article Exploiting long-range order in quasiperiodic structures for broadband plasmonic excitation from article All-optical ultrafast control of beaming through a single sub-wavelength aperture in a metal film from article An analytic model of plasmonic coupling: surface relief gratings
from article Exploiting long-range order in quasiperiodic structures for broadband plasmonic excitation

Exploiting long-range order in quasiperiodic structures for broadband plasmonic excitation

98, 201108 (2011)
B. le Feber, J. Cesario, H. Zeijlemaker, N. Rotenberg and L. Kuipers
from article All-optical ultrafast control of beaming through a single sub-wavelength aperture in a metal film

All-optical ultrafast control of beaming through a single sub-wavelength aperture in a metal film

19, 7856 (2011)
M.A. Swillam, N. Rotenberg and H.M. van Driel
from article An analytic model of plasmonic coupling: surface relief gratings

An analytic model of plasmonic coupling: surface relief gratings

83, 045416 (2011)
N. Rotenberg and J.E. Sipe
â–º 2010 from article Ultrafast silicon-based active plasmonics at telecom wavelengths from article Ultrafast all-optical coupling of light to surface plasmon polaritons on plain metal surfaces
from article Ultrafast silicon-based active plasmonics at telecom wavelengths

Ultrafast silicon-based active plasmonics at telecom wavelengths

18, 19761 (2010)
J.N. Caspers, N. Rotenberg and H.M. van Driel
from article Ultrafast all-optical coupling of light to surface plasmon polaritons on plain metal surfaces

Ultrafast all-optical coupling of light to surface plasmon polaritons on plain metal surfaces

105, 017402 (2010)
N. Rotenberg, M. Betz, and H.M. van Driel
â–º 2009 from article Tunable ultrafast control of plasmonic coupling to gold films
from article Tunable ultrafast control of plasmonic coupling to gold films

Tunable ultrafast control of plasmonic coupling to gold films

80, 245420 (2009)
N. Rotenberg, M. Betz and H.M. van Driel
► 2008 from article Three photon absorption in silicon for 2300 – 3300 nm from article Ultrafast control of grating-assisted light coupling to surface plasmons
from article Three photon absorption in silicon for 2300 – 3300 nm

Three photon absorption in silicon for 2300 – 3300 nm

93, 131102 (2008)
S. Pearl, N. Rotenberg and H.M. van Driel
from article Ultrafast control of grating-assisted light coupling to surface plasmons

Ultrafast control of grating-assisted light coupling to surface plasmons

33, 2137 (2008)
N. Rotenberg, M. Betz and H.M. van Driel
â–º 2007 from article Two-Photon Absorption and Kerr coefficient of Silicon for 850-2200 nm from article Nonlinear absorption in Au films: Role of thermal effects
from article Two-Photon Absorption and Kerr coefficient of Silicon for 850-2200 nm

Two-Photon Absorption and Kerr coefficient of Silicon for 850-2200 nm

90, 191104 (2007)
A.D. Bristow, N. Rotenberg and H.M. van Driel
from article Nonlinear absorption in Au films: Role of thermal effects

Nonlinear absorption in Au films: Role of thermal effects

75, 155426 (2007)
N. Rotenberg, A.D. Bristow, M. Pfeiffer, M. Betz and H.M. van Driel