207 research outputs found
Optical spin-to-orbital angular momentum conversion in ultra-thin metasurfaces with arbitrary topological charges
Orbital angular momentum associated with the helical phase-front of optical
beams provides an unbounded \qo{space} for both classical and quantum
communications. Among the different approaches to generate and manipulate
orbital angular momentum states of light, coupling between spin and orbital
angular momentum allows a faster manipulation of orbital angular momentum
states because it depends on manipulating the polarisation state of light,
which is simpler and generally faster than manipulating conventional orbital
angular momentum generators. In this work, we design and fabricate an
ultra-thin spin-to-orbital angular momentum converter, based on plasmonic
nano-antennas and operating in the visible wavelength range that is capable of
converting spin to an arbitrary value of OAM . The nano-antennas are
arranged in an array with a well-defined geometry in the transverse plane of
the beam, possessing a specific integer or half-integer topological charge .
When a circularly polarised light beam traverses this metasurface, the output
beam polarisation switches handedness and the OAM changes in value by per photon. We experimentally demonstrate values ranging
from to with conversion efficiencies of . Our
ultra-thin devices are integratable and thus suitable for applications in
quantum communications, quantum computations and nano-scale sensing.Comment: 4 pages, 3 figures - submitted
Measurement of the Photon-Plasmon Coupling Phase
Scattering processes have played a crucial role in the development of quantum
theory. In the field of optics, scattering phase shifts have been utilized to
unveil interesting forms of light-matter interactions. Here, we investigate the
mode-coupling phase of single photons to surface plasmon polaritons in a
quantum plasmonic tritter. We observe that the coupling process induces a phase
jump that occurs when photons scatter into surface plasmons and vice versa.
This interesting coupling phase dynamics is of particular relevance for quantum
plasmonic experiments. Furthermore, it is demonstrated that this photon-plasmon
interaction can be modeled through a quantum-mechanical tritter. We show that
the visibility of a double-slit and a triple-slit interference patterns are
convenient observables to characterize the interaction at a slit and determine
the coupling phase. Our accurate and simple model of the interaction, validated
by simulations and experiments, has important implications not only for quantum
plasmonic interference effects, but is also advantageous to classical
applications
Individual Nanostructures in an Epsilon-Near-Zero Material Probed with 3D-Sculpted Light
Epsilon-near-zero (ENZ) materials, i.e., materials with vanishing real part
of the permittivity, have become an increasingly desirable platform for
exploring linear and nonlinear optical phenomena in nanophotonic and on-chip
environments. ENZ materials inherently enhance electric fields for properly
chosen interaction scenarios, host extreme nonlinear optical effects, and lead
to other intriguing phenomena. To date, studies in the optical domain mainly
focused on nanoscopically thin films of ENZ materials and their interaction
with light and other nanostructured materials. Here, the optical response of
individual nanostructures milled into an ENZ material are explored both
experimentally and numerically. For the study, 3D structured light beams are
employed, allowing for the full utilization of polarization-dependent field
enhancements enabled by a tailored illumination and a vanishing permittivity.
This study reveals the underlying intricate interaction mechanisms and showcase
the polarization-dependent controllability, paving the way towards experiments
in the nonlinear optical regime where the presented effects will enable
polarization-controlled nonlinear refractive index based ultra-fast switching
on the single nanostructure level.Comment: 7 pages, 8 figure
Modern cosmologies from empty Kaluza-Klein solutions in 5D
We show that the empty five-dimensional solutions of
Davidson-Sonnenschtein-Vozmediano, {\em Phys. Rev.} {\bf D32} (1985)1330, in
the "old" Kaluza-Klein gravity, under appropriate interpretation can generate
an ample variety of cosmological models in 4D, which include the
higher-dimensional modifications to general relativity predicted by "modern"
versions of noncompactified 5D gravity as, e.g., induced-matter and braneworld
theories. This is the first time that these solutions are investigated in a
systematic way as embeddings for cosmological models in 4D. They provide a
different formulation, which is complementary to the approaches used in current
versions of 5D relativity.Comment: Accepted for publication in JHE
Multiparticle quantum plasmonics
A single photon can be coupled to collective charge oscillations at the interfaces between metals and dielectrics forming a single surface plasmon. The electromagnetic near-fields induced by single surface plasmons offer new degrees of freedom to perform an exquisite control of complex quantum dynamics. Remarkably, the control of quantum systems represents one of the most significant challenges in the field of quantum photonics. Recently, there has been an enormous interest in using plasmonic systems to control multiphoton dynamics in complex photonic circuits. In this review, we discuss recent advances that unveil novel routes to control multiparticle quantum systems composed of multiple photons and plasmons. We describe important properties that characterize optical multiparticle systems such as their statistical quantum fluctuations and correlations. In this regard, we discuss the role that photon-plasmon interactions play in the manipulation of these fundamental properties for multiparticle systems. We also review recent works that show novel platforms to manipulate many-body light-matter interactions. In this spirit, the foundations that will allow nonexperts to understand new perspectives in multiparticle quantum plasmonics are described. First, we discuss the quantum statistical fluctuations of the electromagnetic field as well as the fundamentals of plasmonics and its quantum properties. This discussion is followed by a brief treatment of the dynamics that characterize complex multiparticle interactions. We apply these ideas to describe quantum interactions in photonic-plasmonic multiparticle quantum systems. We summarize the state-of-the-art in quantum devices that rely on plasmonic interactions. The review is concluded with our perspective on the future applications and challenges in this burgeoning field
Polarization shaping for control of nonlinear propagation
We study the nonlinear optical propagation of two different classes of
space-varying polarized light beams -- radially symmetric vector beams and
Poincar\'e beams with lemon and star topologies -- in a rubidium vapour cell.
Unlike Laguerre-Gauss and other types of beams that experience modulational
instabilities, we observe that their propagation is not marked by beam breakup
while still exhibiting traits such as nonlinear confinement and self-focusing.
Our results suggest that by tailoring the spatial structure of the
polarization, the effects of nonlinear propagation can be effectively
controlled. These findings provide a novel approach to transport high-power
light beams in nonlinear media with controllable distortions to their spatial
structure and polarization properties.Comment: 5 pages, and 4 figure
Generating optical orbital angular momentum at visible wavelengths using a plasmonic metasurface
The authors acknowledge the support of the Canada Excellence Research Chairs Program.Light beams with a helical phase-front possess orbital angular momentum along their direction of propagation in addition to the spin angular momentum that describes their polarisation. Until recently, it was thought that these two ‘rotational’ motions of light were largely independent and could not be coupled during light–matter interactions. However, it is now known that interactions with carefully designed complex media can result in spin-to-orbit coupling, where a change of the spin angular momentum will modify the orbital angular momentum and vice versa. In this work, we propose and demonstrate that the birefringence of plasmonic nanostructures can be wielded to transform circularly polarised light into light carrying orbital angular momentum. A device operating at visible wavelengths is designed from a space-variant array of subwavelength plasmonic nano-antennas. Experiment confirms that circularly polarised light transmitted through the device is imbued with orbital angular momentum of ±2ħ (with conversion efficiency of at least 1%). This technology paves the way towards ultrathin orbital angular momentum generators that could be integrated into applications for spectroscopy, nanoscale sensing and classical or quantum communications using integrated photonic devices.Publisher PDFPeer reviewe
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