5 research outputs found
Versatile Polarization Generation with an Aluminum Plasmonic Metasurface
All forms of light
manipulation rely on light–matter interaction, the primary
mechanism of which is the modulation of its electromagnetic fields
by the localized electromagnetic fields of atoms. One of the important
factors that influence the strength of interaction is the polarization
of the electromagnetic field. The generation and manipulation of light
polarization have been traditionally accomplished with bulky optical
components such as waveplates, polarizers, and polarization beam splitters
that are optically thick. The miniaturization of these devices is
highly desirable for the development of a new class of compact, flat,
and broadband optical components that can be integrated together on
a single photonics chip. Here we demonstrate, for the first time,
a reflective metasurface polarization generator (MPG) capable of producing
light beams of any polarizations all from a linearly polarized light
source with a single optically thin chip. Six polarization light beams
are achieved simultaneously including four linear polarizations along
different directions and two circular polarizations, all conveniently
separated into different reflection angles. With the Pancharatnam–Berry
phase-modulation method, the MPG sample was fabricated with aluminum
as the plasmonic metal instead of the conventional gold or silver,
which allowed for its broadband operation covering the entire visible
spectrum. The versatility and compactness of the MPG capable of transforming
any incident wave into light beams of arbitrary polarizations over
a broad spectral range are an important step forward in achieving
a complete set of flat optics for integrated photonics with far-reaching
applications
Visible Metasurfaces for On-Chip Polarimetry
Measuring
the polarization state of light and determining the optical
properties of chiral materials are inherently complex issues because
of the requirement of consequential measurements between different
orthogonal states of polarization. Here, we introduce an on-chip polarimetry
based on the visible metasurfaces for addressing the issue of polarization
analysis with compact components. We demonstrate integrated metasurface
chips can effectively determine a set of Stokes parameters covering
a broad wave-band at visible light. For the proof of concept, the
optical properties of chiral materials are measured using our proposed
device, while experimental verifications are convincing by comparing
with the data obtained from commercial ellipsometry
High-Efficiency Broadband Anomalous Reflection by Gradient Meta-Surfaces
We combine theory and experiment to demonstrate that
a carefully
designed gradient meta-surface supports high-efficiency anomalous
reflections for near-infrared light following the generalized Snell’s
law, and the reflected wave becomes a bounded surface wave as the
incident angle exceeds a critical value. Compared to previously fabricated
gradient meta-surfaces in infrared regime, our samples work in a shorter
wavelength regime with a broad bandwidth (750–900 nm), exhibit
a much higher conversion efficiency (∼80%) to the anomalous
reflection mode at normal incidence, and keep light polarization unchanged
after the anomalous reflection. Finite-difference-time-domain (FDTD)
simulations are in excellent agreement with experiments. Our findings
may lead to many interesting applications, such as antireflection
coating, polarization and spectral beam splitters, high-efficiency
light absorbers, and surface plasmon couplers
High-Efficiency Broadband Meta-Hologram with Polarization-Controlled Dual Images
Holograms, the optical devices to
reconstruct predesigned images,
show many applications in our daily life. However, applications of
hologram are still limited by the constituent materials and therefore
their working range is trapped at a particular electromagnetic region.
In recent years, the metasurfaces, an array of subwavelength antenna
with varying sizes, show the abilities to manipulate the phase of
incident electromagnetic wave from visible to microwave frequencies.
Here, we present a reflective-type and high-efficiency meta-hologram
fabricated by metasurface for visible wavelength. Using gold cross
nanoantennas as building blocks to construct our meta-hologram devices
with thickness ∼ λ/4, the reconstructed images of meta-hologram
show polarization-controlled dual images with high contrast, functioning
for both coherent and incoherent light sources within a broad spectral
range and under a wide range of incidence angles. The flexibility
demonstrated here for our meta-hologram paves the road to a wide range
of applications related to holographic images at arbitrary electromagnetic
wave region
High-Efficiency Broadband Meta-Hologram with Polarization-Controlled Dual Images
Holograms, the optical devices to
reconstruct predesigned images,
show many applications in our daily life. However, applications of
hologram are still limited by the constituent materials and therefore
their working range is trapped at a particular electromagnetic region.
In recent years, the metasurfaces, an array of subwavelength antenna
with varying sizes, show the abilities to manipulate the phase of
incident electromagnetic wave from visible to microwave frequencies.
Here, we present a reflective-type and high-efficiency meta-hologram
fabricated by metasurface for visible wavelength. Using gold cross
nanoantennas as building blocks to construct our meta-hologram devices
with thickness ∼ λ/4, the reconstructed images of meta-hologram
show polarization-controlled dual images with high contrast, functioning
for both coherent and incoherent light sources within a broad spectral
range and under a wide range of incidence angles. The flexibility
demonstrated here for our meta-hologram paves the road to a wide range
of applications related to holographic images at arbitrary electromagnetic
wave region