12 research outputs found
All-optical atom surface traps implemented with one-dimensional planar diffractive microstructures
We characterize the loading, containment and optical properties of
all-optical atom traps implemented by diffractive focusing with one-dimensional
(1D) microstructures milled on gold films. These on-chip Fresnel lenses with
focal lengths of the order of a few hundred microns produce
optical-gradient-dipole traps. Cold atoms are loaded from a mirror
magneto-optical trap (MMOT) centered a few hundred microns above the gold
mirror surface. Details of loading optimization are reported and perspectives
for future development of these structures are discussed.Comment: 7 pages, 15 figure
Surface-wave interferometry on single subwavelength slit-groove structures fabricated on gold films
We apply the technique of far-field interferometry to measure the properties
of surface waves generated by two-dimensional (2D) single subwavelength
slit-groove structures on gold films. The effective surface index of refraction
measured for the surface wave propagating over a distance of more than 12
microns is determined to be 1.016 with a measurement uncertainty of 0.004, to
within experimental uncertainty of the expected bound surface plasmon-polariton
(SPP) value for a Au/Air interface of 1.018. We compare these measurements to
finite-difference-time-domain (FDTD) numerical simulations of the optical field
transmission through these devices. We find excellent agreement between the
measurements and the simulations for the surface index of refraction. The
measurements also show that the surface wave propagation parameter exhibits
transient behavior close to the slit, evolving smoothly from greater values
asymptotically toward the value expected for the SPP over the first 2-3 microns
of slit-groove distance. This behavior is confirmed by the FDTD simulations
Surface wave generation and propagation on metallic subwavelength structures measured by far-field interferometry
Transmission spectra of metallic films or membranes perforated by arrays of
subwavelength slits or holes have been widely interpreted as resonance
absorption by surface plasmon polaritons (SPPs). Alternative interpretations
involving evanescent waves diffracted on the surface have also been proposed.
These two approaches lead to divergent predictions for some surface wave
properties. Using far-field interferometry, we have carried out a series of
measurements on elementary one-dimensional (1-D) subwavelength structures with
the aim of testing key properties of the surface waves and comparing them to
predictions of these two points of view
Optical response of nanostructured surfaces: experimental investigation of the composite diffracted evanescent wave model
The past decade has seen a rapidly developing interest in the response of subwavelength-structured surfaces to optical excitation. Many studies have interpreted the optical coupling to the surface in terms of surface plasmon polaritons, but recently another approach involving diffraction of surface evanescent waves, the Composite Diffractive Evanescent Wave (CDEW) model has been proposed. We present here a series of measurements on very simple one-dimensional (1-D) subwavelength structures with the aim of testing key properties of the surface waves predicted by the CDEW model
The optical response of nanostructured surfaces and the composite diffracted evanescent wave model
Investigations of the optical response of subwavelength-structure arrays milled into thin metal films have revealed surprising phenomena, including reports of unexpectedly high transmission of light. Many studies have interpreted the optical coupling to the surface in terms of the resonant excitation of surface plasmon polaritons (SPPs), but other approaches involving composite diffraction of surface evanescent waves (CDEW) have also been proposed. Here we present a series of measurements on very simple one-dimensional subwavelength structures to test the key properties of the surface waves, and compare them to the CDEW and SPP models. We find that the optical response of the silver metal surface proceeds in two steps: a diffractive perturbation in the immediate vicinity (2–3 mu m) of the structure, followed by excitation of a persistent surface wave that propagates over tens of micrometres. The measured wavelength and phase of this persistent wave are significantly shifted from those expected for resonance excitation of a conventional SPP on a pure silver surface
Surface quality and surface waves on subwavelength-structured silver films
We analyze the physical-chemical surface properties of single-slit, single-groove subwavelength-structured silver films with high-resolution transmission electron microscopy and calculate exact solutions to Maxwell’s equations corresponding to recent far-field interferometry experiments using these structures. Contrary to a recent suggestion the surface analysis shows that the silver films are free of detectable contaminants. The finite-difference time-domain calculations, in excellent agreement with experiment, show a rapid fringe amplitude decrease in the near zone (slit-groove distance out to 3–4 wavelengths). Extrapolation to slit-groove distances beyond the near zone shows that the surface wave evolves to the expected bound surface plasmon polariton (SPP). Fourier analysis of these results indicates the presence of a distribution of transient, evanescent modes around the SPP that dephase and dissipate as the surface wave evolves from the near to the far zone
Analysis of surface waves generated on subwavelength-structured silver films
Using transmission electron microscopy (TEM) to analyse the physical-chemical
surface properties of subwavlength structured silver films and
finite-difference time-domain (FDTD) numerical simulations of the optical
response of these structures to plane-wave excitation, we report on the origin
and nature of the persistent surface waves generated by a single slit-groove
motif and recently measured by far-field optical interferometry. The surface
analysis shows that the silver films are free of detectable oxide or sulfide
contaminants, and the numerical simulations show very good agreement with the
results previously reported.Comment: 9 Figure
Champs optiques issus de structures sub-longueur d'onde
Nous présentons les résultats de nos études de la réponse
optique de structures sub-longueur d'onde gravées sur des films
d'argent. Nous avons réalisé des mesures de l'intensité
transmise et des spectres angulaires d'Ă©mission de ces structures
en fonction de leur géométrie (forme des motifs et distance
entre ceux-ci). Les résultats nous permettent de caractériser en
phase, amplitude et longueur d'onde le champ Ă©vanescent Ă
l'interface air/métal
The optical response of nanostructured surfaces and the composite diffracted evanescent wave model
Investigations of the optical response of subwavelength-structure arrays milled into thin metal films have revealed surprising phenomena, including reports of unexpectedly high transmission of light. Many studies have interpreted the optical coupling to the surface in terms of the resonant excitation of surface plasmon polaritons (SPPs), but other approaches involving composite diffraction of surface evanescent waves (CDEW) have also been proposed. Here we present a series of measurements on very simple one-dimensional subwavelength structures to test the key properties of the surface waves, and compare them to the CDEW and SPP models. We find that the optical response of the silver metal surface proceeds in two steps: a diffractive perturbation in the immediate vicinity (2–3µ m) of the structure, followed by excitation of a persistent surface wave that propagates over tens of micrometres. The measured wavelength and phase of this persistent wave are significantly shifted from those expected for resonance excitation of a conventional SPP on a pure silver surface