All ACMS Movies
ACMS Movie Catagories
|
All ACMS Movies
|
Sorted
ACMS Movie Catagories:
(ACMS Movie Catagories)
AtomInNanoCavity
AtomInNanoCavity/AboveStructure
AtomInNanoCavity/InsideStructure
BallisticPhotons
Bowtie
BroadAreaLaser
HiQNanoCavityPBG
NanoCavity
NanoWires
O-Waves
OpticalCollapse
OpticalTrap
PlasmonResonator
PlasmonResonator/MoreSampleMovies
PlasmonResonator/SingleCycleMovies
SelfFocus
SplitRingResonator
THG-Waves
X-Waves
ACMS Movies:
ACMS Movies by content:
Multiple vievs of electromagnetic quantities inside mode region [25MB]
Multiple views of radation pattern above nano cavity slab PBG [44MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
View of electromagnetic quantities inside mode region [2.5MB]
10fs pulse at 1.396micron propagation through a scattering medium
A close in view of a 250fs pulse hitting 3.0micron radius disk
Pulse propagation of 250fs pulse centered at 1.369micron
Close in view of single disk response to 10fs pulse
Whispering Gallery Mode excited on a single 3.0micron radius disk by 10fs pulse
10fs pulse pulse propagation through 3.0micron radius disk.
10fs Pulse propagation through a scattering medium
BallisticPhotons/MovieWholeDom250fsAt1369nm11Pct
Pulse propagation through a scattering medium
Pulse propagation through a scattering medium
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Near field structure and resonant behavior of metallic bowtie nano-structures
Broad Area Laser [3.2MB]
Broad Area Laser [4.8MB]
Energy difference with and without quantum dot [7.1MB]
Energy density dynamics around quantum dot in PBG nanocavity [0.9MB]
Energy density dynamics around nano cavity without quantum dot in nanocavity [0.9MB]
Time evolution of evenescent field above PBG slab [4.2MB]
Introduction movie to Photonic crystal structures [31MB]
Radiation pattern above a slab PBG nano cavity [2.1MB]
Energy density dynamics around quantum dot in PBG nanocavity [4.4MB]
Shows Adaptive mesh refinment grids around quantum dot [13MB]
Time series of the energy density in the half space above the structure [1.2MB]
The log of the time averaged local Poynting vector in the mode region [2.4MB]
The normalized energy density with and without the atom [1.6MB]
The electric and magnetic fields around a single metal nanowire at 560nm [20MB]
The electric field....
The electric and magnetic fields around two metal nanowires at 503nm [13MB]
The electric and magnetic fields around two metal nanowires at 560nm [13MB]
The electric and magnetic fields around two metal nanowires at 560nm [20MB]
The electric and magnetic fields around a single metal nanowire at 560nm [9.9MB]
The elliptic shaped texture of the spectrum around the fundamental frequency reflects the nature of the so-called linear O-waves
The elliptic shaped texture of the spectrum around the fundamental frequency reflects the nature of the so-called linear O-waves
The elliptic shaped texture of the spectrum around the fundamental frequency reflects the nature of the so-called linear O-waves
Shows temporal dynamics of optical collapse [3.5MB]
Shows temporal dynamics of optical collapse [4.6MB]
Shows temporal and spectral dynamics of optical collapse [5.4MB]
Shows temporal and spectral dynamics of optical collapse [8.3MB]
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
The time series of the intensity for the 3D quantum dot trap for balanced and unbalanced operation [1.2MB]
Spatial distribution of the microscopically computed force in 3D quantum dot nano-trap [1.2MB]
Line cut of Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Line cut of Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Assorted plasmon resonance movies of an isolated 20nm thick Gold spike structure in air.
Line cut of Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Line cut of Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Plasmon resonance of an isolated 20nm thick Gold spike structure in air.
Interplay between plasma defocussing and self-focussing leads to an apparent long propagation of ultrashort pulses in air.
Pulses of longer duration have their collapse halted due to Plasma generation.
The Ikeda map with diffraction produces complex patterns
Self-focussing leads towards collapse. Normal group velocity dispersion will split a collapsing pulse
SplitRingResonator/Montg
SplitRingResonator/Montg.png
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Resonance of an 20nm thick Gold Split Ring Resonator in air.
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Third-harmonic (TH) generation
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
Animation illustrating the evolution of the far-field spectrum filling-up the union of the phase-matched regions.
