href="#fb3_img_img_63553961-c6a7-5d82-9d9f-098f8398445f.png" alt="images"/> ) as a function of the extern...Figure 8.13 Second harmonic evolution for KNSBN:Ti for the same sample and exp...Figure 8.14 Evolution of the
accounting on self‐diffraction effects as de...Figure 8.15 Two‐wave mixing experiment in a photorefractive GaAs intrinsic cry...Figure 8.16 Second harmonic response curves for an undoped semi‐insulating GaA...Figure 8.17 Two‐wave mixing experiment in a photorefractive GaAs intrinsic cry...Figure 8.18 Two‐wave mixing experiment in a photorefractive GaAs intrinsic cry...Figure 8.19 Plot of the first
(Eq. 8.76) and second
(Eq. 8.78) harmonic te...Figure 8.20 Experimental setup for the generation and measurement of running h...Figure 8.21 Diffraction efficiency (left) and
(right) as a function of Kv co...Figure 8.22 Diffraction efficiency (left) and
(right) as a function of Kv co...Figure 8.23 Diffraction efficiency
experimental data (spots) as a function o...Figure 8.24
experimental data (spots) as a function of
for the same condit...Figure 8.25 Holographic photoelectromotive force current setup schema: a laser...Figure 8.26
(in arbitrary units) as a function of the vibration amplitude
...Figure 8.27 Computed
(in arbitrary units) as a function of
in rad for a fi...Figure 8.28 First harmonic component of the holographic current
data (spots)...Figure 8.29 First harmonic component of the holographic current
data (spots)...Figure 8.30
data (spots) plotted as a function of
, for
rad: Ce‐doped BTO...
9 Chapter 9Figure 9.1 Typical time evolution of the
and
signals (dots) at the initial...Figure 9.2 Computed initial
versus applied electric field data (spots) in
....Figure 9.3 Output phase‐shift
versus applied electric field (
) data (circle...Figure 9.4 Fringe‐locked running hologram speed versus applied electric field ...Figure 9.5 Fringe‐locked running hologram experiment: frequency detuning
(me...Figure 9.6 Fringe‐locked running hologram experiment on undoped
crystal usin...Figure 9.7
and
experimentally measured as function of
on an undoped
cr...Figure 9.8 3D plotting of experimentally measured
and
as function of
fro...Figure 9.9 3D surface plotting of
and
as function of
from Eq. 9.19 with ...Figure 9.10 Characterization of reduced
:Fe (labeled LNB3): self‐stabilized h...Figure 9.11Figure 9.11 Characterization of reduced
:Fe (labeled LNB5): self‐s...Figure 9.12 Characterization of oxidized
:Fe (labeled LNB1): self‐stabilized ...
10 Chapter 10Figure 10.1 Schematic diagram of the experimental holographic setup: PBS: pola...Figure 10.2Figure 10.2 (a) Lateral view of the holographic setup: CCD camera (...Figure 10.3 Simplified schema showing the distribution of incident light (
) b...Figure 10.4 Optimization of the target illumination:
, diffracted reference b...Figure 10.5 Loudspeaker membrane (left) driven at 3.0 kHz and analyzed by the ...Figure 10.6 Amplitude of vibration at a point of local maximum in the membrane...Figure 10.7 Amplitude of vibration at two different points of local maximum in...Figure 10.8 Time‐average holographic interferometry pattern of a thin phosphor...Figure 10.9Figure 10.9 Time‐average holographic interferometry pattern of a th...Figure 10.10 Time‐average holographic interferometry pattern of a thin phospho...Figure 10.11 Double exposure holographic interferometry of a tilted rigid plat...Figure 10.12 Double exposure holographic interferometry of a rigid plate that ...Figure 10.13 Double exposure holographic interferometry of a rigid plate that ...
11 Chapter 11Figure 11.1 Experimental setup: S: massive copper cylinder with temperature‐co...Figure 11.2 Evolution of
and
during high temperature self‐stabilized holog...Figure 11.3 Diffraction efficiency of the overall grating during white‐light d...
href="#fb3_img_img_63553961-c6a7-5d82-9d9f-098f8398445f.png" alt="images"/> ) as a function of the extern...Figure 8.13 Second harmonic evolution for KNSBN:Ti for the same sample and exp...Figure 8.14 Evolution of the 
