alt="images"/> ) as...Figure 6.20 Computed evolution of
(
),
(
) in arbitrary units, and
(
) a...Figure 6.21 Self‐stabilized recording in the less‐oxidized crystal (sample LNB...Figure 6.22 Self‐stabilized recording in an oxidized crystal (sample LNB1) wit...Figure 6.23 Self‐stabilized recording in an oxidized crystal (sample LNB1) wit...Figure 6.24 Overall beam
produced by the interference of the recording beams...Figure 6.25 Measurement of the running hologram speed for the sample LNB1,
, Figure 6.26 Self‐stabilized recording on the same
:Fe sample (LNB3) with ordi...Figure 6.27 Recording setup stabilized on a nearby placed glassplate G, all ot...Figure 6.28 Glassplate‐stabilized experimental data for the recording on an ox...Figure 6.29 Mathematical simulation of non self‐stabilized recording with
. T...Figure 6.30 Evolution of
and scattering PSL during stabilized holographic re...
7 Chapter 7Figure 7.1 Schema of the experimental setup for electro‐optic coefficient meas...Figure 7.2 Evolution of the absorption coefficient in an undoped
irradianc...Figure 7.4 Light‐induced absorption of undoped
(sample labeled BTO‐013) at
Figure 7.5 Absorption coefficient‐thickness
measured for three different BTO...Figure 7.6 Arrhenius curve dark conductivity for BTO:V. Data fitting to Eq. 7....Figure 7.7 Frequency‐dependence of the absolute value
in Eq. 7.12 for differ...Figure 7.8 Schematic setup for the electric measurement of photoconductivity. ...Figure 7.9 Typical crystal schema, in the so‐called “Transverse Configuration”...Figure 7.10 Photocurrent (in pA) as a function of the incident irradiance on t...Figure 7.11 (Left) Photograph of the wavelength‐resolved photoconductivity exp...Figure 7.12 Transverse configuration: coefficient σ on a logarithmic scal...Figure 7.13 Detailed view of Fig. 7.12 showing a strong increase in σ for...Figure 7.14 σ (s m/
) for thermally relaxed BTO:V (
) and pre‐exposed to Figure 7.15 Longitudinal configuration schema showing an externally polarized Figure 7.16 Lateral view of the sandwiched BTO crystal plate showing the light...Figure 7.17 Plotting of
with positive polarization (ranging from 0 to 500 V)...Figure 7.18 Light‐induced photoelectric conversion efficiency
measured (
) o...Figure 7.19 Comparative longitudinal
(without external applied field) (
) an...Figure 7.20
and
measured on an ITO‐sandwiched BTO with
mm and
mm under...Figure 7.21 Modulated photocurrent data of an undoped
crystal, with monochro...Figure 7.22 Plot of the Airy function (left), the equivalent Gaussian function...Figure 7.23 Plotting of
in the
plane, for
(left) and
(right).Figure 7.24 Schematic representation of an ac photocurrent produced by a sinus...Figure 7.25Figure 7.25 Stationary space‐charge field arising from a speckle pa...Figure 7.26 Plotting of
in the
plane for a speckle pattern of light vibrat...Figure 7.27 Simulation of the first harmonic photocurrent coefficient
(in ar...Figure 7.28 Simulation of the first harmonic photocurrent coefficient
as a f...Figure 7.29 Schematic representation of the experimental setup. A laser beam i...Figure 7.30 Optical sensor in metallic housing (from Fig. 7.29) showing the se...Figure 7.31Figure 7.31 Expanded front view of the photorefractive sensor housi...Figure 7.32 First harmonic photocurrent as function of reduced vibration ampli...Figure 7.33 Experimental first harmonic photocurrent
measured on a CdTe:V ph...
8 Chapter 8Figure 8.1 Holographic setup: a laser beam is divided by the beamsplitter BS, ...Figure 8.2 Energy transfer between interfering
= 633 nm beams in the two‐wav...Figure 8.3 Exponential gain coefficient
as a function of the external incide...Figure 8.4 White light hologram erasure in
:Fe: The erasure data (
), measure...Figure 8.5 The graph shows the erasure of holograms in undoped BTO under 10–15...Figure 8.6 Hologram diffraction efficiency (arbitrary units) decay during
nm...Figure 8.7 Diffraction efficiency (
in arbitrary units) during erasure of a h...Figure 8.8 Erasure of holograms in Pb‐doped BTO (same sample as in Fig. 8.6) r...Figure 8.9 Diffraction efficiency (recorded and measured using
nm laser beam...Figure 8.10 Diffraction efficiency (au) as a function of time (seconds, in log...Figure 8.11 Hologram relaxation in the dark: exponential time as a function of...Figure 8.12 Photorefractive sensitivity
alt="images"/> ) as...Figure 6.20 Computed evolution of 
