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Download EWDLS Evanescent Wave Dynamic Light scattering
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Transcript
Evanescent Wave Dynamic Light scattering
EWDLS
P. R. Lang
Institut für Festkörperforschung
Forschungszentrum Jülich GmbH
EWDLS.2
APD
to correlator
incident
beam r
se
La
Q
Q
fiber
collimator
αr
sample
θ
cell
totally
αi
reflected beam
ks
T
αr
Q||
θ
ke
Fig. 1: Sketch of a EWDLS setup. Left: The evanescent field, which is created upon total reflection is scattered by an ensemble colloidal sphere. Top right: The scattered light is collected
by a mono–mode fibre an correlated. Bottom right: decomposition of the scattering vector into
components parallel and normal to the reflecting interface
1
Basic Principles
In EWDLS–experiments an evanescent wave is created upon total reflection of a laser beam
from the flat interface between a glass body and the sample solution. This evanescent wave is
used as the incident radiation for a dynamic light scattering experiment, as sketched in Figure 1.
The near-wall dynamics of Brownian particles can be studied by EWDLS, if the intensity which
is scattered off the evanescent wave by an ensemble of particles is correlated. The scattered field
at a given time t from an ensemble of N identical particles is,
½
¾
N
X
Λ
exp − zj exp {ıQ · rj } .
ES ∝
(1)
2
j
Here the scattering vector is the difference between the wave vector of the scattered and the
evanescent wave, Q = kS − ke , rj defines the position of the j th particle and Λ is the 1/e–
penetration depth of the evanescent field intensity. The time auto correlation of the scattered
field can be expanded in a cumulant series as
©
ª
g1 (t) = exp −Γt + O(t2 )
(2)
where the initial decay rate depends on the scattering vector components as
Γ = hDk iQk2 + hD⊥ i(Q2⊥ + 4/Λ2 ),
(3)
With our instrumental design it is possible to vary the amount of the normal, Q⊥ , and the
parallel, Qk , component, of the scattering vector independently. By this means it becomes
possible to distinguish between the particle mobility parallel and normal to the interface.
EWDLS.3
Fig. 2: Left: Total view of the EWDLS setup. Right: Detailed view of the sample surroundings.
2
Experimental Setup
The mechanical setup is based on a three axis x-ray spectrometer by Huber, which is shown in
Figure 2. This instrument allows for a three dimensional access of the detector to the scattering
volume. As a light source we use alternatively a 15 mW HeNe Laser with a wavelength of 632
nm or a Verdi II system from Coherent with a wavelength of 512 nm. The scattered light is
collected with a mono-mode fiber attached to a splitter with a splitting ratio of approximately
50:50. From this the light is guided by two mono–mode fibers to two avalanche diode (Perkin
Elmer) detecting units, which can be operated in a single photon counting mode. The diodes’
TTL outputs are cross correlated using an ALV 6000 multiple tau correlator.
