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Transcript
Non-linear Effects
100mW of cw output from a package 3.8cm x 3.8 cm x
10cm.The device consists of a chip of 0.5mm of Nd:YV04
in contact with a 2mm KTP crystal; 500mW of laser
output at 809nm is used to pump the device.
And inside the box…
Doubling and doubling again!
Non-linear Optics

The polarisation, P, can be described in terms of the
susceptibility tensor, χ. We can include any nonlinear response of the medium as shown below.
 Note that in general the electric field and the
polarisation need NOT be collinear.
Non-linear Effects:
(Classification by order)
Anisotropic binding of an electron in a
crystal
The springs have
different stiffness for
different directions
of the electron’s
displacement from
its equilibrium
position within the
lattice.
The polarisation, and
therefore the
refractive index, will
be different in
different directions
Index ellipsoid and the principal axes
Uniaxial or Biaxial?
(a)Biaxial crystal – two optical
axes.
(b) Positive uniaxial crystal –
one optical axis ne ≥ no
(c) Negative uniaxial crystal –
one optical axis ne ≤ no
The Permittivity Tensor
The Index Ellipsoid
3D ellipsoid surface is given by:
The Electro-optic Ellipsoid
Taylor expand the refractive index in the electric field
Or in terms of r,
So,
With the identities,
Linear Electro-optic Tensor
The r-coefficients
are related to the
crystal symmetry
The 27-elements reduce to 18 because of invariance w.r.t.
i,j interchange
Electro-optic tensor
Electro-optic effect
Distortion of index ellipsoid caused by
The application of an electric field
Case of ADP and isomorphs
With a field applied in the z-direction the ellipsoid is
distorted in the xy-plane
Rotation by 45° about the z-axis transforms to the (x´, y´, z´)
co-ordinate system
Rotation of Axes
If we take
θ=45 degrees
The ellipsoid referred to rotated axes
The transformed axes
So, given,
we can write,
i.e.,
Variable phase-plate
With light polarised
along the original
x-direction
For a half-wave plate:
Giving a half-wave
Voltage:
(Note: the field
& propagation
directions are
the same here!)
Amplitude modulation
Electric field & Displacement Vector
k  H   D
k  E  0H
The wave-vector surface
The intercept of the
k-surface with each
plane xy, xz & yz
Consists of one circle
and one ellipse. The
surface is double
suggesting there
are two possible values
for k for any direction
of the vector k. There are
two phase velocities
corresponding to two
orthogonal polarisations.
At the point P the two
values are equal; this is
the optical axis.
Poynting’s vector- S & Wave vector- k
Summary
Linear optics:
Non-linear optics:
Linear electro-optic:
(Uniaxial crystal becomes biaxial when the field is applied)