Experiment Pockels effect and electro-optic modulation with green laser

Sku: 204850

Dida Concept

The strong points

Reasonable applied tension: a few hundred volts, much less than for a Kerr cell
Linear effect: linear variation of birefringence as a function of the applied tension
Polarization modulation: the birefringence of the crystal is modified to induce a phase shift between the ordinary and extraordinary waves propagating in the crystal and to induce a polarization modification at the output of the cell

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Presentation

Birefringence induced by an electric field: use the Pockels effect to write and transport information on an optical carrier.

Topics covered:
- Polarization and change of light polarization state
- Natural birefringence and birefringence induced by an electric field
- Polarization modulation, amplitude modulation
- Electro-optic modulator, Lithium Niobate crystal (LiNbO3), Pockels effect
- Half-wave voltage (Vp), measurement of the electro-optic coefficient by different methods
- Optical transmission in free space, demodulation

Principles and objectives:
A laser beam is linearly polarized at 45° to the axes (X,Y) of the Lithium Niobate crystal. The beam passes through this crystal along its optical axis (Z).
An applied voltage to the modulator allows for the linear modification of one of the refractive indices of the LiNbO3 crystal (Pockels effect). The natural birefringence of the material is then modified, leading to a phase shift between the ordinary and extraordinary waves propagating in the crystal. This phase shift induces a change in polarization at the ouExperimentut of the modulator. The analyzer placed before the detector transforms this polarization variation into intensity variation.
The transfer function of the setup (transmitted intensity / incident intensity) is measured experimentally either by rotating the analyzer or by applying a continuous voltage to the crystal.
The curve thus obtained is used for the study of its operating points or to determine the half-wave voltage and the electro-optic coefficient (r22) of the material.

This product was developed in collaboration with the LMOPS laboratory in Metz.

Composition:
▪ 1 electro-optic modulator (Pockels cell, LiNbO3 crystal) with 2 SMA-SMA cables
▪ 1 generator-amplifier for Pockels cell control
▪ 1 amplified detector with adjustable gain
▪ 1 prism bench of 1 m with adjustable feet set (ref.202519)
▪ 5 standard prism riders (ref.202234)
▪ 1 prism rider with lateral adjustment (ref.202392)
▪ 1 green laser @532 nm on rod (ref.205157)
▪ 2 polarizers in graduated mount (ref.202374)
▪ 1 rotating mount quarter-wave polaroid plate (ref.202378)
▪ 1 multimedia kit (radio + speakers + all necessary connections for proper functioning)
▪ 1 experiments manual

Technical characteristics

Thématique TP	Optique, Polarisation, Effet Pockels, Composants optiques actifs
Type de matériel	TP clé en main