![light diffraction light diffraction](https://2.bp.blogspot.com/-xJ81hcNqi94/VwQnqUwOPeI/AAAAAAAAAOc/Nr20qh7PC7kBKuKsbu-M5nL-vM-DMXltw/s1600/maxresdefault.jpg)
when developing Q-switched lasers with large mode radii and short laser resonators. Poor stability arises in situations where both effects are weak – for example, in a laser resonator where the Rayleigh length of the beam is much larger than the resonator length. imperfections of a fiber structure, bending of a fiber or misalignment of a resonator element) have comparatively weak effects.
![light diffraction light diffraction](https://d1whtlypfis84e.cloudfront.net/guides/wp-content/uploads/2018/02/21094857/Angels-stairs.jpg)
Good stability of such modes is achieved when the two counteracting effects are relatively strong, so that any additional effects (e.g. Similarly, resonator modes exhibit a balance of diffraction and focusing effects, only that the latter are usually lumped rather than distributed in the resonator.
![light diffraction light diffraction](https://schoolbag.info/physics/physics_math/physics_math.files/image583.jpg)
![light diffraction light diffraction](https://i.pinimg.com/736x/02/ca/a7/02caa7460423a66644fc614f55fda648.jpg)
That resolution limit can be estimated to be roughly the wavelength divided by the aperture diameter.įigures 6 and 7 show an example case, where a laser beam is truncated with a blade. The angular resolution of many optical instruments such as telescopes is also limited due to diffraction e.g. Therefore, the method often does not work that well. Such effects can also occur, for example, when trying to force a laser into single transverse mode operation (for optimum beam quality) by inserting a hard aperture into the laser resonator.Īlthough such an aperture can provide substantially higher round-trip losses for higher-order resonator modes, compared with those for the fundamental mode, it also introduces diffraction effects. The hard aperture introduces high optical frequencies, corresponding to rapid spatial changes of intensity. Such diffraction effects can be well understood and calculated based on Fourier optics. Same as Figure 4, except that a soft aperture is used.
#LIGHT DIFFRACTION SOFTWARE#
The simulation has been done with the software RP Fiber Power. Intensity profiles of a light beam directly behind a hard circular aperture (blue curve) and at some distances behind the aperture in steps of 25 mm. Only after some distance behind the aperture, characteristic diffraction effects can be observed.įigure 4 shows a simulated example, where an originally Gaussian beam has been truncated at a centered circular hard aperture.ĭuring the further propagation in air, the intensity profile develops a complicated structure due to diffraction.įor a soft aperture (Figure 5), causing a smooth intensity drop at the edge, the diffraction pattern is smoother. If a light beam (for example a laser beam) encounters some aperture which transmits the light in some regions and blocks it otherwise, the immediate effect on the transmitted light is only the corresponding truncation of the intensity profile.