News | February 23, 2017

Impossible (But Working!) Recipe For Ultrashort Laser Pulses

Impossible (But Working!) Recipe For Ultrashort Laser Pulses
Physicists from Warsaw have generated ultrashort laser pulses in an optical fiber, by using a method previously considered as physically impossible to achieve. Pictured above: Jan Szczepanek, a Ph.D. student from the Faculty of Physics of the University of Warsaw, at the innovative fiber laser. Image Credit - IPC PAS, Grzegorz Krzyzewski

Pulse lasers built entirely on optical fibers are increasingly readily being used by industry. Optical scientists from the Warsaw Laser Centre of the Institute of Physical Chemistry of the Polish Academy of Sciences and the Faculty of Physics of the University of Warsaw have generated ultrashort laser pulses in an optical fiber, by using a method previously considered as physically impossible to achieve. Their solution is not only useful, but also surprisingly simple!

An innovative fiber laser has come into being at the Laser Centre of the Institute of Physical Chemistry of the Polish Academy of Sciences (IPC PAS) and the Faculty of Physics of the University of Warsaw. Using an ingenious and easy-to-implement solution, the Warsaw optical scientists have "forced" one of the types of optical fiber lasers to generate ultrashort high energy pulses. The method they used is particularly interesting because of the fact that it was considered by experts as impossible to achieve. The new laser is devoid of any mechanically sensitive external parts, what seems to be especially interesting for future applications. The patent-pending invention should soon greatly shorten the time of processing materials in industrial laser machines.

"Fiber lasers can be built so that all the processes important for the generation and shaping of the ultrashort pulses take place in the fiber itself. Such devices, without any external mechanically sensitive components, operate in a very stable manner and are ideal for working in difficult conditions," says Dr. Yuriy Stepanenko (IPC PAS).

Laser action in the fiber leads to the generation of a continuous light beam. The release of energy in the shortest possible pulses is however much more favourable since it signifies a great increase of power. Pulses are generated in fiber lasers by a system known as a saturable absorber. When the light intensity is low, the absorber blocks light, when it is high - it lets it through. Since in femtosecond pulses (i.e. those lasting millionths of a billionth of a second) the light intensity is much greater than in a continuous beam, the parameters of the absorber can be adjusted so that it only lets through pulses.

"Up to now, graphene sheets, among others, have been used as the saturable absorbers, in a form of a thin layer deposited on the tip of the fiber. But the diameters of optical fibers are in the order of single microns. Even a little energy cramped in such a small cross-section has a significant density per unit area, affecting the lifetime of the materials. Therefore, if an attempt was made to increase the power of the femtosecond pulses, the graphene on the tip of the connector was destroyed. Other absorbers, such as carbon nanotubes, may also undergo degradation," explains Jan Szczepanek, a PhD student from the Faculty of Physics of the University of Warsaw, and the first author of the publication in the journal Optics Letters.

In order to generate higher energy femtosecond pulses in the optical fiber, the Warsaw physicists decided to improve saturable absorbers of a different type, not functioning due to the unique properties of materials, but due to the clever use of optical phenomena, such as nonlinear effects causing a change in the refractive index of glass.

Light is an electromagnetic wave, whose electric and magnetic fields usually oscillate in random, mutually perpendicular directions. When the fields oscillate all the time in the same plane, the wave is called linearly polarized. In classical optics, it is assumed that when such a wave passes through a medium it experiences a constant refractive index, regardless of the light intensity. In nonlinear optics this is different: at a sufficiently high light intensity the refractive index begins to increase slightly, the more so, the higher the intensity.

A nonlinear artificial saturable absorber works as follows. At the input the linearly polarized light is divided into a beam with a low intensity and a beam with a high intensity. The medium of the absorber can be chosen for both light beams to experience a slightly different refractive index, that is, for them to travel at slightly different (phase) velocities. As a result of the velocity difference the plane of polarization starts to rotate. At the output of the absorber there is a polarization filter which only lets through waves oscillating perpendicularly to the plane of polarization of the incoming light. When the laser is operating in continuous mode, the light in the beam is of a relatively low intensity, an optical path difference does not occur, the polarization does not change and the output filter blocks the light. At a high enough intensity, typical for femtosecond pulses, the rotation of polarization causes the pulse to pass through the polarizer.

For the saturable absorber with polarization rotation to work, the fibre not only must have different refractive indices in different directions (thus it has to be birefringent), but both indices should also be stable. The problem is that in ordinary optical fibers birefringence occurs accidentally, e.g. due to stress caused by the touch of a finger. Lasers built in this manner are extremely sensitive to external factors. In turn, birefringence of the polarization preserving fibers is so large that the light propagates in them in only one direction and the construction of artificial saturable absorbers becomes physically impossible.

"Birefringent optical fibers retaining the polarization state of the light entering them are already in production in the world. We are the first to demonstrate how they can be used to construct a saturable absorber: we cut the optical fiber into segments of an appropriate length and then reconnect them, rotating each successive segment 90 degrees in relation to its predecessor," says PhD student Szczepanek.

"Rotation means that if in one segment a pulse with, shall we say, vertical polarization travels slowly, in the next it will run faster and catch up with the second pulse, polarized perpendicularly. A simple procedure has therefore allowed us to eliminate the main obstacle on the road to increasing the energy, that is, the great difference in velocities between pulses of different polarities, so typical for all polarization preserving fibres," explains Dr. Stepanenko.

The more rotated segments there are, the better the quality of the pulses generated in the fiber. In the laser built in the Warsaw laboratory the saturable absorber consisted of a fiber with a length of approx. 3 m, divided into 3 segments, and a filtering polarizer. The potential number of rotated segments can be increased up to even a dozen or so.

The new laser produces high quality femtosecond pulses, and their energy can be up to 1000 times larger than typical for lasers with material absorbers. In comparison to the devices with artificial absorbers, the laser made by Warsaw scientists has a much simpler construction and therefore its reliability is significantly greater.

About The Institute of Physical Chemistry
The Institute of Physical Chemistry of the Polish Academy of Sciences was established in 1955 as one of the first chemical institutes of the PAS. The Institute's scientific profile is strongly related to the newest global trends in the development of physical chemistry and chemical physics. Scientific research is conducted in nine scientific departments. CHEMIPAN R&D Laboratories, operating as part of the Institute, implement, produce and commercialise specialist chemicals to be used, in particular, in agriculture and pharmaceutical industry. The Institute publishes approximately 200 original research papers annually.

SOURCE: Institute of Physical Chemistry of the Polish Academy of Sciences