Pump & probe phase microscope

A microscopic system for inducing and monitoring the dynamics of phase changes in a material, manifested by local changes in optical transmittance and reflectance.

One of the promising products of materials research in recent years is thin films of chalcogenides, which are already being commercialized, for example, in data storage technologies. However, due to their excellent combination of properties, their use could soon be extended to the photonics field (metamaterials or other integrated active photonic devices). The principle of inscription is a reversible change between the amorphous and crystalline phases of the material, which can be induced optically. Currently, lasers emitting in the red and infrared spectral regions play a primary role. However, as with conventional CDs, a significant increase in capacity can be achieved by moving into the blue region (Blue-Ray).

This is where scientists from the University of Pardubice want to push the boundaries of knowledge. The aim was to create a functional device with two pulsed lasers, one of which would induce the phase change in the material with a shorter, stronger pulse (pump) and the other would monitor it with a longer, weaker pulse (probe). The requirement was to be able to simultaneously monitor both the change in transmittance and reflectance of the sample, from which the dynamics of the recording is then evaluated. It was also to include the possibility of precise positioning of the samples, an imaging microscopic branch allowing monitoring of the sample surface, a fully functional detection part with an oscilloscope and a PC for controlling the system and processing the measured data.

Although similar research systems already exist, their function is usually based on the use of red or infrared lasers. It was the customer's requested switch to the blue region of the spectrum - in addition to using fibre lasers - that was the main innovation and technical challenge of this project.
A diode laser (405 nm), a laser diode (450 nm), two microscope objectives, 3 fast photodiodes (transmittance, reflectance and reference) and a red LED with camera for the imaging branch were used as the basic building blocks of the microscope system. All complemented by a suitable combination of adjustable mounts, dichroic mirrors, filters and lenses so that both lasers are aimed at the same spot in the sample plane, whose focus is enabled by the imaging branch. The principle optical scheme is shown in the figure.

The custom-made sample holder is mounted in XYZ precision positioning by the PI. The outputs of the detectors are connected to a fast oscilloscope from NI, from which data is then sent to a PC via a PCI-express bus. The control of all hardware (modulation of the lasers allowing adjustable pulse length and intensity, sample positioning, data acquisition on the oscilloscope,...) is realized by our selected electronic components housed together with the lasers in a common control unit (rack). The control of the system and the evaluation of the acquired data is performed via a prepared graphical user interface (GUI) on a supplied PC. This allows the system to be enclosed in an enclosure providing the user with protection from laser radiation - this enclosure is also included.

Device parameters

• Pump laser with 405 nm central wavelength, adjustable power and pulse length
• Probing laser (probe) with central wavelength of 450 nm, adjustable power and pulse length
• Focusing of laser pulses in the sample plane to a trace diameter < 1µm
• Detection of reflected and transmitted probe pulse with sampling time < 10 ns
• Simultaneous readout of data from 2 detectors using an oscilloscope with 1.5 GHz bandwidth, 10 bit resolution and 5 GS/s sampling rate
• Sample positioning in three axes with a minimum step size of 0.25 µm and a range of > 25 mm (YZ) and > 75 mm (X)
• PC control allowing full system masking