RU165622U1 - DEVICE FOR TESTING HOLOGRAPHIC LIGHT-SENSITIVE MATERIALS - Google Patents

Abstract

A device for testing holographic photosensitive materials, comprising a laser, a photo shutter, a mirror forming a laser reference beam, a holographic photosensitive material, a white light source, a spectrophotometer, a computer and a display, characterized in that a translucent mirror is additionally introduced along the holographic photosensitive material to form a laser laser object beam, a translucent mirror attached to the plane of the holographic material with a minimum gap, oeffitsient translucent reflection mirror is selected in the range of 50% -75% in order to allow the passage of the probe beam for detecting the spectral response of the reflection hologram directly in the process of recording.

Description

The utility model relates to the field of holography, mainly to holographic photosensitive materials and their applications, and specifically to devices for testing the shrinkage values of these materials and the diffraction efficiency (DE) of holograms based on them.

Various devices are known for measuring DE and the degree of shrinkage of holographic photosensitive materials, in particular holographic photopolymer materials (HFPM). For example, in the patent [1, RELE Thomas et al. Photopolymer composition and its use for the manufacture of holographic media // RF Patent No. 2515991, published 02.20.2015. Bull. No. 05] a device is described by which first a volume reflective hologram is made on a photopolymer material, and then its diffraction efficiency is measured. In the specified device, the HFMP sample is mounted on a rotating table. Using optical elements from the laser radiation, the reference and object beams are formed and a reflective hologram is recorded in the HFPM. Then, when reading the hologram, the rotating table with the HFMP sample attached to it passes through the interval of angles from Ωmin to Ωmax with a step of 0.05 °. In each position, through 0.05Ω of the rotation angle, with the help of detectors, the powers of the beam passing through the hologram (zero diffraction order) and the first-order diffracted beam are measured, and the diffraction efficiency η is determined by the formula

where P _D is the power at the detector of the diffracted beam, and P _T is the power at the detector of the transmitted beam. From the graph of the dependence of the DE on the angle of rotation of the sample, the angle is determined at which the DE reaches a peak value. However, to determine this value, it is necessary to change the position of the diffracted beam detector, which is due to violations of the so-called Bragg conditions for volume holograms caused by shrinkage of the photopolymer material due to the conversion of the substance during photopolymerization (monomer conversion to a denser substance - polymer). As the authors themselves note, this is a disadvantage of this device.

This drawback (forced change in the position of the diffracted beam detector) does not have other known devices containing, along with the laser and optical elements necessary for recording the reflective hologram, an additionally introduced white light source and a spectrophotometer for recording the spectral response signal of this hologram as a DE measure [2 , Smothers et al. Dry film process altering wavelength response of hologram // US Patent # 4959283, Sep. 25, 1990; 3, Martin et al. Broad band reflection holograms and dry process for making the same // US Patent # 5725970, Mar. 10, 1998]. In these devices, it is not necessary to adjust the position of the diffracted beam detector for any degree of HFMP shrinkage, which is estimated by changing the position of the maximum spectral response of the reflective hologram.

However, a drawback of the devices described in [1, 2, 3] is the fact that to determine the laser illumination energy at which the maximum achievable DE is achieved for a given HFMP sample, and also to clarify the whole picture of DE evolution depending on this energy, it is required to produce several holograms (usually more than 10 pieces) and measure the DE for each of them.

Known devices for testing holographic photosensitive materials that do not require recording many holograms [4, S.A. Babin et al. Methods and devices for testing holographic photopolymer materials // Avtometriya. 2003. No2. S. 57-70; 5, Shelkovnikov V.V. et al. Photopolymer compositions for recording reflective holograms in a wide spectral range // RF Patent No. 2552351, published June 10, 2015, Bull. No. 16]. These devices make it possible to determine the dependence of the DE of the hologram on the illumination energy continuously for the entire recording time by recording the signal from the probe beam of white light transmitted through the hologram.

The main advantage of these devices from the point of view of testing photosensitive materials is the ability to monitor the main processes of hologram recording, including the stage of nucleation and development of the holographic lattice, reaching the maximum DE, evolution of shrinkage of the HPSM.

Devices [4, 5] contain a laser and optical elements that form the reference and object beams, resulting in the interference of a reflective hologram, as well as elements for detecting the spectral response of this hologram during recording, including a white light source, optical fibers guiding the probe beam white light on the hologram and perceiving a beam of light transmitted through the hologram, which is sent to the spectrophotometer. The intensity of the probe beam is set so low that it does not have a noticeable effect on the recording of the hologram.

A modification of the devices [4, 5] is a device for testing holographic photosensitive materials, described with the participation of the author of the proposed application in the article [6, E.F. Pen, I.A. Zarubin, V.V. Shelkovnikov, E.V. Vasiliev. The methodology for determining the shrinkage parameters of holographic photopolymer materials // Avtometriya, 2016, No. 1, p. 60-69] and selected as a prototype of the proposed utility model.

This modification is designed to study the features of shrinkage of HFPM and does not have fundamental differences from devices [4, 5], except that the probe beam of white light is directed perpendicular to the surface of the photosensitive material. This was done for the convenience of calculating the HFPM shrinkage parameters according to the procedure [6].

The functional diagram of this device is shown in figure 1. The device contains the following elements: laser 1; shutter 2, setting the exposure time; beam splitter 3; mirrors 4; sample with HFPM 5; white light source 6; spectrophotometer 7; computer 8; display 9.

The device operates as follows: the laser radiation beam passes through the shutter and is split by a beam splitter into reference (R) and object (Ob) beams of equal intensity, which are directed by mirrors to the same section of the photosensitive material from opposite sides, while identical polarization states and equal lengths of the optical paths of these beams from the beam splitter to the HPSM are ensured; as a result of interference of these beams, a volume reflective hologram is formed; a beam of probing white light of low intensity is directed perpendicularly to the surface of the HPPM; the transmitted probe radiation is sent to a spectrophotometer; the result of the spectral response is observed on the display screen. The measurement of the transmittance spectrum of the resulting hologram begins synchronously with the start of exposure and is carried out periodically during the entire time of exposure, which allows obtaining data on the DE of the hologram at any current moment of recording, the measurement results are accumulated in a computer. After the exposure time, the shutter blocks the laser radiation, while the probe light continues to function, allowing you to observe the resulting spectral response of the reflective hologram.

The disadvantage of this device, as well as devices [1, 4, 5], is the complexity of the optical scheme, since the elements of the formation of the reference and subject beams spaced apart over a considerable distance (tens of centimeters) are used, which should ensure the same state of their polarization and the minimum difference in lengths optical paths from the beam splitter to the photosensitive material (no more than the so-called coherence length of the laser used, in practice, this is on the order of several centimeters). It should also be noted that these holographic devices require careful protection from high-frequency mechanical vibration, leading to a chaotic change in the interference pattern of the reference and subject beams during the recording of holograms.

Practical experience with these devices has shown the need and the possibility of improving them - simplifying the design, increasing its reliability, reducing the cost of manufacturing the device.

The inventive device for testing holographic photosensitive materials eliminates the disadvantages of the prototype. This is achieved due to the fact that in the device containing a laser, a photo shutter, a mirror, a holographic photosensitive material, a white light source, a spectrophotometer, a computer, a display, a translucent mirror is additionally installed, installed along the laser beam directly behind the holographic photosensitive material with a minimum clearance. With this solution, a simplification of the device is achieved (there is no second mirror and a beam splitter), while the object beam necessary for recording a hologram is formed from a reference beam by reflection from a translucent mirror, which automatically leads to the fulfillment of the condition that the optical paths of both laser beams are equal. This circumstance increases the reliability of the device and reduces the requirement for the coherence length of the laser used, and, therefore, allows the use of a cheaper laser. A translucent mirror also performs a second function - it ensures the passage of a probe beam of white light to detect the spectral response of a reflective hologram. It is preferable that the probe beam be directed perpendicular to the plane of the holographic material, which creates convenience when calculating the HFPM shrinkage parameters according to the procedure [6].

A functional diagram of the inventive device is shown in figure 2. The device contains a laser 1; shutter 2; a mirror 3 directing the laser beam R, called reference, on the holographic photosensitive material 4; a translucent mirror 5 forming a beam Ob, called subject; white light source 6; spectrophotometer 7; computer 8; display 9. In order to be able to measure the transmission spectrum of the reflective hologram during recording, the reflection coefficient of the translucent mirror 5 should be less than 100% (in our experiments it was about 75%).

The inventive device operates as follows: a beam of light from a laser passes through the shutter, is reflected from the mirror, forming a reference beam R, which is directed to the HPSM, immediately behind it is a translucent mirror, which, reflecting the incident radiation, forms the object beam Ob necessary for the formation interference pattern in interaction with the R beam. A beam of low-intensity probe white light from a white light source is sent to the resulting volume reflective holographic grating perpendicular to the surface of the GPFM. The probe radiation passing through a translucent mirror and a hologram is sent to a spectrophotometer, the result of the spectral response is processed on a computer and observed on a display screen. The measurement of the transmittance spectrum of the resulting hologram begins synchronously with the start of exposure and is carried out periodically throughout the entire recording process.

The differences and advantages of the claimed device in comparison with the prototype are its compactness, simplicity and reliability, since there is no need to use a number of optical parts that require careful alignment (a beam splitter and one of the mirrors), while the difference in the optical path lengths of the reference and subject beams is practically absent. This allows the use of cheaper lasers with a short coherence length (of the order of several millimeters). The requirements for the degree of vibration protection of the device are reduced, since the propagation paths of the reference and subject beams are maximally localized. It is important that all the functional capabilities of such a device are preserved for assessing the degree of shrinkage of the HFPM and the DE value of reflective holograms based on them.

The efficiency of the claimed device is experimentally confirmed by creating its layout and measuring the spectral responses of reflective holograms in the process of recording them. The model used a diode-pumped laser (DPSS) with a radiation wavelength of 532 nm from Viasho Ltd., a spectrophotometer from VMK Optoelectronics [http://www.vmk.ru/] and photopolymer materials from the Novosibirsk Institute of Organic Chemistry SB RAS [ 5]. The measurement results are similar to the data obtained in [6].

Claims (1)

A device for testing holographic photosensitive materials, comprising a laser, a photo shutter, a mirror forming a laser reference beam, a holographic photosensitive material, a white light source, a spectrophotometer, a computer and a display, characterized in that a translucent mirror is additionally introduced along the holographic photosensitive material to form a laser laser object beam, a translucent mirror attached to the plane of the holographic material with a minimum gap, oeffitsient translucent reflection mirror is selected in the range of 50% -75% in order to allow the passage of the probe beam for detecting the spectral response of the reflection hologram directly in the process of recording.

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