PL241098B1 - Optical collimator for detection of ultraweak luminescence of spatially expanded objects, using the single-channel detector - Google Patents

Abstract

The optical collimator shown in the drawing for the detection of the ultra-weak luminescence of spatially extended objects with the use of a single-channel detector, is a mirror with the shape of the inside of an inverted cone with a truncated apex, which at the base turns into a cylindrical shape, with the entire interior of the body being a reflecting surface.

Description

Description of the invention

The subject of the invention is an optical collector of ultra-weak luminescence of spatially extended objects, enabling its detection with a single-channel detector. This collector collects the radiation emitted by the examined surface and creates a beam of luminescent light with a smaller angular divergence, which enables detection with the use of a single-channel detector. An optical collector that forms a parallel (collimated) beam of collected radiation is called an "optical collimator".

State of the art

Luminescence (the so-called "cold glow") is caused by the excitation of external matter. The stimulating factor can be, for example, ionizing radiation (radioluminescence), chemical reactions (chemiluminescence), an external electric field (electroluminescence) and also light (photoluminescence).

The phenomenon of matter luminescence is used in many ways. One of them is basic research. By examining the luminescent response of the material to specific types of stimulation (usually optical), we can, for example, determine the chemical composition of the material, and in particular detect even trace amounts of certain substances. Other, exemplary application areas are luminescence dosimetry (determination of radiation doses) and luminescence dating of archaeological and geological objects. In these applications, we mainly use the phenomena of thermoluminescence (TL) and optically stimulated luminescence (OSL). Usually very sensitive photomultipliers operating in the photon counting mode are used for detection. The measured luminescence is usually very weak. Therefore, despite the use of advanced solutions and high sensitivity of the detection system, it often turns out to be insufficient.

In order to improve the detection capability of the measuring system, two basic methods are used:

1. Optimization of the geometry of the detection system

This method is the most obvious and most effective. It consists in bringing the detector as close as possible to the source of luminescence emission. This situation is illustrated in Fig. 1, where the photomultiplier positioned directly above the emission source registers photons in a large solid angle.

Unfortunately, such a solution is not always applicable. The need to move the detector (usually a photomultiplier) away from the sample may arise for a variety of reasons. One of them is the protection of the detector against high temperature, which is the case, for example, in thermoluminescence. Another reason is the need to place other elements between the test sample and the detector, such as optical filters and stimulation sources. We encounter such a situation, among others during measurements of optically stimulated luminescence and photoluminescence. Figure 2 shows an example of a typical optics geometry for measuring optically stimulated luminescence. Even a slight distance of the detector from the emission source causes a reduction of the solid registration angle and the number of registered photons.

2. The use of lenticular optics. Optical condenser.

In order to improve the detection capability of the system, sometimes additional optical elements are used to increase the number of photons reaching the detector. In the simplest case, such a role is played by a single focusing lens (Fig. 3) improving the optical geometry of the detection system using an optical condenser consisting of a single lens. The light rays marked in red do not go to the detector. More complex optical condensers consist of two or more lenses (Fig. 4), improving the geometry of the optical detection system by using a dual lens optical condenser. The light rays marked in red do not go to the detector.

The presented solution is quite effective, but it also has numerous disadvantages:

• in order to achieve proper efficiency, the condenser (lens) should be placed as close to the emission source as possible, which is not always possible (see above), • the condenser collects the signal much better from the central area of the sample than from the peripheral elements; these are shown by the extreme radii in Fig. 3 and Fig. 4,

• any lenticular optics exhibit undesirable chromatic aberration, i.e., uneven mapping characteristics depending on the wavelength; the reduction of this defect by the use of e.g. achromatic lenses is possible only in a very small wavelength range (e.g. only the visible range without UV and IR).

In addition to the two methods presented, the possibility of using a paraboloid mirror should also be mentioned. This mirror transforms the radial path of the rays from the point source into a parallel beam, which is quite easy to insert into any detector. However, this solution has two disadvantages. The first is high sensitivity to any deviations from the "punctuality" of the source. Rays coming from another, close place show a large discrepancy. The application of paraboloid mirrors to spatially extended objects is therefore problematic. The second, disadvantageous aspect is also the high cost of making such a mirror.

Technological development in the field of metrology is largely related to the improvement of the sensitivity and detection capabilities of measuring instruments. The vast majority of these instruments are based on optical technology. Many of them also use the measurement of the luminescence of various materials. In particular, it concerns such fields as ionizing radiation and UV dosimetry, and luminescence dating of archaeological and geological objects.

The use of a new optical collector, according to the invention, better than the previous ones, which would allow for more effective detection of weak luminescence, is very important for the development of the above-mentioned measurement techniques. The greater number of recorded photons improves the signal-to-noise ratio, and at the same time improves the minimum detection threshold. In practice, it translates into greater accuracy and sensitivity of the measurements performed - for example determining the absorbed dose of ionizing radiation.

The essence of the invention

The optical collector of ultra-weak luminescence of spatially extended objects, enabling its detection with the use of a single-channel detector, according to the invention, is characterized by the fact that it is the interior of a two-segment passage body, the first of which is an inverted truncated cone, and the second is a cylinder, and whose internal walls have a surface reflecting radiation, the inlet of luminescent radiation inside this collector is the open base of the inverted cone with a smaller diameter (d), and the outlet - the open base of the cylinder with a diameter (D) equal to the diameter of the larger base of the inverted cone, with which the lower edge of the cylinder is connected, opposite to the outlet luminescent radiation with reduced angular discrepancy.

Advantages of the invention

The use of the conical-cylindrical optical collector according to the invention allows for very effective registration of weak optical signals from spatially extended emitters with the use of a single-channel detector with a large aperture (e.g. a photomultiplier). The results of numerical simulations show that the effective detection ability exceeds 80%. This result is almost impossible to obtain with the use of other methods. The use of the described collector will allow to improve the detection ability, and thus the sensitivity, of many optical devices using low luminescence, for example in dosimetry and in luminescence dating.

Detailed Description of the Invention

The body of the optical collector according to the invention can be made in various ways - for example, it can be extruded from one or two blocks of aluminum, polishing the interior of the conical and cylindrical surfaces thoroughly. An essential part of the collector according to the invention is a conical surface which collects a large part of the light rays emitted by the sample, while giving them a direction similar to the direction of the collector and photomultiplier axis. The cylindrical part essentially acts as an optical guide, directing the rays into the photomultiplier tube.

The cross-section of the optical collector according to the invention is shown in Fig. 5, where the path of several light rays is marked.

Figure 6 shows a cross section of the present mirror optical collector with the dimensions marked. The figure shows the course of two selected light rays. The height h, where the cylindrical part starts, is very important. Part of the rays emitted by the sample hits the cylindrical surface directly (as indicated in Figure 6). The reflection from the cylinder does not change the value of the angle of deviation of the ray from the optical axis of the system (vertical direction in Fig. 6), but only its sign. Therefore, it is important that the height h is large enough so that the angle of deflection γ is small.

PL 241 098 Β1 (1)

The rays hitting the cylindrical part of the current collector have deflection angles l / l - I / I ^{1 1} I s |, where y _g is the limiting (maximum) angle with the value:

(D + d γ _σ = arctan ----- ^s (. 2h

We can therefore reduce the angle y _g by increasing the height h and reducing the dimensions of D and d. The reflection from the conical part may be multiple. Each rebound reduces the yaw angle value. For example, in the case shown in Fig. 6, after a single reflection, the initial value of γι is reduced to / ₂ = 180 ° -2e- /, (2)

And so, for an exemplary value of ε = 60 °, we have:

/ 2 = ⁶⁰ ° ^ (3)

Radii with a deflection angle γι e (30 °, 90 °) will hit the inner surface of the inverted cone, so we will obtain the divergence of the output rays in the range of γ ₂ e (-30 °, 30 °).

Example. In order to demonstrate the operation of the current collector directly, computer simulations were performed using the Monte Carlo method. Exemplary simulation results are given in Fig. 7, which shows a numerical simulation of the course of 10,000 light rays (photons) emitted from the sample. The lines show the history of the rays. Some fall directly on the detector, others one reflection, two and more reflections, and the rest are lost rays. The reflection coefficient was set at 0.9 which roughly corresponds to the real value for the mirror made of aluminum.

Simulation results Number of rays in the simulation = 10,000 Number of registered rays = 9699 (96.99%) Detection efficiency = 84.83% (after taking into account losses on reflections)

The results of the above simulation naturally depend on the geometrical parameters of the system, ie the cone's inclination angle - ε, its height h, the output aperture D and the input aperture d, etc. Based on the exemplary data, it can be seen that the efficiency of the current collector is very high.

Claims (1)

1. Optical collector of ultra-weak luminescence of spatially extended objects, enabling its detection with the use of a single-channel detector, characterized by the fact that it is the interior of a two-segment passage body, the first of which is an inverted truncated cone, and the second is a cylinder, and whose internal walls have a surface reflecting radiation, at where the inlet of luminescent radiation inside this collector is the open base of the inverted cone with a smaller diameter (d), and the outlet - the open base of the cylinder with a diameter (D) equal to the diameter of the larger base of the inverted cone, with which the lower edge of the cylinder is connected, opposite to the radiation outlet luminescence with reduced angular divergence.