SU1666889A1 - Cryostat for optical study of materials - Google Patents

Abstract

The invention relates to a physical experiment technique and can be used for optical research of materials, including optical research of materials in a wide range of temperatures. The aim of the invention is to improve the usability and reduce the consumption of the cryogenic agent. The rod 9, on the lower end of which the sample holder 10 is fixed, is securely fixed by placing the created in the cavity 15 of the upper part 12 of the removable distributor by pumping air from the cavity 15 through the fitting 19. This removes air from the channel through which the optical radiation, due to the communication cavity 15 with the horizontal section 21 of the light guide channel through the gap between the rod 9 and the central channel in the housing of the distribution device. Gas from the cavity of the rod 9 is pumped out through an opening in the wall of the rod 9, made at the level of the entrance of the portion 21 of the light guide channel. The creation of a discharge in the cavity 15 allows for two functions: fixing the rod 9 in the desired position and creating an optically transparent light guide channel. In order to lower the sample temperature to 2.2 K, vacuum is created in the cavity 16 and under the surface of the liquid helium in the vessel 1, which communicates with the cavity 16. The liquid helium evaporates more intensively, as a result of which the temperature of the sample decreases. To change the sample, the pumping out of the cavity 15 is stopped, helium gas is injected and the rod 9 with the sample is removed by the handle 28. 2 Il.

Description

The invention relates to a physical experiment technique and can be used for optical research of materials, including semiconductor ones, over a wide range of temperatures.

The aim of the invention is to improve the usability and reduce the consumption of the cryogenic agent.

Figure 1 schematically depicts the crystal, section; 2 shows the stem structure. A cryostat for optical studies of materials contains a Dewar vessel 1 with an inner (helium) vessel placed in shield 2. The vessel 1 and shield 2 are placed in the casing 3. Between the casing 3 and the screen 2 a heat insulator 4 is installed. Above the screen 2 there is an external (nitrogen) vessel 5.

A cylindrical shell 7 is reinforced in the neck 6 of the Dewar vessel, and a gap is formed between the neck 6 and the shell 7. The lower end of the shell 7 is located in the Dewar vessel below the estimated level of the cryogenic agent in it. At this end of the shell 7, an optical radiation receiver 8 is installed, for example a bolometer, which has a tight connection with the cylindrical shell 7.

Inside the cylindrical shell 7 there is a hollow rod 9 having a lower portion located in the Dewar vessel 1 and an upper portion located outside the vessel 1. At the lower end of the lower portion a sample holder 10 is fixed. The rod 9 is made in the form of a tube. The cryostat has a light guide channel, and the inner surface of the rod 9 forms a vertical section 11 of this light guide channel.

The cryostat is provided with a removable distributor fixed on the neck of the 6th Dewar, containing a detachable housing with a central channel in the upper part, made of two hermetically connected parts 12 and 13 mounted one above the other. Sealing is performed, for example, by means of a gasket 14, and parts 12 and 13 are bolted to one another (not shown). In each of the parts 12.13 along the vertical axis is made a cavity 15, 16, respectively. The cavity 16 in the lower part communicates with the cavity of the helium vessel 1 Dewar due to the presence of a gap formed between the neck 6 and the cylindrical shell 7.

The same gap is used to make electrical connections between the optical radiation receiver 8 and the electrical connector 17.

The cavity 16 of the part 13 is also in communication with the choke 18 for pumping gas and reducing the pressure in the Dewar vessel.

The cylindrical shell 7 is fixed in the part 13 of the distribution node and has a tight connection with it along the perimeter so that the cavity 15 is not communicated with

cavity 16.

The cavity 15 in the upper part 12 communicates with the second fitting 19 for evacuating the gas and with the cavity of the cylindrical shell 7 through a channel 20 formed between

0 by a rod 9 and a central channel in the upper part of the body (in detail 12). The channel 20 is located between the cavity 16 and the end wall of the part 13.

In detail 12 detachable node is made

5 is a horizontal section 21 of the light guide channel located at an angle to the channel 20 (in FIG. 1 at an angle of 90 °). A portion 21 of the light guide channel is connected to a manifold 22. A manifold 22 representing itself

0, the entrance of the light guide channel is provided with a transition sleeve 23, which seals the internal cavity of the nozzle 22 and at the same time allows the passage of optical radiation. The clutch 23 is for

5 connecting the cryostat with an optical radiation source. The design of the adapter may vary. The clutch 23 consists of two parts of an annular shape, between which a synthetic

0 film 24, for example, Lavsan, with a thickness of 3 μm when measuring in the wavelength range from 50 to 650. In this range, a lavsan film of a specified thickness sufficiently well passes optical radiation and easily withstands a pressure drop of 1 atm (with a channel diameter of 9 mm).

The upper end of the rod 9, located in the cavity 15 and 16 and the Central channel

0 of the housing of the distribution device, has an opening 25 (FIG. 2), which is made in the wall at the entrance level of the light guide horizontal section 21 of the light guide channel. In the upper zone of the stock

5 9 is provided with an insert 26 connected to the cover 27 with a handle 28. The end end of the insert 26, located at the level of the horizontal section 21 of the light guide channel in the upper part 12, has a mirror

0 surface made at an angle to the vertical axis. The mirror surface can be made by polishing it and coating it with a thin layer of silver. Inner surface of the tube

5 of the rod 9, as well as the channel 21 and the pipe 22 is carefully polished and coated with silver.

The sample holder 10 is made in the form of a process insert, which has an internal opening in the form of a cone converging to the sample. If necessary, an electric furnace (not shown) can be mounted on the holder 10.

In this cryostat design, almost any Dewar transfer vessel can be used as a Dewar vessel.

The cylindrical shell 7 and the rod 9 should be made of a material with low thermal conductivity. This reduces the flow rate of the liquid refrigerant (reduces losses). Brass tubes or stainless steel tubes can be used as materials.

The components of the distribution unit, as well as box 26, make sense (for the same reason) to be made of brass or stainless steel. The gasket 14 may be made, for example, from Teflon.

The device works as follows.

Before starting the experimental work, a removable distributor is fixed on the neck 6 of the transport vessel. The cylindrical shell 7 with the optical radiation receiver 8 is placed in the internal cavity of the vessel 1, in which a coolant, for example helium, is placed. The rod 9 while you can not put in the internal cavity of the cylindrical shell.

Using a transition sleeve 23, a connection is made with the output of the horizontal section 21 with an optical radiation source. Due to the presence of the coupling 23, the states of the vacuum cavities of the radiation source and the cryostat are independent. This is of no small importance when conducting experimental work, since the time required for pumping out a radiation source significantly exceeds the time required for pumping out the cavity of the light guide channel of the cryostat (due to a significant difference in volume). This solution made it possible to reduce the preparation time of the experiment by at least one order of magnitude.

Connector 17 is connected to receiver 8, fittings 18 and 19 are connected to vacuum pumps (via a valve or valves). Pressure monitoring in the channels is carried out with vacuum gauges (not shown).

The test sample is mounted on the holder 10 so that the hole in it closes. At the same time, the process vtsavka 29 can be removed from the rod 9 (for ease of handling).

The holder 10 may be interchangeable and have different (depending on the purpose of the experiment) design and equipment.

The holder 10 shown in FIG. 2 is intended to investigate optical transmission. The divergence of the cone and the outlet in it can vary 5.

After installing the sample under investigation on the holder 10 and fixing it at the end of the rod 9, the latter is placed through the hole in the top part 12 of the distribution node 10 into the cylindrical shell 7. The outer diameter of the rod tube 9 is chosen so that the rod 9 with a small gap enters the cavity of the cylindrical shell 7

When the rod 9 is inserted into the cylindrical shell 7, the rod 9 is oriented (along the mark or along the guide) so that the hole 25 in the rod 9 coincides with the hole of the horizontal section 21 of the light guide channel. The end face of the insert 26 is then facing the entrance of the horizontal portion 21 of the light guide channel. Further, the rod 9 is fixed, for example, with the help of bolts, pressing the cover 27 to the distribution part 12

5 node (bolts in figure 2 are not shown). Under the cover 27 enclose a sealing gasket.

The design of this cryostat allows not to fix the cover 27

0 (respectively, rod 9) with the help of additional tools (bolts, etc.). Stock

9 is reliably fixed due to the vacuum in the cavity 15 that occurs when the pump valve (valve) is opened.

5 connected to the fitting 19. In this case, the pressure drop (about 1 atm) between the cavity 15 and the environment (atmosphere) creates a force acting on the cover 27, which is pressed against the part 12 of the distribution device. The absence of the need for special means of fastening and fixing the rod 9 increases the convenience of operation, simplifies work with the cryostat, and also reduces the time for

5 sample change. After installing the rod 9 in the cylindrical shell 7, air is pumped out of the cavity 15. This is done not only to fix the rod 9 (by pressing the cover 27), but

0 and in order to decontaminate the channel through which the optical radiation passes. From the radiation source, optical radiation through the coupling 23 passes through the nozzle 22, section 21 of the light guide channel, is reflected

5 from the end surface of the inlet 26 and into the internal cavity of the rod 9, i.e.

the light guide channel of rod 9, passes through

it is concentrated by the cone of the holder

10 and through the hole in it enters the sample.

Degrading the optical channel improves the accuracy of measurements.

Thus, creating a vacuum (vacuum) in the cavity 15 and, accordingly, in the adjacent and communicating cavities simultaneously allows two functions: fixing the rod in the desired position and creating an optically transparent channel from the source of optical radiation (device) to the sample under investigation. .

The optical radiation transmitted through the sample under investigation is recorded by the receiver 8. Experimental studies of samples of materials using the proposed cryostat can be carried out at different temperatures. So, if in vessel 1 there is helium (in vessel 5, respectively, nitrogen), then without heating the sample and at atmospheric pressure in cavity 16, the temperature of the sample will be almost equal to the temperature of liquid helium, i.e. 4.2 K.

If it is necessary to raise the temperature, then turn on the electric oven on the holder 10,

In a cryostat of this design, the sample temperature can be lowered to 2.2 K. To do this, open the valve (or valve) connecting the air channel from fitting 18 to the vacuum pump. In the cavity 16 and, accordingly, a vacuum is created above the surface of the liquid gel, a more intensive evaporation of the liquid gel occurs, as a result of which its temperature decreases, and with it the temperature of the sample under study. The higher the pumping speed, the lower the temperature. Temperature control can be carried out by the pressure of saturated steam or by using a thermocouple installed near the sample under study.

With this cryostat, it is possible to investigate not only the transmission spectra of materials, but also, for example, photoconductivity spectra. In this case, the signal; the transducer is not taken from the optical radiation receiver 8, but directly from the sample under study.

For changing the sample, the pumping of the cavity 15 is carried out, gas helium is injected and the rod 9 with the sample is taken out by the handle 28. In this case, the inlet of the gels into the cavity 15 and the cavity of the shell 7 adjacent to it i does not lead to unproductive consumption of the cryoagent. 3-5 minutes is enough for changing the sample when using this cryostat. If there are several holders 10 and the samples are pre-installed on them, then the time is even shorter. And at

By using two rods 9, the time taken to change the sample (along with the rod) is reduced to 1 minute. As a result, productivity is improved when working with the device.

A reduction in refrigerant consumption is provided not only by reducing losses when changing samples, but also by eliminating the transfusion operation of gels from

0 transport vessel Dewar in the working volume of the vessel 1.

Claims (1)

The invention of a cryostat for optical research of materials, comprising a Dewar flask, a cylindrical shell in its neck, a cylindrical shell, a lid, a hollow rod placed in the shell, having a portion located in the Dewar flask, and a portion with a handle located under the lid, a holder 0 sample, optical radiation receiver, light guide channel, gas pumping nozzles, characterized in that, in order to increase operating convenience and reduce the cryoagent consumption, the cryostat is provided with a removable distributor mounted on the neck of the Dewar vessel containing a detachable housing with a central channel the upper part, consisting of two hermetically connected parts mounted one above the other, in each of which a cavity is made along the vertical axis, and in the upper part there is a horizontal section vetovodnogo channel, wherein the cavity 5 of the lower part communicates with the cavity of the Dewar vessel and with one fitting to reduce the pressure in the vessel, and the cavity in the upper part communicates with the second fitting and with the cavity of the cylindrical shell, The latter is hermetically sealed in the lower part of the housing of the distributor, and the lower end of the shell is placed in the Dewar vessel below the proposed cryoagent level in it and the optical radiation receiver is fixed on this end of the shell, and the sample holder is located on the lower end of the stem, in the cavity and the central channel of the housing of the distribution device, provided in the upper zone connected to the lid by an insert, the end end of which is located at the level of the horizontal part of the lights channel-stand in the upper part, has a mirror surface vypolnen5 hydrochloric an angle to the vertical axis, and a stem wall provided with an opening located at the level of the horizontal portion of the light guide channel, and the latter has a vertical portion defined by the inner surface of the rod. FIG. I ten