RU2759509C1 - Method for creating a solid immersion medium for observing the internal structure of transparent objects with a high refractive index - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical engineering, namely to a method for creating a solid immersion medium for observing the internal structure of transparent objects with a high refractive index, and can be used for optical diagnostics and visualisation of the internal structure of objects by microscopy methods by introducing optical emission into such objects, as well as for laser modification or local optical excitation thereof. The technical result of the invention is achieved by filling the transparent object in a mould with an immersion powder including a solid substance with a refractive index n greater than 2.1, wherein n is the absolute refractive index, followed by transferring the immersion powder to a state of transparent solid ceramics by evacuation, pressing and sintering thereof; the mould with said immersion powder and the transparent object is cooled, the resulting solid immersion medium with the transparent object inside is extracted therefrom, followed by forming at least one optical window on the surface of the solid immersion medium by mechanical processing - grinding, polishing.EFFECT: increase in the stability of the method for studying the internal structure of transparent objects with refractive indices greater than 2.1, including precious stones.4 cl, 2 dwg

Description

The invention relates to methods for creating immersion systems for optical diagnostics of transparent objects with a high refractive index, including precious stones, as well as for visualizing the internal structure of such objects by microscopy methods and introducing optical radiation into such objects, including for their laser modification, for local optical excitation.

Immersion compositions are widely used in the study of various objects by optical methods - primarily in microscopy and spectroscopy [O.V. Egorova, Immersion method of microscopic observation. Overview. Gosstandart, Moscow, Russia]. Dozens of different liquid immersion compositions are commercially available, but their refractive index practically does not exceed 1.8 [https://www.cargille.com/refractive-index-liquids/]. At the same time, over the past several decades, no fundamentally new immersion liquids with any significantly different parameters have appeared. Most of the currently used compositions, including those with high refractive indices of about 1.8 - 2, were known already in the first half of the 20th century.

Known immersion liquids based on white phosphorus, methylene iodide, organic solvents β-bromonaphthalene, bromoform, decalin, tetralin, which have a high refractive index (more than 1.5) (Chemist's Handbook, vol. 4, M.-L .: Chemistry, p. 821). The disadvantages of these fluids include their high toxicity, extreme toxicity, explosiveness and high cost.

Known highly refractive Meyrowitz liquids (Geological Dictionary. - M .: Nedra. Edited by K.N. methylene CH2I2, as well as immersion liquids based on methylene iodide CH2I2 containing white phosphorus, arsenic bromide AsBr3, arsenic sulfide As2S3, sulfur, tin iodide SnI4 and antimony iodide SbI3. There are liquids (for example, Se ₂ Br ₂ ) with a refractive index equal to 2.1. These fluids are highly toxic and degrade quickly when exposed to light.

Cheaper and safer liquids based on metal iodides are known. For example, an aqueous solution of potassium and cadmium iodides and zinc chloride with a maximum refractive index n = 1.625 (USSR author's certificate N 948994, IPC3: C09K 3/00 and G01M 11/00, published on 08/07/1982). But with sufficient stability of this liquid, it does not allow obtaining higher refractive indices simultaneously with high values of viscosity.

A less stable liquid is known in the form of an aqueous solution of zinc iodide with a refractive index n = 1.64 (RF Patent No. 2051940, IPC6: C09K 3/00, G02B 1/06 and G01M 1/00, published on 01/10/1996). But the disadvantage of this liquid is the fragility of maintaining its high optical properties. After a few days, complexes are formed in the liquid, which change its optical properties.

At the moment, there are no known liquids with a refractive index n higher than 2.1. Thus, it is impossible to use them for transparent objects with a higher refractive index, for example, for diamond, (n = 2.40-2.46) in the visible range of the spectrum [Vasiliev LA, Belykh ZP. Diamonds, their properties and application - Moscow: Nedra, 1983].

In IR spectroscopy, the method of sample preparation is known and widely used, in which a solid test substance is ground to obtain submicron particles, mixed with a finely dispersed buffer material (usually KBr), and then pressed into a tablet form convenient for spectroscopic studies [Smith, A .L. Applied IR Spectroscopy: Fundamentals, Technique, Analyte. application / A. Smith; Per. from English B.N.Tarasevich. - M .: Mir, 1982.]. When the particle size is less than the probe radiation wavelength and the tablet thickness is small, the scattering in it is small, and it is relatively transparent in the IR range.

Known methods for creating transparent ceramic compositions, including those with high refractive indices. For example, transparent ceramic materials are obtained from ZnSe [A. Gallian, V. V. Fedorov, S. B. Mirov, V. V. Badikov, S. N. Galkin, Hot-pressed ceramic Cr2 +: ZnSe gain-switched laser. Optics Express (2006) 14 (24): 11694-11701.], [I. P. Shcherbakova, A. A. Dunaev, A. G. Kadomtseva, and A. E. Chmel, Impact Fracture of ZnSe Ceramics, PHYSICS OF THE SOLID STATE Vol. 58 No. 10 2016], [Hao Lu et al., Optical properties of transparent ZnSe0.9S0.1 mixed crystal ceramics prepared by hot isostatic pressing, Optical Materials, Volume 108, October 2020, 110214]. ZnS is also widely used to produce transparent ceramics [Roy Johnson et al., Zinc Sulfide Ceramics for Infrared Optics, Handbook of Advanced Ceramics and Composites. Springer, Cham. https://doi.org/10.1007/978-3-319-73255-8_16-1].

The technical problem of the claimed invention is to create an immersion medium with a refractive index n greater than 2.1 for observing the internal structure of transparent objects with similar refractive indices, including precious stones, as well as the problem of introducing optical radiation into such objects for their laser modification or for local photoexcitation.

The technical result consists in solving the specified technical problem.

The specified technical result is achieved in a method for creating a solid immersion medium for observing the internal structure of transparent objects with a high refractive index, which consists in the fact that a transparent object in a mold is covered with an immersion powder consisting of a solid with a refractive index n greater than 2.1, where n is an absolute refractive index, transform the immersion powder into a state of transparent solid ceramic by evacuating it, pressing and sintering; the mold with the specified immersion powder and the transparent object is cooled, the resulting solid immersion medium with the transparent object inside is removed from it; the internal structure of the transparent object is observed through the formed at least one optical window on the surface of the solid immersion medium.

An optical window is created on a solid immersion medium after it is converted into the form of a transparent ceramic by mechanical processing - grinding, polishing.

The optical window is created in the process of converting the immersion powder into the state of a transparent solid ceramic.

The immersion powder is added with an additive consisting of a powdery substance with a refractive index that differs from the refractive index of the specified immersion powder, with a concentration of the specified additive from 0.1 to 30% by volume, as a result, an effective refractive index of the solid immersion medium is obtained, lying in the range between the indices refraction of immersion powder and additives.

The claimed invention is illustrated using explanatory materials, where:

FIG. 1 - diagram of the refraction of rays at the boundary of the object.

FIG. 2 is a diagram of the implementation of the claimed invention.

When using an immersion composition, the refractive index on both sides of the interface is the same, so no refraction of the rays occurs (see Fig. 1).

The absence of refraction at the boundary allows visualizing the internal structure of an object, as well as introducing optical radiation into it.

Without the use of an immersion composition, the rays are refracted at a non-uniform boundary of an object, for example, a natural gemstone, due to the difference in refractive indices.

In addition to diamond, objects of observation can be other materials with a high refractive index, for which it is difficult to use "classical" liquid immersion compositions: cuprite (Cu2O, n = 2.848), proustite (Ag3AsS3, n = 2.792), cubic zirconia (ZrO2, n = 2, 17), anglesite (PbSO4, n = 1.877 - 1.894), etc.

To implement the method of observing the internal structure of transparent objects using a solid immersion medium, take a solid substance in the form of a powder (immersion composition) with a refractive index close to the refractive index of the object, for example, if the object is a diamond (refractive index 2.42), take zinc sulfide ZnS, or zinc selenide ZnSe (refractive index in the visible and near-IR spectral region 2.6-2.4).

Next, the specified immersion composition, for example, ZnSe, is taken in the form of a powder, then the object 1 (Fig. 2) is covered with the specified powder 2 in the mold 3, and then the powder is transferred to the state of a transparent ceramic, for example, by evacuating it, pressing it, and sintering 4. The mold is cooled, the resulting solid immersion medium 5 is removed from it with an object inside it, with at least one optical window formed. In this case, an optical contact is formed between the solid immersion medium and the object, and the transmitted rays 7 do not experience refraction.

The internal structure of the object is observed using standard microscopic techniques through the formed optical window on the surface of the immersion composition. Solid immersion medium provides this opportunity due to the absence of refraction of rays on the curved surface of the object.

Radiation is introduced into the object through a formed optical window on the surface of a solid immersion medium in the form of a converging, parallel, or diverging beam, depending on a specific technical problem. Due to the absence of refraction of rays on the curvilinear surface of the object, there is no distortion of the shape of the beam, and it continues to propagate inside the object practically unchanged.

Since the immersion compound is in the solid phase, there is no strong adhesion to the surface of the object. In addition, the immersion compound is generally less durable than the object and therefore can be easily removed mechanically. Alternatively, it can be removed chemically with a solvent that dissolves the solid immersion medium but does not affect the object.

Alternatively, the optical window 6 is created on a solid immersion medium after it is converted into the form of a transparent ceramic by mechanical processing - grinding, followed by chemical-mechanical polishing.

To control the refractive index of the immersion composition (if it is necessary to change the refractive index), a small amount of a substance with a higher or lower refractive index in the form of a powder is introduced into it as an additive (similar to the method used in IR spectroscopy). For example, KBr, traditionally used in IR spectroscopy. The amount is calculated individually, based on the required effective refractive index of the composition, for example, according to the formula of Maxwell Garnett or Bruggeman. The concentration of the specified additive can be from 0.1 to 30% by volume. The value of the refractive index of such a mixture lies between the values of the refractive indices of the components and depends on their volume fractions in accordance with the indicated formulas.

Claims (9)

1. A method of creating a solid immersion medium for observing the internal structure of transparent objects with a high refractive index, which consists in the fact that a transparent object in a mold is covered with an immersion powder consisting of a solid with a refractive index n greater than 2.1, where n is the absolute refractive index; transfer the immersion powder to the state of a transparent solid ceramic by evacuating it, pressing and sintering; the mold with the specified immersion powder and the transparent object is cooled; extract from it the resulting solid immersion medium with a transparent object inside it; the internal structure of the transparent object is observed through the formed at least one optical window on the surface of the solid immersion medium. 2. The method according to claim 1, characterized in that the optical window is created on a solid immersion medium after it is converted into the form of a transparent ceramic by mechanical processing - grinding, polishing. 3. The method according to claim 1, characterized in that the optical window is also created in the process of converting the immersion powder into the state of a transparent solid ceramic. 4. The method according to claim 1, characterized in that an additive is introduced into said immersion powder, consisting of a powdery substance with a refractive index that differs from the refractive index of said immersion powder, with a concentration of said additive from 0.1 to 30% by volume, in As a result, an effective refractive index of the solid immersion medium is obtained, lying in the range between the refractive indices of the immersion powder and the additive.

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