RU2682563C1 - Single-mode crystalline infrared light guide - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to single-mode crystalline IR light guides, which are designed to deliver IR radiation of medical solid-state lasers with a parametric frequency conversion at a wavelength of 5.75 microns. Single-mode crystalline infrared light guide includes a core and a shell made of silver chloride-bromide solid solutions. Core with a diameter of 48.0–52.0 mcm is made with a central rod in it with a diameter of 11.0–13.0 mcm, the shell is made with an outer diameter of 95.0–105.0 mcm with six rods with a diameter of hexagonal in it 11.0–13.0 mcm at a distance of 30.0–32.0 mcm between their centers, while the central core contains ingredients in the following ratio, wt.%: silver chloride 83.0–83.9; silver bromide 17.0–16.1, the core and the shell are made of crystals of solid solutions in the following ratio, wt.%: silver chloride 81.3–82.1; silver bromide 18.7–17.9, rods in the shell have the composition in the following ratio of components, wt.%: silver chloride 79.6–80.4; silver bromide 20.4–19.6.EFFECT: provision of opportunities for timely implementation of minimally invasive intravascular operations.1 cl, 1 dwg

Description

The invention relates to single-mode crystalline IR optical fibers, which are intended for the delivery of IR radiation from medical solid-state lasers with parametric frequency conversion at a wavelength of 5.75 μm [N.A. Kalintseva, V.A. Serebryakov. Fiber delivery systems for medical mid-IR lasers: requirements and parameters. Electronic publication Laser-X-2017-15.pdf. Collection of reports of the X All-Russian School for students, graduate students, young scientists and specialists in laser physics and laser technology. S. 81-87].

Instead of solid-state lasers, a CO gas laser (5-6 μm) can be used as a source of IR radiation. The selective absorption band of cholesterol essential fatty acids, which are part of atherosclerotic plaques, lies precisely at a wavelength of 5.75 microns, while the vascular wall itself does not absorb. Therefore, it becomes possible to timely conduct minimally invasive intravascular operations (indirect treatment and prevention of coronary heart disease) [V.A. Serebryakov, E.V. Boyko, N.M. Petrishchev, A.V. Yang. Medical use of mid-infrared lasers. Problems and prospects. Optical Magazine. 2010. 77, 1. S. 9-23, S. Suzuki-Yoshihashi, S. Yamada, I. Sato, K. Awazu. A novel laser angioplasty using hollow fiber - guided min infrared laser. Proc. of SPIE. 2006, Vol. 6083. P. 60830I-1].

Known optical fiber for the infrared region of the spectrum [RF Patent No. 2174247 from 09/27/01. The optical fiber for the infrared region of the spectrum // Zhukova LV, Zelyansky AV, Zhukov VV, Kitaev GA], which consists of a core based on solid solutions of AgCl-AgBr-AgI, taken in certain ratios , and a reflective shell based on solid solutions of the AgCl-AgBr system of a certain composition. But this two-layer fiber is multimode and is designed to operate at a wavelength of 10.6 microns.

Known infrared fiber based on silver halides. The core of the fiber is made of silver bromide, and the sheath is made of silver bromide with the inclusion of silver chloride. But the fiber is modeled in such a way that it transmits 12 modes at a wavelength of 10.6 μm, and not one mode, i.e. is multimode [E. Rave, A. Katzir. Mid-IR photonics crystal fibers. Book of Abstract of 6 ^th international conference on "Mid-Infrared optoelectronics materials and devices", St. Petersburg, Russia, 2004, P. 57-58].

Known two-layer halide silver fibers with a small core diameter, designed to transmit radiation in the mid-IR range of the spectrum. However, the authors give only a theoretical assessment of a single-mode fiber and do not provide specific data on its production [Sh. Shalem, A. Katzir. Silver halide Mid-IR transmitting core / clad fibers wish small cores. Mid-IR photonics crystal fibers, Book of Abstract of 6 ^th international conference on "Mid-Infrared optoelectronics materials and devices", St. Petersburg, Russia, 2004, P. 145-146].

The closest technical solution as a prototype is a single-mode crystalline infrared fiber [RF Patent No. 2340921 from 12/10/2008 / Zhukova LV, Examples N.V., Chazov A.I., Korsakov A.S.], based on solid silver chloride bromide solutions. The core has a diameter of 20-110 microns and contains the ingredients in the following ratio in wt. %: silver chloride 19.0-21.0; silver bromide 81.0-79.0. The shell contains the same ingredients in the following ratio in wt. %: silver chloride 25.0-35.0; silver bromide 75.0-65.0.

Technically, the obtained fibers are designed to operate in a wide spectral range (3.0-30 microns).

But the prototype provides examples of IR optical fibers for operating at wavelengths of 10.6 μm and 30.0 μm, and it is indicated that when the working wavelength of the fiber is shifted to the IR range (up to 30.0 μm), the core diameter increases significantly. Thus, the shorter the wavelength, the smaller the core diameter, and this complicates the introduction of infrared radiation into the fiber, leads to loss of transmitted energy, and also complicates the coupling of the fiber with the optical elements of the fiber optic system.

There is a problem of obtaining an optimal fiber structure for maintaining a single-mode regime at a wavelength of 5.75 μm with a maximum core diameter of up to 50 μm (mode field diameter). The IR fiber is designed to deliver radiation at a specified wavelength of medical surgical tunable lasers, in particular solid-state lasers with parametric frequency conversion.

A single-mode crystalline infrared fiber including a core and a sheath made on the basis of solid solutions of silver chloride-bromide, characterized in that the core with a diameter of 48.0-52.0 μm is made with a central rod in it with a diameter of 11.0-13.0 μm, the shell is made with an outer diameter of 95.0-105.0 μm with six rods located in it in hexagonal order with a diameter of 11.0-13.0 μm at a distance of 30.0-32.0 μm between their centers, while the central rod contains ingredients in the following ratio, wt. %:

silver chloride 83.0-83.9;

silver bromide 17.0-16.1,

the core and shell are made of crystals of solid solutions in the following ratio of components, wt. %:

silver chloride 81.3-82.1;

silver bromide 18.7-17.9,

the rods in the shell have a composition in the following ratio of components, wt. %:

silver chloride 79.6-80.4;

silver bromide 20.4-19.6.

The problem of delivering and focusing the infrared radiation of medical surgical lasers to a biological object at a wavelength of 5.75 μm (angioplasty) using a new fiber structure of single-mode flexible IR optical fibers made of non-toxic and plastic crystals of solid solutions of the AgCl-AgBr system (see examples and drawing).

The fiber shown in the drawing delivers IR radiation up to 50.0% at a wavelength of 5.75 μm due to the chemical composition and structure of the fiber with an outer sheath diameter D = 100.0 ± 5.0 μm, in which a core with a diameter of MFD = 50 is placed , 0 ± 2.0 μm with a central rod with a diameter of d = 12.0 ± 1.0 μm and six rods of the same diameter in the shell, located in hexagonal order at a distance between their centers A = 31.0 ± 1.0 μm.

The use of new single-mode optical fibers solves the problem of minimally invasive intravascular operations (removal of atherosclerotic plaques) without damaging the vessel wall, because the vascular wall itself (its composition) does not absorb at a given wavelength. This cannot be achieved using a two-layer fiber presented in the prototype.

Example 1

A single-mode IR fiber was manufactured by extrusion of an external diameter of 95.0 μm and a core with a diameter of 48.0 μm, into which a rod with a diameter of 11.0 μm was placed. Six rods of the same diameter are placed in the shell, located in hexagonal order at a distance of 30.0 μm between their centers.

A survey of the outgoing radiation from the end of the fiber in a far field with a power of 5 W was carried out. A tunable CO laser at a wavelength of 5.75 μm was used as a radiation source. The radiation has the form of a Gaussian function, which confirms the single-mode operation. The area of the mode field is 1805 μm ² .

Example 2

A single-mode IR optical fiber was manufactured by extrusion. The fiber structure consists of a sheath with a diameter of 100.0 μm, in which rods with a diameter of 12.0 μm are placed in hexagonal order at a distance of 31.0 μm between their centers. A core with a diameter of 50.0 μm with a central rod with a diameter of 12.0 μm is placed in the shell.

As in example 1, a survey was conducted of the outgoing radiation from the end of the fiber and the single-mode operation at a wavelength of 5.75 μm at 1960 μm ² of the mode field area was confirmed.

Example 3

Based on crystals of the AgCl-AgBr system, a single-mode IR optical fiber was manufactured by extrusion. The structure of the fiber: the central rod with a diameter of 13.0 μm, the core with a diameter of 52.0 μm, the sheath with a diameter of 105.0 μm, the rods in the sheath (d = 13.0 μm) are located in hexagonal order at a distance of 31.0 μm between their centers.

As a radiation source at a wavelength of 5.75 microns, a CO laser was used. The radiation emerging from the end of the fiber in the far field has the form of a Gaussian function, which indicates the existence of a single fundamental mode of a lower order. The density of the mode field is 2115.0 μm ² .

In the manufacture of crystalline IR optical fibers that do not correspond to the compositions and structure shown in the examples, a multimode mode of operation is observed.

Technical result

что соответствует диаметру MFD=50,0±2,0 мкм и величине площади поля моды 1960±155 мкм². Определены параметры микроструктуры: диаметр стержней в оболочке и расстояние между их центрами.The structure diagram of the fiber and the distribution of the z-component of the light vector are presented in the drawing. The light flux density S in the core satisfies the condition

which corresponds to a diameter of MFD = 50.0 ± 2.0 μm and a magnitude of the mode field area of 1960 ± 155 μm ² . The microstructure parameters are determined: the diameter of the rods in the shell and the distance between their centers.

Due to the combination of distinctive features in the structure of the IR fiber compared to the prototype, namely, the presence of a central defect (rod) with a large refractive index (n = 2,135) than the matrix material (core and cladding, n = 2,129) and rods in the cladding with a smaller ( n = 2.125) than the matrix material, a single-mode crystalline IR optical fiber is obtained, which is used as a channel for transmitting radiation strictly at a wavelength of 5.75 microns of medical lasers. In addition, the outer diameter of the IR fiber is 100.0 ± 5.0 μm, which expands the possibilities of use in narrower vessels.

Claims (6)

A single-mode crystalline infrared fiber including a core and a sheath made on the basis of solid solutions of silver chloride-bromide, characterized in that the core with a diameter of 48.0-52.0 μm is made with a central rod in it with a diameter of 11.0-13.0 μm, the shell is made with an outer diameter of 95.0-105.0 μm with six rods located in it in hexagonal order with a diameter of 11.0-13.0 μm at a distance of 30.0-32.0 μm between their centers, while the central rod contains ingredients in the following ratio, wt.%: silver chloride 83.0-83.9 silver bromide 17.0-16.1 the core and shell are made of crystals of solid solutions in the following ratio of components, wt.%: silver chloride 81.3-82.1 silver bromide 18.7-17.9 the rods in the shell have a composition in the following ratio of components, wt.%: silver chloride 79.6-80.4 silver bromide 20,4-19,6

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