Method for preparing praseodymium-doped ion exchange aluminate and germanate glass waveguide

A technology of aluminum germanate and doping ions, which is applied in the field of preparation of rare earth doped optical devices, can solve the problems of high cost of photodynamic therapy equipment, damage to human healthy tissues, and limited lifespan, so as to ensure uniformity and transparency, Good chemical stability, the effect of improving moldability

Inactive Publication Date: 2012-12-05
DALIAN POLYTECHNIC UNIVERSITY
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, these irradiation light sources all have certain deficiencies. Although the laser has the advantages of good monochromaticity and easy transmission through optical fibers, its power density is too high. Once the target positioning error occurs, it will damage human healthy tissues, cause inflammation, Burns and swelling, and the high cost and limited lifespan of lasers make photodynamic therapy equipment expensive to use
Using high-power, multi-wavelength LEDs as irradiation light sources is an effective means of treating skin tumors and skin surface diseases such as port wine stains, acne, and condyloma acuminatum. On the surface of the skin, unable to reach the inside of the body
In addition, the LED light source can only output light of a single central wavelength, which makes it difficult to simultaneously excite several photosensitive drugs, which seriously restricts the therapeutic effect.

Method used

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  • Method for preparing praseodymium-doped ion exchange aluminate and germanate glass waveguide
  • Method for preparing praseodymium-doped ion exchange aluminate and germanate glass waveguide
  • Method for preparing praseodymium-doped ion exchange aluminate and germanate glass waveguide

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0041] (1) Adopt the following molar ratio: sodium carbonate (Na 2 CO 3 ): Magnesium Oxide (MgO): Aluminum Oxide (Al 2 o 3 ): germanium oxide (GeO 2 )=25:2:20:53, weigh the above matrix raw materials, and weigh 0.1% of the total mass of matrix raw materials for praseodymium oxide (Pr 6 o 11 ) as a dopant, the purity of all raw materials is 99.99%, and the specific ingredients are shown in Table 1.

[0042] Table I

[0043] raw material

Na 2 CO 3

MgO

Al 2 o 3

GeO 2

PR 6 o 11

mass (g)

8.744

0.266

6.729

18.301

0.034

[0044] (2) Put the raw materials weighed according to the method described in step (1) into an agate mortar and mix them thoroughly. After they are evenly mixed, pour them into a pure alumina crucible and place them in a box-type resistance furnace. Min heating rate, the temperature was raised to 500°C, and then the temperature was continued to rise at a rate of 5°C / min. T...

Embodiment 2

[0050] (1) Adopt the following molar ratio: sodium carbonate (Na 2 CO 3 ): Magnesium Oxide (MgO): Aluminum Oxide (Al 2 o 3 ): germanium oxide (GeO 2 )=22:2:24:50, weigh the above matrix raw materials, and weigh praseodymium oxide (Pr 6 o 11 ) as a dopant, the purity of all raw materials is 99.99%, and the specific ingredients are shown in Table 2.

[0051] Table II

[0052] raw material

Na 2 CO 3

MgO

al 2 o 3

GeO 2

PR 6 o 11

mass (g)

7.695

0.532

8.075

17.265

0.336

[0053] (2) Put the raw materials weighed according to the method described in step (1) into an agate mortar and mix them thoroughly. After they are evenly mixed, pour them into a pure alumina crucible and place them in a box-type resistance furnace. Min heating rate, the temperature was raised to 500°C, and then the temperature was continued to rise at a rate of 5°C / min. The furnace was cooled to room temperature (approxi...

Embodiment 3

[0059] (1) Select the glass sample prepared in Example 2, process it into a glass substrate with a size of 3cm×1.5cm×0.1cm and smooth surfaces on both sides, and first place the glass substrate in a trichloroethane solution for Ultrasonic cleaning for ten minutes to clean the surface oil; then immerse the substrate in acetone solution for five minutes to remove trichloroethane; then immerse the substrate in isopropanol for five minutes to remove residual acetone; finally rinse off the isopropyl with deionized water To remove residual stains from alcohol, dry the surface of the substrate with nitrogen.

[0060] (2) Potassium nitrate (KNO 3 ) The quartz crucible of molten salt is placed in an ion exchange furnace. After the temperature rises to 380°C and stabilizes, the glass substrate treated in step (1) is immersed in molten salt for ion exchange to prepare a planar optical waveguide. The ion exchange time for 2-6 hours. After the ion exchange process, the glass substrate is...

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Abstract

The invention discloses a method for preparing a praseodymium-doped ion exchange aluminate and germanate glass waveguide. The method includes melting praseodymium-doped aluminate and germanate glass at first, processing the melted praseodymium-doped aluminate and germanate glass into a glass substrate, evaporating an aluminum coating on the glass substrate, and opening an ion exchange window with the width ranging from 8 micrometers to 50 micrometers on the surface of the glass substrate by micro-machining technique and a wet chemical corrosion method; and soaking the glass substrate in potassium nitrate melted salt or mixed molten salt of silver nitrate and potassium nitrate to exchange ions, washing the melted salt and the aluminum coating which are remained on the surface of the glass substrate, and then polishing the washed glass substrate to obtain the praseodymium-doped ion exchange aluminate and germanate glass waveguide. The method solves the problem that effective radiative transition of rare earth ions cannot be realized due to high energy of phonons of an oxide glass waveguide, and spontaneous radiation fluorescence is continuously amplified by praseodymium ions in a visible light wavelength range for the first time. The method has a good application prospect in fields of minimally-invasive photodynamic cancer therapy, laser, communication, lighting and the like.

Description

technical field [0001] The invention belongs to the field of preparation of rare earth-doped optical devices, and in particular relates to a preparation method of a praseodymium-doped ion-exchanged aluminogermanate glass waveguide. Background technique [0002] Photodynamic therapy, as an emerging and effective method for cancer treatment, is becoming increasingly popular due to its advantages of low toxicity, little damage to normal tissues; cold photochemical reaction, which does not affect other treatments; repeated medication, no drug tolerance, etc. s concern. This method refers to the use of light of appropriate wavelengths under the premise of the presence of oxygen molecules to induce a series of photodynamic reactions of anticancer photosensitive drugs that are preferentially enriched in tumor lesions, and promote the transformation of oxygen molecules into singlet oxygen, thereby destroying tumor tissue. , to kill cancer cells. As a key device for photodynamic th...

Claims

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Application Information

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IPC IPC(8): G02B6/122G02B6/134C03C3/253C03C17/09C03C21/00C03B27/03
Inventor 林海赵昕刘潇
Owner DALIAN POLYTECHNIC UNIVERSITY
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