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Ultraviolet-transmittance and high-damage-threshold fluoride phosphate laser glass and preparation method thereof

A high damage threshold, fluorophosphate technology, applied in glass manufacturing equipment, glass furnace equipment, glass production, etc., can solve the problems of easy crystallization of fluoride glass, low triple frequency damage threshold, and difficulty in large-scale production. Achieve the effect of being suitable for large-scale mass production, high resistance to laser damage threshold, and improving load capacity

Active Publication Date: 2015-10-28
XI'AN INST OF OPTICS & FINE MECHANICS - CHINESE ACAD OF SCI
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0009] Aiming at the problems that the triple frequency damage threshold of quartz glass is low at present, and fluoride glass is easy to devitrify and difficult to produce in large size, etc., the present invention proposes a composition and preparation method of a novel UV-transparent, high damage threshold fluorophosphate laser glass

Method used

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  • Ultraviolet-transmittance and high-damage-threshold fluoride phosphate laser glass and preparation method thereof
  • Ultraviolet-transmittance and high-damage-threshold fluoride phosphate laser glass and preparation method thereof
  • Ultraviolet-transmittance and high-damage-threshold fluoride phosphate laser glass and preparation method thereof

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Effect test

Embodiment 1

[0039] According to the above recipe 1 # Calculate the weight percent of the glass from the molar composition in the glass, then weigh a total of 25Kg of raw materials, and mix them uniformly in the mixing box. Add the prepared powder into the 11-liter platinum crucible in turn, and heat and melt it through a silicon carbide electric furnace. The melting temperature is controlled at about 1280 ° C, and the melting time is 6 hours. The liquid is stirred. After the glass liquid has been clarified to remove air bubbles and fully stirred evenly, the high-temperature glass liquid is injected into the copper mold preheated to 300°C through the leak nozzle at the bottom of the crucible to form a glass blank, and the formed glass sample is quickly demolded and placed in the Has been heated to the annealing temperature (set at the transition temperature T of the glass g In the muffle furnace nearby), after 12 hours of heat preservation, the temperature is lowered to 100°C at a coolin...

Embodiment 2

[0044] According to the above recipe 2 # Calculate the weight percent of the glass from the molar composition in the glass, then weigh a total of 25Kg of raw materials, and mix them uniformly in the mixing box. Add the prepared powder into the 11-liter platinum crucible in turn, and heat and melt it through a silicon carbide electric furnace. The melting temperature is controlled at about 1280 ° C, and the melting time is 6 hours. The liquid is stirred. After the glass liquid has been clarified to remove air bubbles and fully stirred evenly, the high-temperature glass liquid is injected into the copper mold preheated to 300°C through the leak nozzle at the bottom of the crucible to form a glass blank, and the formed glass sample is quickly demolded and placed in the Has been heated to the annealing temperature (set at the transition temperature T of the glass g In the muffle furnace nearby), after 12 hours of heat preservation, the temperature is lowered to 100°C at a coolin...

Embodiment 3

[0048] According to the above recipe 3 # Calculate the weight percent of the glass from the molar composition in the glass, then weigh a total of 25Kg of raw materials, and mix them uniformly in the mixing box. Add the prepared powder into the 11-liter platinum crucible in turn, and heat and melt it through a silicon carbide electric furnace. The melting temperature is controlled at about 1280 ° C, and the melting time is 6 hours. The liquid is stirred. After the glass liquid has been clarified to remove air bubbles and fully stirred evenly, the high-temperature glass liquid is injected into the copper mold preheated to 300°C through the leak nozzle at the bottom of the crucible to form a glass blank, and the formed glass sample is quickly demolded and placed in the Has been heated to the annealing temperature (set at the transition temperature T of the glass g In the muffle furnace nearby), after 12 hours of heat preservation, the temperature is lowered to 100°C at a coolin...

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Abstract

The invention provides high-damage-threshold fluoride phosphate laser glass as a material for preparing an ultraviolet-transmittance window, and a preparation method of the high-damage-threshold fluoride phosphate laser glass. The preparation method comprises the steps of adopting an alkali metal oxide, an alkaline earth metal oxide, alumina, zinc oxide and phosphoric pentoxide as main raw materials, adding a small amount of rare earth fluoride, molding and preparing glass pressing blanks based on the drip injection method after the treatments of high-temperature melting, clarification and homogenizing, and finally obtaining the high-damage-threshold fluoride phosphate laser glass material through the annealing treatment. The fused quartz material can be replaced by the above glass material for preparing lenses, plane windows, prisms and other optical components applied to high-energy and high-power laser systems. In this way, the laser-induced damage problems of ultraviolet optical components made of the fused quartz material in existing high-energy and high-power laser systems can be solved. The load output capability of a laser is further improved. Therefore, the above material can be used for preparing the ultraviolet-transmittance optical components of high-power lasers for laser-driven inertial confinement fusion experiments.

Description

technical field [0001] The invention belongs to the technical field of laser glass materials, and in particular relates to a fluorophosphate laser glass material with an ultraviolet transmission and high damage threshold and a preparation method thereof. Background technique [0002] The development of clean new energy is an urgent task for the survival and development of human beings, and it is also a major issue of priority for my country to implement the sustainable development strategy. Laser-driven inertial confinement nuclear fusion is an important means to achieve controlled nuclear fusion, which can provide human beings with inexhaustible energy, and is a potential important way to solve the current global energy crisis and alleviate the greenhouse effect. The dawn of new energy. At the same time, laser-driven inertial confinement fusion has important theoretical significance and practical value for basic research in strong field physics, laser plasma, high energy d...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C03C3/247C03B5/187C03B19/02
CPCY02P40/57
Inventor 王鹏飞彭波陆敏高飞
Owner XI'AN INST OF OPTICS & FINE MECHANICS - CHINESE ACAD OF SCI
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