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Dysprosium and terbium co-doped scandium-containing garnet laser crystal and its preparation method and application of ld pumping the crystal to realize yellow laser output

A technology of laser crystal and garnet, which is applied in the direction of lasers, crystal growth, laser components, etc., can solve the problems of low stimulated emission cross section, low thermal conductivity, high laser threshold, etc., and achieve the effect of lower threshold and high thermal conductivity

Active Publication Date: 2022-04-29
ANHUI UNIVERSITY OF TECHNOLOGY
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  • Abstract
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AI Technical Summary

Problems solved by technology

[0004] The single-doped Dy pumped by GaN blue light LD has been reported so far 3+ Laser crystals have fewer crystals that obtain yellow laser output, mainly Dy:YAG, because Dy 3+ Particles with lower stimulated emission cross-sections and lower laser energy levels cannot relax rapidly to the ground state, resulting in high laser threshold
Furthermore, the vast majority of Dy 3+ Doped yellow laser crystals have low thermal conductivity and are unbearable due to Dy 3+ Low absorption and emission cross sections necessitate high pump power waste heat issues

Method used

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  • Dysprosium and terbium co-doped scandium-containing garnet laser crystal and its preparation method and application of ld pumping the crystal to realize yellow laser output
  • Dysprosium and terbium co-doped scandium-containing garnet laser crystal and its preparation method and application of ld pumping the crystal to realize yellow laser output
  • Dysprosium and terbium co-doped scandium-containing garnet laser crystal and its preparation method and application of ld pumping the crystal to realize yellow laser output

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0044] Example 1: Dy 3+ ,Tb 3+ Co-doped scandium-containing garnet laser crystal Dy,Tb:YSAG

[0045] Growth Dy 3+ Doping concentration is 2at%, Tb 3+ Doping concentration of 1at% Dy 0.06 Tb 0.03 Y 2.91 sc 2 Al 3 o 12 crystals. Dy in this embodiment 3+ The concentration is 2at%, Tb 3+ The doping concentration is 1at%, that is, the molecular formula Dy x Tb y A 3-x-y sc 2 B 3 o 12 Wherein x=0.06, y=0.03, A is Y in the component, B is Al.

[0046] The preparation method is as follows: the high-purity oxide raw material is used according to the chemical reaction formula:

[0047] 0.03 Dy 2o 3 +0.0075Tb 4 o 7 +1.455Y 2 o 3 +Sc 2 o 3 +1.5Al 2 o 3

[0048] = Dy 0.06 Tb 0.03 Y 2.91 sc 2 Al 3 o 12 +0.00375O 2

[0049] Accurately weigh a total of 610g, then uniformly mix the raw materials and briquette, and use high-temperature solid-phase method to sinter at 1400°C for 48 hours to obtain Dy 0.06 Tb 0.03 Y 2.91 sc 2 Al 3 o 12 Polycrystalline ra...

Embodiment 2

[0051] Example 2: GaN LD pumping Dy x Tb y A 3-x-y sc 2 B 3 o 12 Crystal Realizes Yellow Laser Output

[0052] A GaN laser diode with an output wavelength of 450nm is used as the pump source, and the end-pumped Dy x Tb y A 3-x-y sc 2 B 3 o 12 Crystal element, the element size is 3×3×10mm 3 , the two end faces have a very high degree of parallelism and are finely polished. The laser experiment device is attached Figure 5 shown. The laser resonator adopts a flat cavity structure, and the cavity mirror is composed of an input coupling mirror M1 and an output coupling mirror M2; the M1 mirror is coated with a 450nm antireflection coating and a 585nm high reflection coating, and the M2 mirror is coated with a 585nm partially transparent coating. 3-5%; the distance between M1 and M2 is 2cm-4cm. The laser output from the GaN LD is focused by the lens and then passes through M1 and is vertically incident on the crystal end face. Dy in the crystal 3+ The ions absorb th...

Embodiment 3

[0053] Example 3: Dy 3+ ,Tb 3+ Co-doped scandium-containing garnet laser crystal Dy,Tb:LuSAG

[0054] Growth Dy 3+ Doping concentration is 1at%, Tb 3+ Doping concentration of 1at% Dy 0.03 Tb 0.03 Lu 2.94 sc 2 Al 3 o 12 crystals. Dy in this embodiment 3+ The concentration is 1at%, Tb 3+ The doping concentration is 1at%, that is, the molecular formula Dy x Tb y A 3-x-y sc 2 B 3 o 12 Where x=0.03, y=0.03, A is Lu and B is Al in the components. The preparation method is as follows: the high-purity oxide raw material is used according to the chemical reaction formula:

[0055] 0.015 Dy 2 o 3 +0.0075Tb 4 o 7 +1.47Lu 2 o 3 +Sc 2 o 3 +1.5Al 2 o 3

[0056] = Dy 0.03 Tb 0.03 Lu 2.94 sc 2 Al 3 o 12 +0.00375O 2

[0057] Accurately weigh a total of 905g, then uniformly mix the raw materials and briquette, and use high-temperature solid-phase method to sinter at 1400°C for 48 hours to obtain Dy 0.03 Tb 0.03 Lu 2.94 sc 2 Al 3 o 12 Polycrystalline ra...

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Abstract

The present invention discloses dysprosium and terbium co-doped scandium-containing garnet laser crystal and its preparation method and the application of LD pumping the crystal to realize yellow laser output. The crystal chemical expression is Dy x Tb y A 3‑x‑ y sc 2 B 3 o 12 ; Prepare Dy by solid-phase method or liquid-phase method x Tb y A 3‑x‑ y sc 2 B 3 o 12 Polycrystalline raw material, after which Dy is grown by melt method x Tb y A 3‑x‑y sc 2 B 3 o 12 Single crystal; using GaN LD as pumping light source, pumping Dy x Tb y A 3‑x‑y sc 2 B 3 o 12 Crystal realizes yellow laser output. In the present invention, dysprosium and terbium are used as active ions, and Dy 3+ with Tb 3+ Resonant energy transfer between the Dy 3+ lower laser level 6 h 13 / 2 Particles on Tb are transferred to Tb by 3+ ion 7 f 4 energy level, so that Dy 3+ It is easier to achieve particle number inversion and reduce the threshold of yellow laser; use scandium-containing garnet laser crystal as the host crystal, so that Dy 3+ It is easy to realize the inverse number of particles, and the crystal has high thermal conductivity, which can endure due to the Dy 3+ The lower absorption and emission cross-sections necessitate the use of high pump powers resulting in waste heat problems.

Description

technical field [0001] The invention relates to the technical field of laser crystals, in particular to a dysprosium and terbium co-doped scandium-containing garnet laser crystal, a preparation method thereof, and an application of LD pumping the crystal to realize yellow laser output. Background technique [0002] The yellow laser with a wavelength of 550-600nm belongs to the most sensitive wavelength band of the human eye, so it has important applications in the fields of laser display and laser lighting, especially for space measurement and indication in heavy fog environments. In addition, yellow laser is widely used in many fields, such as the treatment of skin and eye diseases, the detection and identification of space targets, photoelectric countermeasures, high-density information storage, ocean detection and other industrial, national defense and scientific research fields. . At present, there are three main ways to realize yellow laser: dye laser, dual wavelength ...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): C30B29/22H01S3/16
CPCC30B29/22H01S3/164
Inventor 丁守军刘文鹏黄仙山任浩李泓沅
Owner ANHUI UNIVERSITY OF TECHNOLOGY
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