Development of high-precision beam splitter for inter-satellite communication system
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摘要:
随着星间通信系统的迅速发展,数据传输的精度要求不断提高。分光镜作为系统的核心元件,其光谱特性和面形精度直接影响整个系统的传输精度。本文基于薄膜干涉理论,选取Ta2O5与SiO2作为高低折射率膜层材料进行膜系设计,采用电子束蒸发的方式在石英基板上制备高精度分光镜。同时根据膜层应力补偿原理建立面形修正模型,修正分光镜面形。经光谱分析仪检测,分光镜在入射角度为21.5°~23.5°范围内,1563 nm透过率大于98%,1540 nm反射率大于99%。经 干涉仪检测,分光镜反射面形精度RMS由λ/10修正至λ/90(λ=632.8 nm),透过面形精度RMS为λ/90。
Abstract:With the rapid development of inter-satellite communication systems, the requirements for data transmission accuracy are constantly increasing. As the core component, the spectral characteristics and surface shape accuracy of the beam splitter directly affect the transmission accuracy of the whole system. In this paper, based on the interference theory of thin film, Ta2O5and SiO2were selected as the high and low refractive index film materials for the design of the film system, and electron beam evaporation was used to prepare a high-precision beam splitter on a quartz substrate. At the same time, a surface shape correction model was established based on the principle of film stress compensation to control the surface shape. Through the detection of a spectral analyzer, the transmittance of beam splitter is greater than 98% at 1563 nm and the reflectance is greater than 99% at 1540 nm within the incidence range of 21.5° to 23.5°. The surface shape was measured by laser interferometer, the reflective surface shape accuracy RMS is corrected from λ/10 to λ/90 (λ=632.8 nm), and the transmissive optical surface shape accuracy RMS is λ/90.
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图 3薄膜应力(a)张应力(b)压应力
Figure 3.Thin film stress (a) Tensile stress (b) Compressive stress
图 5基底的矢高与曲率半径示意图
Figure 5.Schematic diagram of the Power and radius curvature of the substrate
图 9样品Power改变量随沉积SiO2厚度变化的拟合曲线
Figure 9.Fitting curve of the change in sample Power with the thickness of deposited SiO2
表 1材料沉积工艺参数
Table 1.Material deposition process parameters
材料 沉积速率/(nm·s−1) 起始真空度/(×10−4Pa) 沉积温度/(°C) Ta2O5 0.4 7 220 SiO2 0.6 7 220 
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表 2不同离子源工艺参数沉积的SiO2薄膜对样品的Power改变量
Table 2.Change in Power of samples by SiO2films deposited by different ion source process parameters
编号 电压/V 束流/mA 面形图 ∆power(λ) 基底 沉积后 1 1 100 950 
0.148 5 2 1 000 920 
0.160 2 3 950 900 
0.182 1 下载:
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表 3离子源工艺参数
Table 3.Process parameters of ion source
材料 电压/
V束流/
mA气体 O2/
Sccm气体 Ar/
SccmTa2O5 1 100 950 50 8 SiO2(直控) 1 100 950 50 8 SiO2(背反) 950 900 50 8 SiO2(晶控) 950 900 50 8 下载:
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表 4样品沉积分光膜的面形结果
Table 4.Surface shape results of sample deposited beam splitter
类别 编号 1# 2# 3# 4# 基底 面形图 
PV(λ) 0.074 6 0.076 1 0.077 4 0.072 3 RMS(λ) 0.008 7 0.009 2 0.009 7 0.008 3 Power(λ) 0.007 3 0.008 1 0.008 4 0.007 8 沉积后 面形 
PV(λ) 0.516 7 0.528 9 0.531 6 0.515 3 RMS(λ) 0.111 8 0.111 6 0.111 4 0.111 9 Power(λ) −0.385 9 −0.383 9 −0.382 7 −0.3854 下载:
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表 5样品Power改变量与A值随沉积SiO2膜层厚度变化的数据
Table 5.Data on the variation of sample Power change andA-value with the thickness of deposited SiO2film
SiO2厚度(nm) ∆Power(λ) A(∆λ/100 nmSiO2) 3 500 0.155 1 0.004 43 5 000 0.228 0 0.004 56 6 500 0.308 8 0.004 75 8 000 0.394 4 0.004 93 9 500 0.488 3 0.005 14 下载:
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表 6修正前后样品的面形参数
Table 6.Surface parameters of samples before and after correction
类别 面形图 PV(λ) RMS(λ) Power(λ) 修正前 
0.531 6 0.111 4 −0.382 7 修正后 
0.121 9 0.016 2 −0.042 9 下载:
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表 7修正前后的面形参数与面形图
Table 7.Surface parameters and surface profile before and after correction
类别 面形图 PV(λ) RMS(λ) Power(λ) 基底 
0.0723 0.0083 0.0078 修正前( 反射面形) 
0.5153 0.1119 −0.3854 修正后(反射面形) 
0.0888 0.0107 −0.0153 修正前(透过面形) 
0.0694 0.0097 0.0136 修正后(透过面形) 
0.0783 0.0103 0.0141 下载:
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