激光与红外
激光與紅外
격광여홍외
LASER & INFRARED
2014年
10期
1095-1099
,共5页
激光光学%光致旋转%自旋角动量%旋转频率
激光光學%光緻鏇轉%自鏇角動量%鏇轉頻率
격광광학%광치선전%자선각동량%선전빈솔
laser optics%optical rotation%spin angular momentum%rotation frequency
从理论上讨论了双折射晶体微粒与圆偏振光束作用的基本过程,建立了由于光束自旋角动量向双折射晶体微粒的转移所引起的旋转现象的物理模型。为提高晶体微粒的旋转频率,从理论和实验两方面对CaCO3和SiO2晶体微粒的厚度与其旋转频率的关系进行了详细分析。基于MATLAB软件分别模拟出双折射晶体微粒的厚度与其旋转频率的正弦关系曲线,并通过实验测得相应的晶体旋转频率数据进行验证。结果表明,在有效激光功率为10 mW的条件下 CaCO3和 SiO2双折射晶体微粒的最大旋转频率分别为1.7 Hz 和1.5 Hz。该结果可用于光致旋转在微机械设计中转子厚度的选择和其旋转频率的最优化控制。
從理論上討論瞭雙摺射晶體微粒與圓偏振光束作用的基本過程,建立瞭由于光束自鏇角動量嚮雙摺射晶體微粒的轉移所引起的鏇轉現象的物理模型。為提高晶體微粒的鏇轉頻率,從理論和實驗兩方麵對CaCO3和SiO2晶體微粒的厚度與其鏇轉頻率的關繫進行瞭詳細分析。基于MATLAB軟件分彆模擬齣雙摺射晶體微粒的厚度與其鏇轉頻率的正絃關繫麯線,併通過實驗測得相應的晶體鏇轉頻率數據進行驗證。結果錶明,在有效激光功率為10 mW的條件下 CaCO3和 SiO2雙摺射晶體微粒的最大鏇轉頻率分彆為1.7 Hz 和1.5 Hz。該結果可用于光緻鏇轉在微機械設計中轉子厚度的選擇和其鏇轉頻率的最優化控製。
종이론상토론료쌍절사정체미립여원편진광속작용적기본과정,건립료유우광속자선각동량향쌍절사정체미립적전이소인기적선전현상적물리모형。위제고정체미립적선전빈솔,종이론화실험량방면대CaCO3화SiO2정체미립적후도여기선전빈솔적관계진행료상세분석。기우MATLAB연건분별모의출쌍절사정체미립적후도여기선전빈솔적정현관계곡선,병통과실험측득상응적정체선전빈솔수거진행험증。결과표명,재유효격광공솔위10 mW적조건하 CaCO3화 SiO2쌍절사정체미립적최대선전빈솔분별위1.7 Hz 화1.5 Hz。해결과가용우광치선전재미궤계설계중전자후도적선택화기선전빈솔적최우화공제。
In the paper,the basic process of the interaction between the laser beam and the birefringent crystal particle is discussed theoretically,and physical model of optical rotation due to the transfer of spin angular momentum from the laser beam to particle is established.For improving rotation frequency of crystal particle,the relation between rotation frequency and thickness of CaCO3 和SiO2 crystal particle was analyzed in theoretical research and experimental re-search.The sine relation curve between CaCO3 and SiO2 particle’s rotation frequency and thickness was simulated with MATLAB software,and the results show that experimental curve of rotation frequency and thickness is the period-ic sine undulation,meanwhile rotation frequency is proportional to laser power.Rotation frequency is measured under the same laser power,the results show the maximum frequency of CaCO3 particles is 1.7 Hz,and the maximum fre-quency of SiO2 particles is 1.5 Hz when laser power is 1 0 mW.The conclusion can be used to the thickness choice of the rotor and the optimization control of rotation frequency in actual application.