全光纤拉曼测温激光雷达分光系统设计

设计了一个532.25nm波长的转动拉曼激光雷达用新型全光纤分光系统,对强背景噪音下微弱的转动拉曼信号进行高精度提取,以用于探测大气温度。该新型全光纤分光系统由3个光纤布拉格光栅(FBG)及光纤环行器构成,利用FBG的波长选择特性,可高精度剔除大气回波信号中的米氏散射、瑞利散射信号成份,分离出中心波长分别为530.6nm和528.8nm的转动拉曼散射信号,用于反演大气温度。通过对分光系统进行参数优化设计和数值计算,表明基于FBG的分光系统可以对回波信号中的米氏散射、瑞利散射信号进行高达7个数量级以上的抑制,满足转动拉曼测温激光雷达对米氏散射、瑞利散射信号的高精度剔除。     

基于气溶胶光学参数的拉曼激光雷达重叠因子校正方法

提出了一种稳定的拉曼激光雷达重叠因子计算和校正算法,适用于含有拉曼散射通道的激光雷达系统的重叠因子校正。此算法基于大气气溶胶光学参数的拉曼反演算法,通过分析消光系数和后向散射系数的反演特点,发现后向散射系数在过渡区中不受重叠因子的影响。用后向散射系数和激光雷达比的乘积对消光系数缺失信号进行初步校正,进而正演出初步校正后的拉曼散射回波信号,将实际拉曼散射回波信号与正演的拉曼散射回波信号相除即可得到重叠因子廓线。对回波信号和气溶胶光学参数进行了过渡区信号校正和盲区信号补充。分别用单组和连续的激光雷达实验观测数据进行了重叠因子的计算和校正,并与能见度仪观测的近地面数据进行了对比,呈现良好的一致性。结果表明,此算法对重叠因子计算较为稳定。     

水汽探测拉曼激光雷达的新型光谱分光系统设计与分析

提出并设计了一套新型的大气水汽和气溶胶探测用紫外域拉曼激光雷达系统, 以二向色镜和超窄带滤光片构成高效率拉曼光谱分光系统, 实现激光雷达大气回波信号中米-瑞利散射信号、 氮气和水汽的振动拉曼散射信号的精细分离和高效率提取. 利用美国标准大气的分子散射模型和实测的大气米散射信号模型, 对分光系统的米-瑞利散射信号的抑制率、大气水汽测量的信噪比和误差进行数值仿真设计. 搭建实验系统对西安地区夜间的大气水汽进行实验观测, 并利用有云天气下实测的激光雷达回波信号, 反演获得大气后向散射比和水汽混合比的相关特性, 验证了该拉曼光谱分光系统对米-瑞利信号的抑制率达到10^-7以上量级. 理论和实验结果表明, 设计的新型拉曼光谱分光系统可以在大气后向散射比为17时, 实现水汽探测误差小于15%, 满足拉曼激光雷达系统对大气水汽的高效率探测. 关键词： 拉曼激光雷达 水汽混合比 大气后向散射比     

纯转动拉曼激光雷达中阶梯光栅单色仪设计

纯转动拉曼激光雷达测温系统通常根据大气中N₂分子高低阶量子数的转动拉曼散射回波信号来反演大气温度,而探测转动拉曼谱的一种有效方法就是采用单色仪。文章阐述了中阶梯光栅单色仪的探测原理和结构,分析了探测谱线的高阶和低阶量子数及对应的拉曼散射波长。通过对中阶梯光栅的分光原理及色散能力分析计算了准直-聚焦系统的焦距,给出了光学系统的设计参数。利用Zemax软件对光路进行了模拟仿真,仿真结果表明：在探测激光波长为532 nm的条件下,采用两块中阶梯光栅设计的单色仪,能够将529.05, 530.40, 533.77和535.13 nm的拉曼谱线很好的分开,同时对对称量子数的谱线信号进行求和,增强系统的信噪比。中阶梯光栅单色仪体积较小,利于测温雷达系统的小型化。     

绝对探测大气温度的纯转动拉曼激光雷达系统

纯转动拉曼激光雷达是探测大气温度廓线的重要手段之一,其正常工作需要配置其他并行校正设备,制约其在气象及环境监测领域中的实用化进程.基于大气氮气分子的纯转动拉曼谱型对温度的依赖性,提出并设计了绝对探测大气温度廓线的纯转动拉曼激光雷达系统.系统采用波长532 nm且脉冲能量300 m J的激光激励源和口径250 mm卡塞格林望远镜的接收器,设计了衍射光栅和光纤Bragg光栅结合的多通道并行纯转动拉曼光谱分光系统;仿真分析氮气和氧气分子的纯转动拉曼散射谱线间关系,优化选择了6条氮气分子的纯转动拉曼谱线以直接反演大气温度,设计了两级滤光器间转接光纤阵列的结构;基于最小二乘原理推导了绝对探测大气温度的反演算法,并结合标准大气模型,分析了纯转动拉曼激光雷达绝对探测大气温度的探测性能.结果表明,所设计纯转动拉曼激光雷达系统可直接反演大气温度廓线,在测量时间17 min内,温度偏差小于0.5 K的探测高度达2.0 km.     

基于三级Fabry-Perot标准具的纯转动拉曼测温激光雷达

提出了新的纯转动拉曼测温雷达系统,即以种子激光注入锁定的Nd:YAG激光器为激发光源,采用基于三级Fabry-Perot(F-P)标准具的双通道分光结构代替双光栅单色仪结构.通过通道中宽带滤光片(带宽为7nm)及F-P标准具的组合使用,对532nm激发光的大气Mie-Rayleigh弹性回波散射抑制比可达10^-10,对量子数J=±6,J=±12的N₂纯转动拉曼散射光谱线接收带宽均小于10pm,因此能充分抑制大气背景辐射噪声及O₂纯转动拉曼谱线的干扰,从而实现了单谱线比反演温度,提高了探测精度,且可在白昼探测大气对流层温度.最后通过探空气球测得的对流层温度垂直分布逆向模拟了该系统双通道的Raman信号曲线,证实了该系统的可行性. 关键词： 拉曼激光雷达 纯转动拉曼散射 三级Fabry-Perot标准具 对流层     

基于火星巡视器车载激光诱导击穿光谱仪系统设计米散射激光雷达可行性研究

火星大气气溶胶的地基探测对研究火星大气环境具有重要意义,为了能够在节约火星巡视器/着陆器体积、重量的条件下进行气溶胶探测,论证了基于巡视器车载激光诱导击穿光谱仪系统设计米散射激光雷达方案的可行性。所设计的米散射激光雷达系统使用巡视器车载激光诱导击穿光谱仪的既有硬件资源,加入分光元件和探测器模块,构成与激光诱导击穿光谱仪系统集成的米散射激光雷达,米散射激光雷达与激光诱导击穿光谱仪在火星地表分时工作,互不影响。为了论证所设计的米散射激光雷达的探测性能,对Phoenix火星探测任务中独立的米散射激光雷达得到的一组原始回波信号数据进行了处理,反演得到一组典型火星大气消光系数廓线,结合消光系数廓线与系统硬件参数计算了所设计的米散射激光雷达的回波信噪比,结果表明该系统在所用原始数据被记录的当日在火星大气边界层顶4 km高度处信噪比达到26 dB,在10 km高度附近下降到0 dB,说明基于火星巡视器车载激光诱导击穿光谱仪系统设计米散射激光雷达进行气溶胶探测具有现实可行性。对比Phoenix的独立米散射激光雷达设计方案,基于激光诱导击穿光谱仪的米散射激光雷达不但能够节省巡视器体积、重量,而且发射能量更高,回波接收方案更为简单,数据反演步骤更为简洁。     

振动拉曼散射信号反演激光雷达几何因子分析

利用研制的探测大气二氧化碳廓线的振动拉曼激光雷达系统采集的氮气分子振动拉曼散射信号,结合激光雷达探测时的大气消光数据,反演求出激光雷达的几何因子曲线。并对气溶胶波长指数变化对振动拉曼信号反演几何因子造成的影响进行分析与估算。气溶胶消光波长指数变化对振动拉曼散射信号反演几何因子会带来较大的误差影响。当气溶胶消光波长指数或其谱分布确定时,振动拉曼散射信号反演几何因子具有简便、可靠等优点,在振动拉曼激光雷达系统几何因子确定中可以充分应用此方法。     

日盲紫外域拉曼激光雷达探测大气水汽技术研究

拉曼激光雷达通过探测与水汽浓度相关的大气水汽振动拉曼散射回波信号,可实现大气水汽混合比廓线的探测。然而由于振动拉曼信号非常微弱,在白天测量时振动拉曼散射光谱会淹没在太阳背景光中,多在夜间测量。为实现大气水汽的全天时测量,设计开发一套日盲紫外波段拉曼激光雷达系统。该系统选择Nd∶YAG脉冲激光器的四倍频输出-266.0 nm日盲紫外波段作为拉曼激光雷达系统的激励波长,采用镀高增益介质膜的牛顿式望远镜作为接收器,同时利用二向色镜和超窄带干涉滤光片设计高效率的高光谱分光系统,实现了大气氧气、氮气和水汽振动拉曼散射回波信号277.5,283.6和294.6 nm的精细提取。计算仿真结果表明,臭氧吸收对日盲紫外域拉曼激光雷达探测存在一定的影响,主要是探测距离的影响;氮气通道不受白天太阳背景光噪声的影响;水汽通道存在少量太阳背景光噪声,对系统探测距离略有影响。而系统信噪比计算结果表明,设计的日盲紫外域拉曼激光雷达系统可实现白天3.5 km大气水汽的探测。实际进行水汽探测时,可利用氮气和氧气通道反演出臭氧浓度廓线,修正臭氧对发射波长、各通道拉曼散射波长的吸收,进一步提升系统的探测能力和探测精度。     

Raman-Mie方法反演气溶胶后向散射系数

传统的Klett和Fernald反演气溶胶法依赖于消光系数和后向散射系数的假设关系,给反演结果带来误差。根据纯转动拉曼后向散射系数仅是大气温度和压强的函数,设计的Raman-Mie方法用米散射和纯转动拉曼回波信号结合探空温度和大气压强共同反演气溶胶后向散射系数。不仅消除了Klett和Fernald方法引入假设带来的误差,还可避免因几何因子修正带来的影响。最后将该方法用于实验室自行研制的拉曼-米散射激光雷达,反演出了大气气溶胶后向散射系数廓线,实验结果与Klett(Fernald)方法分别进行了比较。     

The decay kinetics of radical-recombination luminescence in crystal phosphors

The features of the decay kinetics of radical-recombination luminescence (RRL) in crystal phosphors excited by atomic hydrogen have been studied. It is shown that the kinetics of the RRL decay can be determined both by the processes in the gas phase (decrease in the hydrogen-atom concentration as a result of their recombination at the walls of the reaction vessel after the atom-generation source has been switched off) and by the processes in the solid itself. Some conclusions are drawn concerning the mechanism of recombination for the RRL of the experimental phosphors.Translated from Izvestiya VUZ. Fizika, No. 12, pp. 16–19, December, 1973.     

The mechanism of radical-recombination luminescence in zinc oxide

The temperature-time relationships of the intensity of radical-recombination luminescence (RRL) and the surface electroconductivity of zinc oxide with excitation by atomic hydrogen have been studied. The results are analyzed on the basis of the electron theory of chemisorption and catalysis and the band theory of crystal-phosphor luminescence. The effect of the state of the gas phase and the deep trapping level on the intensity of the RRL is elucidated. A mechanism is proposed for the RRL excitation of this phosphor.Translated from Izvestiya VUZ. Fizika, No. 12, pp. 19–24, December, 1973.     

一种基于自相关的激光脉冲编码信号解码方法

激光脉冲编码是半主动激光制导武器采用的一种抗干扰措施,为满足半主动激光制导武器光电对抗的需要,以激光信号的脉冲到达时间(TOA)为参数,依据激光脉冲编码信号的时间相关性,提出了一种通过首先对由脉冲到达时间组成的脉冲到达时间序列作自相关处理,计算出信号的重复周期,然后再在一个信号周期内,通过确定脉冲重复间隔的时间值、个数和位序来鉴别信号码型,从而实现信号解码的方法。阐述了该解码方法的原理及实现。原理实验和数字仿真实验证明,对于当前半主动激光制导武器采用的大多数激光脉冲编码信号,采用该解码方法,一般在4个信号周期时间内就能实现解码。     

A novel spectroscopic filter used in rotational Raman lidar for the temperature profiling

We perform the rotational Raman temperature measurements in the troposphere and lower stratosphere with high performance. Depending on the aerosol content and presence of clouds in the lower troposphere, the rotational Raman lidar (RRL) is the lidar technique of choice for temperature measurements. However, the Raman filter design is a technical difficulty in RRL systems. Considering the higher spectral resolution and compactness, we select several photonic crystals to construct a novel spectroscopic filter for extracting the required rotational Raman spectrum (RRS) signals of atmospheric molecules. We describe in detail the principle to design the photonic-crystal filter. To verify the feasibility of the novel spectroscopic filter, we carry out some numerical calculations, and our results show that the novel spectroscopic filter has the capability to fine draw the required RRS signal and suppress sufficiently elastic signals. For the RRL system which uses the novel spectroscopic filter, we obtain that a statistical temperature error is less than 1 K up to a height of 3.2 and 5.6 km for daytime and nighttime measurements, respectively. Our simulation conditions are as follows: 532 nm laser with 500 mJ energy, and 10 Hz pulse repeating rate, a 300 mm diameter Cassegrain reflecting telescope with 1000 mm focus length, 0.2 mm diameter multimode optical fiber which sets the field of view (FOV) of receiving system to 0.2 mrad, 45 m range resolution, 9 min observation time, overall optical-system efficiency of 0.6, and a special atmospheric model which integrates the US standard model of 1976 with an actual Mie scattering profile obtained from practical observations.     

Single Pulse-Laser Induced Breakdown Spectroscopy in aqueous solution

In this paper the flexibility of Laser Induced Breakdown Spectroscopy (LIBS) has been proved for the analysis of water solutions. The plasma is generated directly in the bulk of a water solution by a Q-switched Nd:YAG laser (1064). The emission signal of four different solutions has been studied: AlCl₃, NaCl, CaCO₃ and LiF. The basic mechanisms influencing the emission signal and the experimental tricks for the optimization of the detection mode have been pointed out. PACS 52.70.Kz; 52.80.Wq; 39.30.+p     

Numerical ray-tracing approach with laser intensity distribution for LIDAR signal power function computation

We have developed a new numerical ray-tracing approach for LIDAR signal power function computation, in which the light round-trip propagation is analyzed by geometrical optics and a simple experiment is employed to acquire the laser intensity distribution. It is relatively more accurate and flexible than previous methods. We emphatically discuss the relationship between the inclined angle and the dynamic range of detector output signal in biaxial LIDAR system. Results indicate that an appropriate negative angle can compress the signal dynamic range. This technique has been successfully proved by comparison with real measurements.     

Radical-Recombination Luminescence of the Uranyl Nitrate Complex in the Adsorbed State

We have investigated the luminescence of uranyl nitrate molecules on the surface of powdery SiO₂ upon excitation by UV light (PhL) and hydrogen atoms (radical-recombination luminescence (RRL)). It has been found that the PhL and RRL spectra have a clearly defined vibrational structure. The luminescence peaks of the adsorbed UO₂ ^2– ion are characterized by a systematic longwave shift from the same peaks of crystalline uranyl nitrate (by 230–430 cm^–1 at 130 K). Moreover, in the adsorption centers the vibration frequencies of UO₂ ^2– are 20–80 cm smaller than in crystalline salt and the RRL bands are 150–350 cm^–1 (130 K) wider than the corresponding PhL bands.     

The temperature characteristics of radical-recombination luminescence

The radical-recombination luminescence (RRL) of solids which arises as a result of the recombination at the surface of the body of free radicals or atoms from the gaseous phase, is a relatively little known form of nonequilibrium radiation. Valuable information concerning the mechanism involved can be obtained by studying the temperature characteristics of the luminescence and by comparing them with those of photoluminescence, since these have been extensively studied. Hanle and Niermann [1] carried out measurements of this kind on certain sulphide phosphors excited by atomic nitrogen. Sancier and others [2] did similar work on CaO. V. G. Kornich and A. N. Gorban [3] studied the luminescence of ZnO under the effect of radicals obtained by a discharge in water vapor.In this paper we consider the temperature dependence of the RRL of phosphors based on ZnS and ZnO when excited by atomic hydrogen.The authors thank Prof. V. A. Sokolov for discussing the results.     

水溶液中金属元素的激光诱导击穿光谱的检测分析

文章对竖直流动的CuSO₄和Pb(NO₃)₂水溶液样品表面的激光诱导击穿光谱的（简称LIBS）特性进行了观测分析。实验中采用的烧蚀激光波长为532 nm,脉冲宽度为10 ns,重复频率为10 Hz;LIBS信号的探测通过一色散相加型双光栅单色仪、Boxcar和PMT的组合来完成。通过对水溶液中金属元素的LIBS信号随时间和能量演化规律的分析,初步确定了系统 的最佳烧蚀能量和最佳探测延时。受样品表面附近空气击穿时氧元素信号的影响,实验对Cu和Pb各自的击穿位置进行了优化。在分析影响LIBS光谱探测因素的基础上,进一步优化了系统的工作条件和探测 参数。通过对不同浓度下LIBS信号的探测分析,初步确定了系统对Cu与Pb的最低检测浓度,分别约为31,50 ppm(μg·mL-1)。文章还对将LIBS技术运用到海水中重金属的实时在线检测的可 行性进行了讨论。     

Sputtering of zinc sulfide phosphors in excitation of radical-recombination luminescence by atomic hydrogen

Treatment of zinc sulfide phosphors in atomic hydrogen not only produces radical-recombination luminescence (RRL) but also sputtering of the phosphor. The sputtering rate has been estimated for FKP-03k powder phosphor at various temperatures. The atomic hydrogen produces defects of etch-pit type on the surface of a single crystal. The long-term response of the RRL has been recorded for the FKP-03k phosphor and it is ascribed to the sputtering.Translated from Izvestiya Vysshikh Uchebnykh Zavedenii, Fizika, No. 3, pp. 107–110, March, 1975.