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有效线吸收系数能谱效应综合法研究 总被引:3,自引:1,他引:2
利用综合法(照射量传递函数法、剥层法和MC数值模拟法)研究了闪光照相中法国实验客体FTO(French Test Object)中各种材料的有效线吸收系数.结果表明:在照相过程中,随着X光穿透的加深,其能谱不断地向材料最小质量吸收系数对应的能量值演变并窄化.在这样的能谱效应下,有效线吸收系数随着穿透材料厚度的加深而减小.铜的平均有效线吸收系数为0.299(1±3.0%)cm-1,钨的平均有效线吸收系数为0.829(1±2.7%)cm-1.在图像重建中,利用上述的有效线吸收系数能够得到高精度的材料密度分布. 相似文献
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研究闪光照相中影响材料有效吸收系数的两个主要因素,即X光的能谱效应和散射影响。用Monte-Carlo方法对闪光照相系统的客体各种组成材料的有效吸收系数进行数值模拟;求出不考虑散射而仅受能谱影响的有效吸收系数及其空间分布,发现该分布类似于医学CT数的分布规律,在高光程数对应的位置上该吸收系数较低;也得到了在20MeV闪光机情况下,客体各种组成材料的单个平均吸收系数。结果表明:钨、铝和铁的平均等效吸收系数分别近似为0.830,0.080和0.265cm
-1。 相似文献
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用窄线宽、脉冲可调谐光参量振荡器(OPO)作光源,使用光程长达1 097m的怀特池,采用单探测器分时复用的探测方法,首次在吸收池中精确测量了实际大气中1.315 μm波长附近高分辨率吸收光谱,实验验证了实际大气中水汽是该波段的主要吸收气体;得到了实际大气中吸收分子在氧碘激光波长(7 603.14cm-11)处的吸收截面为 (1.05±0.09)×10-24 cm2(标准大气条件下)以及在该波段主要吸收谱线的参数,包括吸收线的位置、线强度、压力加宽半宽度等。利用实测的线参数计算了在氧碘激光波长附近大气分子的吸收截面,发现吸收最小的波长分别位于7 603.31和7 603.93cm-1,其值约为(8.9±0.8)×10-25 cm2,比氧碘激光波长处的吸收截面约小15%。 相似文献
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大气中的水汽对DF激光主要强线的吸收相对较小,而HF激光的大多数谱线受水汽和CO2分子等的吸收较大。利用较新的HITRAN96数据库和我国不同地区的气象资料,采用逐线积分法计算了HF/DF 激光的大气衰减情况。所选的谱线中,在合肥地区(年平均), HF的水汽吸收系数最大值可达到10km-1的数量级,二氧化碳吸收系数最大可达10-4~10-3km-1量级,P2(8)线吸收最弱;DF激光水汽吸收系数最大值可达到10-1km-1,比HF低2个量级,且随高度衰减很快,10km处就到10-5~10-4km-1量级,P2(8)线吸收最弱。在我国,由南向北,由夏季到冬季,水汽浓度减少,大气对HF/DF激光的吸收率也相应地递减。 相似文献
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利用可调谐激光长程吸收光谱测量系统,记录到1.315μm附近高气压(80kPa和40kPa)CO2的高分辨率吸收光谱,拟合分析获得谱线参数,结果与HITRAN 2k的数据基本一致。用程差法测量了绝对吸收,氧碘激光频率(7 603.138 5cm-1)的总吸收截面为(0.23~0.29)×-24cm2。仅计算谱线吸收的吸收截面为0.18×10-24cm2。在1.315μm波段COCO2存在连续吸收,吸收截面为(0.05~0.11)×10-24cm2。还讨论了测量误差问题。 相似文献
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在激光能量130 mJ(靶面),脉宽60 fs,波长800 nm,对比度1∶10-6,激光与靶法线成45°夹角,P偏振,靶面激光峰值功率密度约为7.0×1017 W·cm-2,无预脉冲的条件下,采用电子谱仪与经γ标准源标定的LiF热释光探测器(TLD)相配合,测量了飞秒激光-薄膜靶相互作用中产生的超热电子能谱。根据所测的能谱,推算出超热电子的产额和激光能量转化为超热电子能量的效率,在靶法线方向分别为1.19×1010/sr和4.55%/sr,在激光反射方向分别为1.83×109/sr和0.76%/sr。结果显示,不同方向的超热电子产额和激光转化效率有所不同,原因在于激光-等离子体相互作用产生的超热电子构成各向异性的分布。 相似文献
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研究了电子通量对ZnO/K2SiO3热控涂层光学性能的影响。分别采用通量为5×1011/cm2·s,8×1011/cm2·s,1×1012/cm2·s 和5×1012/cm2·s的电子对试样进行辐照。电子辐照下涂层的光学性能发生了退化,并且发现了退化涂层在空气中的“漂白”现象。分析了ZnO/K2SiO3热控涂层光学性能的退化机制,同时讨论了电子通量对太阳光谱吸收系数的影响。实验结果发现,在5×1011~1×1012/cm2·s的电子通量范围内,电子通量对ZnO/K2SiO3热控涂层光学性能的影响相同。因此在这个电子通量范围内,采用加速地面试验来模拟空间的电子辐照效应是有效的。 相似文献
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The goal of this study is to propose a model for the ultrasonic frequency-dependent backscatter coefficient in femoral cancellous bone. This model has been developed with success to predict backscatter in human calcaneal bone [Jenson, Ultr. Med. Biol. 2003]. A weak scattering model is used and the backscatter coefficient is expressed in terms of a Gaussian autocorrelation function of the medium. The backscatter coefficient is computed and comparison is made with experimental data for 37 specimens and for frequency ranging from 0.4 to 1.2 MHz. An excellent agreement between experimental data and predictions is found for both the magnitude and the frequency-dependence of the backscatter coefficient. Then, a nonlinear regression is performed for each specimen, and the mean trabecular thickness is estimated. Experimental data and theoretical predictions are averaged over the 37 specimens. We also find a close agreement between theoretical predictions obtained using the Gaussian autocorrelation function (scatterer size=134+/-15 microm) and the mean trabecular thickness (Tb.Th=132+/-12 microm) derived from the analysis of bone 3-D micro-architecture using high-resolution micro-tomography. However, the correlation between individual experimental and estimated Tb.Th values is moderate (R(2)=0.44). The performance of the estimator are limited mainly by two factors: interference noise due to random positioning of the scatterers and attenuation. We show that the fundamental limitation of our estimator due to the speckle noise is around 5 microm for trabecular thickness estimation. This limitation is lower than the observed biological variability which is around 30 microm and should not be a limiting factor for individual prediction. A second limitation is the tremendous attenuation encountered in highly scattering media such as cancellous bone, which results in highly damped backscatter signals. The compensation for attenuation is difficult to perform, and it may be a critical point that limits the precision of the estimator. 相似文献
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对Cl/HN3/I2产生NCl(a)/I激光的过程进行了化学动力学计算,主要考察了Cl,HN3和I2的初始粒子数密度及其配比对小信号增益系数的影响。结果发现,当温度为400K, 初始Cl粒子数密度为1×1015,1×1016和1×1017cm-3时,小信号增益系数分别达到1.6×10-4,1.1×10-3和1.1×10-2cm-1,获得最佳小信号增益系数的HN3和I2的初始粒子数密度分别为初始Cl粒子数密度的1~2倍和2%~4%。同时,对Cl,HN3和I2配比对小信号增益系数和增益持续时间的影响进行了讨论。 相似文献
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介绍了硅基片上具有微米厚度的SiO2膜在斜入射情况下的红外反射透过谱测量结果,发现在900~1250cm-1波段内的结果有别于一般的透射谱,出现了峰位基本不变的1100cm-1反射峰。随厚度增大,1100cm-1峰和1200cm-1凹谷的降低逐渐变为迟缓。当厚度达到2μm以上后,1075~1250cm-1谱线的变化已不再明显。通过分析表明,结果中包含了SiO2膜的表面反射谱和SiO2膜层的吸收谱。当膜厚达到微米量级而引起较大吸收时,表面反射谱的贡献相当明显。此时,对该段谱线的分析不能仅考虑膜层的吸收。 相似文献
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采用微波等离子体化学气相沉积(MW-PCVD)和直流热阴极辉光放电等离子体化学气相沉积(DC-PCVD)两种方法相结合,制备出一种吸收辐射的复合金刚石膜,它对宽光谱范围的光辐射具有99%—99.2%的吸收率,同时具有较低的反射率和透过率.随着黑色吸收辐射金刚石层厚度的增加,复合金刚石膜的热导率将小幅度降低,但黑色金刚石膜层厚度小于15 μm时,复合金刚石膜的热导率都在16 W·cm-1·K-1以上,这满足吸收辐射复合金刚石膜的高导热需求.用热阴极DC-PCVD方
关键词:
吸收辐射
光学材料
金刚石
热导率 相似文献
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The effective ultrasonic energy radiation into the air of piezoelectric transducers requires using multilayer matching systems with accurately selected acoustic impedances and the thickness of particular layers. One major problem of ultrasonic transducers, radiating acoustic energy into air, is to find the proper acoustic impedances of one or more matching layers. This work aims at developing an original solution to the acoustic impedance mismatch between transducer and air. If the acoustic impedance defences between transducer and air be more, then finding best matching layer(s) is harder. Therefore we consider PZT (lead zirconate titanate piezo electric) transducer and air that has huge acoustic impedance deference. The vibration source energy (PZT), which is used to generate the incident wave, consumes a part of the mechanical energy and converts it to an electrical one in theoretical calculation. After calculating matching layers, we consider the energy source as layer to design a transducer. However, this part of the mechanical energy will be neglected during the mathematical work. This approximation is correct only if the transducer is open-circuit. Since the possibilities of choosing material with required acoustic impedance are limited (the counted values cannot always be realized and applied in practice) it is necessary to correct the differences between theoretical values and the possibilities of practical application of given acoustic impedances. Such a correction can be done by manipulating other parameters of matching layers (e.g. by changing their thickness). The efficiency of the energy transmission from the piezoceramic transducer through different layers with different thickness and different attenuation enabling a compensation of non-ideal real values by changing their thickness was computer analyzed (base on genetic algorithm). Firstly, three theoretical solutions were investigated. Namely, Chebyshev, Desilets and Souquet theories. However, the obtained acoustic impedances do not necessarily correspond to a nowadays available material. Consequently, the values of the acoustic impedances are switched to the nearest values in a large material database. The switched values of the acoustic impedances do not generally give efficient transmission coefficients. Therefore, we proposed, in a second step, the use of a genetic algorithm (GA) to select the best acoustic impedances for matching layers from the material database for a narrow band ultrasonic transducer that work at frequency below the 2.5 MHz by considering attenuation. However this bank is rich, the results get better. So the accuracy of the propose method increase by using a lot of materials with exact data for acoustic impedance and their attenuation, especially in high frequency. This yields highly more efficient transmission coefficient. In fact by using increasing number of layer we can increase our chance to find the best sets of materials with valuable both in acoustic impedance and low attenuation. Precisely, the transmission coefficient is almost equal to unity for the all studied cases. Finally the effect of thickness on transmission coefficient is investigated for different layers. The results showed that the transmission coefficient for air media is a function of thickness and sensitive to it even for small variation in thickness. In fact, the sensitivity increases when the differences of acoustic impedances to be high (difference between PZT and air). 相似文献
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重点研究碳纳米管的紫外-可见-红外多光谱兼容衰减特性。在傅里叶变换红外光谱、紫外-可见光谱分析、激光散射、电子显微镜(SEM)等现代分析技术的基础上阐述了碳纳米管的添加剂、质量浓度、结构与多光谱兼容衰减特性的密切联系,并探讨了调控多光谱衰减的新原理和新技术。结果表明,不同结构和浓度的碳纳米管流体的紫外-可见光谱差别很大。质量浓度为0.04 g.L-1时,粒径为30~50 nm的碳纳米管样品在265 nm紫外衰减的消光系数为7.825 m2.g-1,透光度为4.4%,紫外吸收光谱衰减为90%以上。验证了样品吸光度和碳纳米管的质量浓度是线性相关的。该碳纳米管在红外光谱范围的兼容衰减特性良好,碳纳米管薄膜厚度为0.1 mm时,测量光路中碳纳米管的质量为0.349 mg,粒径为30~50 nm碳纳米管与液体石蜡复合样品在4.0~6.25μm和7.0~16.7μm红外吸收光谱衰减在90%以上。 相似文献
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