基于超短脉冲的癌细胞荧光光谱

研究用于癌症诊断与治疗的光敏剂血卟啉(hematoporphyrin derivative,HPD)的超快光动力学过程。采用超短脉冲激光光谱技术和皮秒时间相关单光子计数系统,测量经血卟啉培养的活体癌细胞与正常细胞的荧光光谱、荧光寿命特性及荧光峰值强度随时间的变化,观测到:癌细胞样品在645nm处具有特征发射光谱峰;癌细胞与正常细胞样品荧光寿命的快成分分别为150,300ps;癌细胞与正常细胞的荧光峰值强度经12h分别衰减10%和55%。对测量所得的荧光光谱曲线及时间分辨荧光衰减曲线分析,计算出:在癌细胞内部血卟啉浓度增大了约2个数量级;癌细胞与正常细胞的荧光寿命分别为824,1798ps;血卟啉在癌细胞与正常细胞样品中滞留时间分别为17,6d。测量结果确认了荧光光谱技术诊断与治疗癌症的可行性,并对发展超短脉冲激光光谱技术早期诊断与治疗癌症具有重要的指导意义和临床应用价值。     

光谱学 光谱分析、光谱测量

O433．4 2006064868基于超短脉冲的癌细胞荧光光谱=Fluorescence spectra study of cancer cells based oll ultrashort pulses laser tech- nique[刊,中]/刘天夫(中国计量学院信息工程系,浙江,杭州(310018)),陈碧芳…//发光学报．—2006．27(1)．—113-117研究用于癌症诊断与治疗的光敏剂血卟啉(HPD))的超快光动力学过程。采用超短脉冲激光光谱技术和皮秒时间相关单光子计数系统,测量了经血卟啉培养的活体癌细胞与正常细胞的荧光光谱、荧光寿命特性及荧光峰值强度随时间的变化。对测量所得的荧光光谱曲线及时间分辨荧光衰减曲线分析,计算出在癌细胞内部血卟啉浓度增大了约2个数量级,结果确认了荧光光谱技术诊断与治疗癌症的可行性。图6表1参4(于晓光)     

皮秒时间相关单光子计数光谱仪的核心技术

研制的皮秒时间相关单光子计数光谱仪利用时间相关单光子计数(TCSPC)技术,采用了具有分光时间弥散动态和静态补偿特性的光栅分光系统,解决了传统分光系统的光信号时间弥散问题;使用多道谱分析仪开设时间窗口,测量荧光衰减曲线和时间分辨光谱;用荧光衰减曲线的多指数拟合方法处理数据。给出了光谱仪的原理和总体方案,介绍了系统的集成和工作流程。通过各种标准样品的试验数据分析和对比,得出系统所测荧光寿命可达到ps量级,而且具有最高的灵敏度——单光子计数,时间分辨率达到8．8ps。     

生命科学中皮秒光脉冲的测量

利用时间相关单光子计数系统测量和比较了正常细胞和癌细胞的荧光光谱和荧光寿命特性，并利用同样的方法测量了单一细胞内不同部位的荧光寿命特性，其结果可作为癌症诊断的重要依据。     

低能量光子激发下纳米ZnO的超快时间分辨光谱特性

室温下获得了均匀沉积法制备的纳米ZnO颗粒在低能量2.33 eV光子(532 mm)的准连续皮秒脉冲激发下的频谱范围从550～1 000 mm的时间分辨光谱和时间积分光谱.随着样品粒径的增加,发光带谱带峰值出现规律性的红移.通过高斯拟合对光谱结构解迭发现,这种规律性的红移是由于低能端区域的高斯组分的相对比例增加所致.时间分辨光谱中超快发射的荧光衰减寿命(皮秒量级)也出现随着样品粒径的增大而相应变长.源于材料尺寸、纳米颗粒大的比表面积所引起的表面能级可以较好的解释此范围的超快发射特性.     

基于电荷转移过程的PAN-C60共聚物薄膜的时间分辨荧光研究

利用吸收光谱和皮秒时间分辨荧光研究PAN－C60星状共聚物的电荷转移过程。PAN－C60共聚物的吸收和荧光光谱结果显示共聚物中存在着电荷转移过程。时间分辨荧光结果表明PAN的荧光衰减遵循双指数衰减规律（一快过程160ps和一慢过程1500ps)，快衰减过程主要来源于聚合物中主链间相互作用产生的空间间接极化子对的影响，慢变过程主要来源于单重态激子的辐射跃迁弛豫。在共聚物中，C60分子的存在除导致PAN激发态寿命缩短外，还影响聚合物链间的相互作用，C60分子对PAN荧光猝 灭作用主要通过慢变过程影响的，而对PAN的空间极化子对的影响主要与其快衰减过程有关。     

皮秒级时间分辨超快高能脉冲激光光谱

介绍了一种利用光电摄谱法和条纹管相结合测量ps级时间分辨超快高能脉冲激光光谱的方法。论述了条纹相机工作原理和平面衍射光栅的分光原理,分析指出利用介绍的装置,可以实现波长300 nm ～1 600 nm、脉宽＞2 ps超快高能脉冲激光的光谱测量。采用1 054 nm超快高能脉冲激光器,实验得到了条纹像,对条纹像进行数据处理后得到测量光谱曲线,通过能量标定后,得到了超快高能脉冲激光器实际光谱曲线,验证了ps级时间分辨超快高能脉冲激光光谱方法。讨论了系统中耦合透镜组对光谱测量和光纤色散角对条纹图像的影响,论述了ps级时间分辨超快高能脉冲激光光谱的作用。随着条纹管制造技术的飞速发展,该方法可用于fs级激光光谱的测量。     

基于猝灭荧光素的一种TCSPC仪器响应函数测量方法

根据荧光物质的动态猝灭作用原理,将碘化钠饱和水溶液与碱性荧光素水溶液按照特定的比例混合,利用时间分辨设备测量猝灭后的荧光素荧光寿命。实验观察到随着碘化钠饱和溶液浓度的增加,测量得到的荧光寿命逐步从4 ns减小至24 ps左右。如将猝灭荧光素作为仪器响应函数的标准样品,与通常作为标准样品的二氧化硅纳米颗粒悬浮液进行对比,实验结果显示两者非常吻合,表明猝灭荧光素可以作为荧光衰减测试中的标准样品,进一步研究发现这种新的标准样品一方面避免了传统测量手段中需要在不同探测波长反复测量仪器时间响应函数的问题,更有效地减小了实验中颜色效应造成的实验误差。有望在时间分辨荧光光谱和荧光寿命成像等研究中得到应用。     

CdS/CdTe多晶薄膜的时间光谱特性

采用超短皮秒脉冲激光激发制备了SnO₂:F 玻璃衬底和石英衬底的CdTe多晶薄膜,在室温下测量其稳态和瞬态荧光光谱。结果表明,随着激发功率的增大,其荧光光谱峰逐渐展宽,并发生蓝移。对于退火处理的样品,其荧光光谱伴随主峰旁出现一个肩峰,是Cl 原子与富Cd区存在的空位形成复合体引起的发射。其瞬态荧光光谱寿命呈双指数衰减,即表面效应所引起的慢过程和带边激子态发射的快过程组成。样品退火处理后荧光寿命变长,有利于电子-空穴对在复合发光前分离,提高电子空穴的迁移率,改善其光伏性能。     

原油样品激光诱导荧光的时间分辨光谱特性研究

为探索激光诱导时间分辨荧光光谱技术应用于海洋悬浮溢油原位探测的可行性,对来自胜利油田六个不同井区不同密度的原油样品的时间分辨荧光光谱进行了探测分析。结果发现,各原油样品荧光发射的持续时间基本相同,从ICCD中数字延时发生器(DDG)的输入延时52 ns开始,到输入延时82 ns左右结束,各原油样品的荧光峰强度随时间变化曲线的半高宽约10 ns;不同原油样品的最强荧光峰位及其衰减寿命不尽相同,并且与样品密度有一定相关性,密度相近的原油具有相近的最强荧光峰位和相似的荧光寿命。对比六种原油样品的时间分辨荧光光谱发现,在荧光增强时,原油荧光光谱峰位不变,当荧光从最大强度开始衰减时,六种原油样品的荧光光谱峰位均出现了不同程度(17~30 nm)的红移现象,这一定程度上反映出原油中各荧光组分的荧光衰减速率存在差异,或者存在荧光组分之间的能量传递。所观测到的原油密度相关的时间分辨光谱信息和荧光峰红移现象可望成为水下悬浮溢油识别的有效特征之一。     

Yb:CaF2–YF3 transparent ceramics ultrafast laser at dual gain lines

Yb³⁺:CaF₂-YF₃ transparent ceramics with excellent optical quality was successfully fabricated by hot-pressed method. Pulsed laser properties of this ceramics were investigated for the first time. Laser diode (LD) was applied as the pump source to generate a dual-wavelength mode-locked (ML) laser. The maximum average output power was 310 mW, which represents the highest output power of ultrafast calcium fluoride ceramic laser. The spectrum separated at 1048.9 nm and 1049.7 nm with a total pulse duration of 8.9 ps. The interval period between the beating signals was about 4.3 ps, corresponding to a 0.23 THz beat pulse repetition rate. These results demonstrate its potential in producing dual-wavelength ultrashort pulses. These Yb³⁺:CaF₂-YF₃ ceramics with low-cost and short-preparation period are ideal candidate materials for ultrafast lasers.     

Picosecond time delay fluorimetry using a jitter-free streak camera

A streak camera driven with picosecond accuracy by a laser-activated cryogenic Si-switch has been used to measure the decay time of malachite green in water by a pulse fluorimetry technique. The single shot timing accuracy of the streak camera (a few ps) corresponds to ～10% of the optical pulsewidth. The overall stability of the system allows the averaging of hundreds of laser shots without image translation improving both the signal to noise ratio and timing accuracy of the measurements.. The subpicosecond timing accuracy afforded by shot averaging has enabled us to measure a 2 ps fluorescence decay time for a low quantum yield sample with a 20 ps excitation pulse.     

人工模拟捕光天线分子中超快能量转移的瞬态荧光测量

利用飞秒时间分辨瞬态荧光光谱仪测量苝四甲酰二亚胺三聚体内的超快荧光淬灭过程. 观察到因能量转移而导致的单体荧光的快速衰减,这一过程的时间常数约为0.82 ps.     

Time-wavelength two-dimensional femtosecond fluorescence imaging

We report a new femtosecond time-resolved fluorescence spectrometer that enables us to observe fluorescence intensity as a time-wavelength two-dimensional image in a single measurement. This method utilizes a time-to-space conversion technique and fluorescence sum-frequency mixing with a femtosecond gate pulse. It provides a fluorescence image covering temporal and spectral spans of approximately 2 ps and approximately 60 nm, respectively. Calibration of the time and intensity axes of the image is made by use of a long-lived dye fluorescence. The two-dimensional fluorescence image of beta-carotene obtained demonstrates the high potential of this method for quantitative studies of ultrafast excited-state dynamics.     

Probing nonequilibrium dynamics with white-light femtosecond pulses

Femtosecond pulsed lasers have become an invaluable tool for examining ultrafast nonequilibrium dynamics. With pulsewidths of a few hundred femtoseconds (fs) to less than 10 fs, these lasers can clearly provide unprecedented temporal resolution. By amplifying ultrashort laser pulses to sufficient levels of energy per pulse, it is possible to exploit the nonlinear optical properties of certain materials to generate extremely broadband pulses. These pulses retain the time structure of the incident pulse, but contain a spectral bandwidth extending from the infrared to as far as the ultraviolet. By generating white-light pulses, it becomes possible to probe ultrafast nonlinear processes over a large range of energies. In this paper, the process of generating white-light ultrashort pulses will be presented, along with a discussion of different probing techniques and procedures necessary for modeling the transient optical data. Finally, results from pump-probe measurements using a white-light probe on indium phosphide (InP) films will be presented as a demonstration of this technique.     

一种用于荧光皮秒时间分辨光谱的测试系统

本文详细描述了一种由氩离子锁模激光器、样品池、分光系统及微微秒条纹相机构成的用于测试低强度荧光微微秒时间分辨光谱的系统。给出了典型样品的测试结果:时间分辨率为10ps,光谱范围为500Å—800Å。最后对测量结果进行了分析讨论。     

Generation and detection of tunable ultrashort infrared and far-infrared radiation pulses of high intensity

We report on generation and detection of intense pulsed radiation with frequency tunability in the infrared and far-infrared spectral regions. Infrared radiation is generated with a transversally electrically excited high pressure CO₂ laser. A laser pulse of a total duration of about 300 ns consisted, due to self mode locking, of a series of single pulses, some with pulse durations of less than 450 ps and peak powers larger than 20 MW. Using these pulses for optical with durations less than 400 ps were obtained. For detection a new ultrafast superconducting detector was used.     

Wide spectral range third-order autocorrelator based on ultrafast nonresonant nonlinear refraction

We demonstrate a simple scheme for a wide spectral range, third-order autocorrelator based on ultrafast nonlinear Kerr-type refraction. The technique was successfully used to characterize high-energy ultrashort pulses at 1550 and 1300 nm, where the pulse's shape and width are two of the most critical parameters. Because of its simplicity, this technique is also a powerful tool for the optimization of high-power chirped-pulse amplified laser systems, in which slight misalignment of the stretcher-compressor gratings can lead to spatiotemporal pulse distortions. In addition, it can be extended to low-power mode-locked oscillators.