在单模光纤中放大的反斯托克斯拉曼背向自发散射的温度效应

在单模光纤中,输入的激光功率大于阈值时．出现放大的反斯托克斯拉曼背向自发散射现象。实验发现：放大的反斯托克斯拉曼背向自发散射具有温度效应．与反斯托克斯拉曼背向自发散射一样,放大的拉曼散射光的光子通量受到光纤温度的调制。反斯托克斯拉曼背向白发散射的放大效应抑制了单模光纤中的相干噪声,改善了系统的信噪比。实验还发现．放大的反斯托克斯扎曼背向自发散射空域曲线上放大的端点位置随激发功率的增高前移并具有一定的规律性。放大的反斯托克斯拉曼背向自发散射的温度效应作为一种新的测温原理,已应用于远程30km分布光纤温度传感器系统。     

硅桥红外辐射单元温度的显微拉曼测定

本文采用显微拉曼光谱实验的方法对红外目标模拟器中的重掺杂Si电阻微桥单元进行了绝对温度的测量 ,并根据斯托克斯与反斯托克斯强度与温度关系以及Raman峰位移动与温度依赖关系两种方法确定温度 ,保证了所测温度的可靠性。针对Si桥建立相应的Raman模型 ,选择合适的物理参数 ,最终得到了反映Si桥工作特性的电流 -温度关系。此外 ,通过对Si桥的空间分辨的测量实验 ,得到了Si桥上的温度分布状况 ,对了解其电阻、热导及氧化等特性十分有用。所有结果表明该方法是器件优化的有效途径。     

光纤背向激光自发喇曼散射的温度效应研究

从理论和实验上研究了光纤背向激光自发喇曼散射的温度效应.光纤背向激光自发反斯托克斯喇曼散射、斯托克斯喇曼散射光的相对强度正比于光纤分子上、下能级粒子数的布居,依赖于温度.由于实际系统中,作为分光用的干涉滤光片不可能完全隔离背向瑞利散射光,因此,实际系统温度曲线比理论曲线低,本文给出了理论修正公式,提出了附加修正项,它与隔离度和波长有关.     

基于新型超低频拉曼光谱的液态水分子高温研究

液态水是地球上大多数生化过程的化学支柱,对生物的新陈代谢是必不可少的。因此,它是一个跨科学领域的关键课题。水的理化特性被认为是氢键衍生结构的结果。然而,目前还很难在实验上定量地将水分子的理化特性与氢键结构联系起来形成完整的液态水分子结构理论。拉曼光谱因其快速、无损等优点成为表征液态水分子结构及其变化规律的主要手段。目前,水分子的拉曼光谱主要研究的是其高频振动模。然而,液态水较宽的低频拉曼模是氢键及其局部结构效应的结果,包含高频峰无法表征的特征信息,而超低频拉曼特征峰仍能在高温下揭示水分子（超）结构的许多关键细节。因此,在实验上实现对水分子的新型高温超低频拉曼光谱（5～200 cm-1频率区域）,探测得到理论预测的全部四种平动特征模,包括弯曲模（51.7 cm-1）、扭转模（81.4 cm-1）、对称（154.0 cm-1）和不对称拉伸模（188.6 cm-1）,并在225.2 cm-1处额外发现了平动-旋转耦合特征模。所有特征模都被精确指认。高温超低频拉曼光谱实验发现,首先在特征峰频率上,由于高温下氢键断裂导致水分子间的平均结构关联长度（SLG）迅速缩短,当温度从0 ℃升高到400 ℃,所有四种超低频特征模的频率都随温度升高而大幅蓝移。其次在特征峰强度上,拉伸模的强度在100和200 ℃间出现明显降低。而弯曲模的强度随着拉伸模频率从高频率到低频率依次升高,这是理论研究从未涉及的。最后在斯托克斯/反斯托克斯比值（R_S/AS）上,温度在150～170 ℃时（压强约为2 kbar）,R_S/AS迅速从1.1增加到1.3;当温度高于170 ℃时,R_S/AS随温度线性变化。综上所述,通过对水分子各共振模的频率蓝移、强度变化,以及斯托克斯/反斯托克斯比值等特征进行细致研究,得到温度对水分子结构,尤其是氢键衍生特性的影响。该新型高温超低频拉曼光谱方法,填补了部分理论空白,为深入全面地理解水分子结构提供了重要的实验依据。     

纳米晶Y_2O_3:Eu~(3+)的反常拉曼散射(英文)

作者用燃烧法制备了8nm-50nm的系列纳米晶Y2O3:Eu3+,利用XRD谱确定了纳米晶的晶体结构及晶粒大小。利用两套由不同波长的激光所激发的拉曼光谱,指认了纳米晶Y2O3:Eu3+的拉曼振动模,研究其拉曼光谱。与传统的拉曼光谱学相比较,光谱呈现出明显的反常,其一,是斯托克斯与相对应的反斯托克斯谱峰波数不相等;其二,随晶粒的减小,拉曼谱有明显的变化,包括谱峰的微移、半高宽的增加,以及谱峰强度比的强烈变化;其三,随着激发波长的变化,光谱也呈现出峰位移动的明显变化。这些反常的散射光谱的变化源于纳米结构的本征缺陷。     

Compensation for temperature dependence of Stokes signal and dynamic self-calibration of a Raman distributed temperature sensor

This article discusses a powerful calibration technique that compensates for the temperature dependence of the Stokes signal in a Raman distributed temperature sensor. The Stokes signal is conventionally used for normalization since its scattering cross-section is a weaker function of temperature than that of the anti-Stokes signal. The potential of this temperature dependence of the Stokes signal to introduce errors in measurements has received only cursory mention in the literature. We show that this effect degrades the temperature accuracy by as much as 90%. Additionally the heavy fiber attenuation at the operating wavelength also makes calibration non-trivial. The technique described implements a corrective mechanism for this temperature dependence, offers the additional benefit of self-referencing of a heated curve rather than referencing to the fiber at room temperature, and demonstrates the viability of such a system despite the heavy fiber attenuation at the operating wavelength. This obviates the impractical and erroneous approach of storing an initial room temperature profile for subsequent temperature calculation. This dynamic self-referencing adds substantial immunity to the tolerances in the actual numerical values of the Raman wavelengths thereby making the system robust.     

混合溶液中CARS过程的非共振信号实验研究

相干反斯托克斯拉曼散射是一种非线性四波混频效应,但是通过探测共振信号不易进行物质成分的定量光谱分析。本文利用单频相干反斯托克斯拉曼散射光谱分析法,对不同体积比混合的乙醇溶液在远离双光子共振跃迁及其远离溶质与溶剂的特征拉曼共振态位置进行了光谱探测。通过对实验结果进行分析发现,在共振位置2 876 cm-1的信号强度随混合溶液中的乙醇的体积比增加而增加,呈二次方关系。而在远离共振态位置的非共振信号强度随混合溶液中乙醇的体积比增加而增加,且呈线性关系,进而说明了非共振信号强度随着分子数浓度N呈线性变化关系。因此,通过探测非共振信号强度与分子数浓度关系可以为混合物中特定成分的定量光谱分析提供一种研究途径。     

Accurate intensity calibration for low wavenumber (−150 to 150 cm−1) Raman spectroscopy using the pure rotational spectrum of N2

We report on an accurate intensity calibration method for low wavenumber Raman spectroscopy. It uses the rotational Raman spectrum of N₂. The intensity distributions in the rotational Raman spectra of diatomic molecules are theoretically well established. They can be used as primary intensity standards for intensity calibration. The intensity ratios of the Stokes and anti‐Stokes transitions originating from the same rotational levels are not affected by thermal population. Taking the effect of rotation–vibration interactions appropriately into account, we are able to calculate these intensity ratios theoretically. The comparison between the observed and calculated ratios of the N₂ pure rotational spectrum provides an accurate relative sensitivity curve (error ~5 × 10⁻⁴) in the wavenumber region of −150 to 150 cm⁻¹. We determine the temperature of water solely from the low wavenumber Raman spectra, using a thus calibrated spectrometer. The Raman temperature shows an excellent agreement with the thermocouple temperature, with only 0.5 K difference. The present calibration technique will be highly useful in many applications of low wavenumber quantitative Raman spectroscopy. Copyright © 2015 John Wiley & Sons, Ltd.     

Nonclassicality in off-resonant Raman process

The detuning parameter in experimentally feasible off-resonant Raman process is shown as a control parameter to probe and enhance the nonclassicality generated in the output of the process. Specifically, the normal characteristic function is obtained for the process as a function of detuning parameters in Stokes and anti-Stokes generation processes using more general solution than the conventional short-time solution under complete quantum treatment, which remains in the multimode Gaussian form. Single- and two-mode squeezing and antibunching as well as intermodal entanglement are reported in terms of experimentally accessible quantum noise fluctuations considering either phonon mode coherent or chaotic. Further, the joint photon-phonon number and integrated intensity distributions reveal a higher number of Stokes-phonon (pump-phonon) pair generation for the lower (higher) values of detuning parameter in Stokes generation. Pump-phonon pair generation is also supported by the lower values of detuning parameter in anti-Stokes generation.     

Improved anti-Stokes energy transfer between rare earth ions in Er（0.5）Yb（9.5）：FOV oxyfluoride vitroceramics explains the strong color reversal

The widely used energy transfer theory is a foundation of luminescence,in which the rates of Stokes and antiStokes processes have the same calculation formula.An improvement on the anti-Stokes energy transfer to explain the fluorescence intensity reversal between the red and green fluorescence of Er(0.5)Yb(9.5):FOV is reported in the present article.The range of the intensity reversal Σ was measured to be 877.Dynamic processes for 16 levels were simulated.A coefficient,the improvement factor of the intensity ratio of Stokes to anti-Stokes processes in quantum Raman theory compared to classical Raman theory,is introduced to successfully describe the anti-Stokes energy transfer.A new method to calculate the distance between the rare earth ions,which is critical for the energy transfer calculation,is proposed.The validity of these important improvements is also proved by experiment.     

斯托克斯和反斯托克斯拉曼位移差与时间反演对称性

首先列出若干Stokes和anti-Stokes位移不对称的事例,并在此基础上指出,如果将anti-Stokes散射严格定义为Stokes散射的时间反演行为,则对于初态或末态具有Kramers简并的体系,Stokes和anti-Stokes散射的拉曼位移可以不同.这是因为时间的正过程和反演过程各对应于不同的跃迁途径,其位移大小的差别与简并能级的分裂值相关.     

自发喇曼散射技术对燃烧场的诊断

 介绍了利用Nd:YAG激光的三倍频激发自发振动喇曼散射技术对燃烧场的诊断及相关的实验原理，测量了不同配比条件下的CH₄-air预混火焰内的主要组分(N₂，O₂，H₂O，CH₄)及其相对浓度；并分别用分子浓度测温法和斯托克斯谱与反斯托克斯谱强度比法测量了火焰的温度；还对该技术测温、测浓度的不确定度进行了分析。将该技术应用到对复杂的固体燃剂燃烧场的诊断，取得了燃烧场中几种主要燃烧组分（N₂，H₂CO，CH₄，H₂O）的喇曼光谱，以及这些组分在燃烧过程中的变化信息。     

Picosecond parametric Raman laser based on KGd(WO4)2 crystal

Simultaneous frequency up and down conversion using a biharmonically pumped parametric Raman laser (PRL) based on a KGd(WO₄)₂ (KGW) crystal has been demonstrated experimentally. Collimated beams have been generated for both the 1st anti-Stokes (1AS) at 511 nm and 2nd Stokes (2S) at 579 nm by four-wave parametric Raman interaction. To excite PRL biharmonically, we pumped the KGW crystal with 20 ps pulses at the fundamental 530 nm and its 1st Stokes component at 555 nm. The 1st Stokes pump beam was generated using stimulated Raman scattering in a separate KGW Raman oscillator. The energy conversion efficiencies reached experimentally were 10% for the 2S and 4% for the 1AS.     

The use of diode array detectors in conjunction with continuous wave gas lasers for anti-Stokes Raman spectroscopy

The Raman spectrum of any molecule consists of two mirror-image signals, th e Stokes and anti-Stokes Raman spectra. In most cases, unless highly specific sampling conditions are used, the anti-Stokes signal is much weaker than that of the Stokes. The recent application of intensified diode array detectors to Raman spectroscopy has produced a marked increase in the sensitivity of the technique which makes a study of the anti-Stokes spectrum potentially more rewarding than it has been to date. The present study has shown that, although of limited use for general purposes, there are some specific instances where the anti-Stokes spectrum can be of considerable practical use. Such applications are to extend the operating range of the Raman spectrometer, to study photodegradable samples and for the analysis of samples which exhibit strong fluorescence.     

Narrowband switchable dual-passband atomic filter with four-wave mixing optical amplification

By using Faraday optical filter combined with four-wave mixing (FWM) amplifier, a narrow bandwidth optical amplifying atomic filter with switchable dual-passband is demonstrated experimentally. The two transmission peaks of the filter correspond to the Stokes and anti-Stokes frequencies, exhibiting a Raman gain in 13- and 17-fold, respectively, with bandwidth of ～120 MHz. By properly setting pump laser detuning, switching between filter passbands is realized. We also investigate the dependence of peak transmission on both pump laser intensity and Rb cell temperature. This atomic filter can find practical applications in long-distance laser communications and laser remote-sensing systems.     

Measuring the uniaxial strain of individual single-wall carbon nanotubes: resonance Raman spectra of atomic-force-microscope modified single-wall nanotubes

Raman spectroscopy is used to measure the strain in individual single-wall carbon nanotubes, strained by manipulation with an atomic-force-microscope tip. Under strains varying from 0.06%-1.65%, the in-plane vibrational mode frequencies are lowered by as much as 1.5% (40 cm(-1)), while the radial breathing mode (RBM) remains unchanged. The RBM Stokes/anti-Stokes intensity ratio remains unchanged under strain. The elasticity of these strain deformations is demonstrated as the down-shifted Raman modes resume their prestrain frequencies after a nanotube is broken under excessive strain.     

单模石英光纤受激拉曼散射温度特性研究

研究了在不同温度下单模石英光纤的受激拉曼散射光谱,从实验和理论上分析了温度对拉曼散射光谱特性的影响,在脉冲调Q倍频YAG激光的泵浦作用下,获得了石英光纤一级斯托克斯光的拉曼频移、带宽及光强随温度的变化规律。实验表明随着温度的升高,拉曼频移逐渐增大,在一定的温度范围内拉曼频移和温度成线性关系。在相同的泵浦功率作用下,当温度较低时,拉曼光谱的级次较低, 低温对高阶斯托克斯光有抑制作用; 温度越低其阈值越高;而拉曼光谱的谱线宽度随温度的变化不是线性的,存在一个谱线宽度极大值点。理论和实验表明温度对光纤受激拉曼散射的光谱特性有直接的影响。     

强激光照射下,α-LiIO3晶体中晶格振动的多模激发和模之间的相互作用

本文叙述了用调Q倍频YAG脉冲激光照射α-LiIO₃晶体,在不同的散射配置下,获得了各种散射谱图。实验表明,当用e光入射时,可以比用o光入射激发起更多不同模的晶格振动;获得了E₂模的很强的一阶、二阶斯托克斯散射线和反斯托克斯散射线,E₁模Polariton的一阶、二阶、三阶斯托克斯线和反斯托克斯线,还获得了反斯托克斯频率区一条频移为469cm^-1的新线,认为是不同模的Polariton之间的相互作用引起的。最后,提到实验中初步观察到的晶体拉曼活性的“疲劳现象”。 关键词：     

硅甲烷射频放电分解动力学的CARS光谱研究

应用相干反斯托克斯喇曼光谱(CARS)技术对硅甲烷(SiH_4)的射频放电分解进行在位诊断.基于硅甲烷v_1振动模CARS信号强度的变化,研究了SiH_4-H_2及SiH_4-N_2体系中射频功率及总气压对硅甲烷分解速率的影响.此外,还用CARS方法检测硅甲烷分解的中间产物,得到信噪比较好的光谱,并试作了初步归属.     

光纤维中的喇曼混频

我们在656厘米^-1到1343厘米^-1的频率范围研究了光纤维的调谐喇曼混频(RM)效应。在实验中观察到下列现象:相干反斯托克斯喇曼散射(CARS)的大小与逆喇曼吸收(VRA)的大小成反比;RM对受激喇曼散射(SRS)的强度分布有强烈影响。除了观测到相干斯托克斯(CSRS)和CARS辐射,还观测到二级相干斯托克斯(SOCSRS)和相干反斯托克斯(SOCARS)辐射。对实验结果进行了讨论。 关键词：