RbH(X1∑+,v=O～2)能级与H2碰撞振动能量转移

利用积分时间分辨荧光光谱方法,研究了RbH(X1Σ+,v=0～2)与H2间的振动碰撞能量转移。在Rb-H2混合样品池中,泵浦激光双光子激发Rb原子至6D态,Rb(6D)与H2反应生成RbH(X1Σ+)分子,探测激光延迟泵浦激光20ns,通过激光感应荧光光谱(LIF)的测量,确定了X1Σ+(v=0～2,J)原生态的转动布居分布。增加检测激光与泵浦激光的延迟时间,测量了0～10μs延迟时间内各振动态时间分辨LIF强度,v=0,1能级荧光信号先增加后缓慢减弱,这是因为RbH在瞬间形成后通过碰撞转移和扩散而减少所致。通过速率方程分析,并利用振动能级上布居数变化与积分时间分辨荧光强度的关系,得到v=1→v=0和v=2→v=1的碰撞转移速率系数分别为(2.8±0.6)×10-11cm3·s-1和(3.4±0.8)×10-11cm3·s-1。而v=0,1,2的扩散率分别为(4.9±1.1)×105,(1.0±0.3)×105,(0.6±0.2)×105s-1。实验表明,v=2能级上布居数衰减率最大。     

激光激发Rb＋H2系统形成RbH分子机理的实验研究

在Rb-H2混合系统中用激光(泵浦激光)将基态Rb原子激发到Rb(5P3/2)能级,将调谐至5P3/2→7S1/2跃迁的另一激光束(检测激光)与泵浦激光反向平行通过样品池,并在池的直径方向平行移动,利用光学吸收法得到Rb(5P3/2)态的密度及其空间分布。由于辐射陷获存在,有效辐射率是自然辐射率与透射因子(发射的光子在探测区域内没有被吸收的平均概率,它与吸收截面及激发态原子密度和空间分布有关)的乘积。由5P3/2原子密度及其空间分布结合5P3/2←5S1/2跃迁线的碰撞增宽计算了透射因子。能量合并过程5P3/2 5P3/2→5S1/2 5D产生高位态5D原子,猝灭过程Rb(5P3/2) H2(v=0)→Rb(5S) H2(v=2)产生H2(v=2)态,H2(v=2)密度由Rb(5P3/2)与H2的碰撞猝灭截面得到。Rb(5D) H2和Rb(5P3/2) H2(v=2)发生碰撞反应可生成RbH分子,通过对不同H2密度时5D→5P3/2与5P3/2→5S1/2荧光强度比以及RbH分子X1Σ →A1Σ 跃迁线吸收光强的测量,首次得到了Rb(5D) H2→RbH H和Rb(5P3/2) H2(v=2)→RbH H的反应截面分别为4.02×10-17cm2和1.00×10-18cm2。实验表明,Rb(5P3/2) H2不直接生成RbH分子,而是通过二步反应产生的。     

Rb(5D_J)+H_2→RbH+H反应截面的测定

利用激光泵浦一吸收技术,研究了在样品池中(T=385 K,H2气压400 Pa)的Rb(5DJ)+H2→RbH+H[x1∑+(υ"=0)]+H光化学反应过程.双光子激发Rb-H2混合蒸气中Rb原子至52D态,荧光中除有泵浦能级发生的直接荧光外,还包含由精细结构碰撞转移产生的敏化荧光,RbH分子是由5D原子与H2间的三体碰撞反应产生的.利用852 nm激光扫描RbH X1∑+(υ"=0→υ'=17)吸收带,△I'和△I"分别表示泵浦5D3/2和5D5/2时的吸收光强.泵浦室温下的纯Rb蒸气至5D3/2或5D5/2态,由于在低密度下52D精细结构混合可略去,故由5D3/2→5P1/2与5D5/2→5P3/2的荧光比得到泵浦率比.解速率方程组,得到5D3/2→5D5/2和5D→5D以外态的碰撞转移截面分别是9.8×10-16和2.0×10-16cm2,Rb(5DJ)+H2→RbH+H的反应截面分别是5.4×10-17(J=3/2)和2.3×10-17cm2(J=5/2),5D3/2与H2的反应活动性大于5D5/2,这与其他实验结果是一致的.     

Rb与H_2的反应碰撞:Rb(6~2D)+H_2→RbH+H

在样品池条件下,应用脉冲激光的泵浦-检测技术,研究了Rb(6~2D)激发态原子与H_2反应碰撞生成的RbH分子的振转能级的布居数密度分布及平均转动能、振动能、平动能的相对比值.发现RbH(X~1∑~+)只有v=0,1上有布居.转动带分布轮廓与池温下的统计分布接近,得到RbH的Boltzmann转动温度稍低于池温,而振动温度高.v=1和v=0上的布居数之比约为0.69,从而得到RbH(X~1∑~+)上平均转动能和平均振动能,由反应的有效能得到平均平动能,这三种能量的相对比值f_R:f_V:     

高激发振动态RbH（Х1Σ+,ν″=15～22）与H2,N2的振动-振动碰撞能量转移

脉冲激光激发Rb原子至6 D态,Rb(6 D)与H2反应生成RbH(Х1Σ+,ν″=0～2)振动态。研究了RbH(Х1Σ+)高位振动态与H2,N2间的碰撞弛豫过程,利用泛频泵浦分别激发Х1Σ+(ν″=0)至Х1Σ+(ν″=15～22)各振动态,检测激光激发Х1Σ+(ν″)至A1Σ+(ν′),测量A1Σ+(ν′)的时间分辨激光感应荧光光谱,利用Stern-Volmer方程,得到振动能级ν″的总的弛豫速率系数kν(H2)。在H2和N2的混合气体中,总弛豫速率系数kν(H2+N2)与α(H2的摩尔配比)成直线的关系,其斜率为kν(H2)-kν(N2),而截距为kν(N2)。对于ν″<18主要发生单量子弛豫(Δν=1)过程,kν(H2)和kν(N2)与振动量子数ν″均成线性增加关系。对于ν″≥18,多量子弛豫(Δν≥2)过程及共振振动-振动转移起重要作用。对于RbH(ν″=21)+N2(0),测量ν″=16的布居数时间演化轮廓,在20μs内有一个锐锋,在100～200μs内有一个较低的宽峰,锐锋相应于RbH(ν″=21)+N2(0)→RbH(ν″=16)+N2(1)的共振转移过程,而宽峰是由相继的单量子过程产生的。     

Cs(6D5/2)+H2→CsH[X1∑+(v,J)]+H转动分辨总截面的测量

利用泵浦-检测方法,在样品池条件下,研究了Cs(6D5/2)与H2反应碰撞传能过程.利用激光感应荧光(LIF)光谱技术,确定了CsH[X1∑+(v,J)]振转能级上的布居分布,转动态分布与热统计分布基本一致.Cs激发态原子密度由激光能量吸收得到.记录A1∑+(v',J+1)→X1∑+(v,J)的时间分辨荧光,从荧光强度的对数值给出的直线斜率确定(v',J+1)→(v,J)的自然辐射率,结合(v,J)→(v',J+1)吸收系数的测量,得到反应生成物CsH[x1∑+(v,J)]态的分子密度.由速率方程分析,给出反应截面σ(v,J),对J求和,得到σ(v)[10-16 cm2单位]分别为(0.64士0.19)(v=0)和(0.58士0.17)(v=1).     

Cs(6D5/2)+H2→CsH[ X1Σ+(v,J)]+H转动分辨总截面的测量

利用泵浦-检测方法,在样品池条件下,研究了Cs(6D5/2)与H2反应碰撞传能过程。利用激光感应荧光（LIF）光谱技术,确定了CsH[X1Σ+(v,J)]振转能级上的布居分布,转动态分布与热统计分布基本一致.Cs激发态原子密度由激光能量吸收得到.记录A1Σ+(v',J+1)→X1Σ+(v,J)的时间分辨荧光,从荧光强度的对数值给出的直线斜率确定(v',J+1)→(v,J)的自然辐射率,结合(v,J)→(v',J+1)吸收系数的测量,得到反应生成物CsH[X1Σ+(v,J)]态的分子密度.由速率方程分析,给出反应截面(v,J),对J求和,得到(v)[10-16cm2单位]分别为（0.64±0.19）（v=0）和（0.58±0.17）（v=1）.     

高位振动态RbH(X1∑+,v″≧15)与CO2碰撞转移中的能量相关性

研究了高位振动态RbH(X1∑+,v″=15～21)与CO2碰撞转移过程.脉冲激光激发RbH至高位态,利用激光感应荧光光谱(LIF)得到RbH(X1∑+,v″)与CO2的猝灭速率系数kv″(CO2),kv″=21(CO2)=2.7kv″=15(CO2).利用激光泛频光谱技术,测量了CO2(0000,J)高转动态分布,得到了转动温度,从而获得了平均转动能＜Erot＞和转动能的变化＜△Erot＞,发现＜△Erot＞v″=21≈2.9＜△Erot＞v″=15.对于v″=16,证实了振动—振动能量转移的4-1近共振过程.在一次碰撞条件下,通过速率方程分析,得到RH(v″)-CO2振转速率系数.对于v″=15,J=32-48,速率系数在1.25-0.33×10-13 cm3 s-1.之间;对于v″=21,速率系数在2.47-1.53×10-13 cm3 s-1之间,其能量相关性是明显的.     

高位振动态RbH(Х1Σ+,v″≧15) 与CO2碰撞转移中的能量相关性

研究了高位振动态RbH(Х1Σ+,v″=15-21)与CO2碰撞转移过程。脉冲激光激发RbH至高位态,利用激光感应荧光 光谱(LIF)得到RbH(Х1Σ+,v″)与CO2的猝灭速率系数,。利用激光泛频光谱技术,测量了CO2(0000,J)高转动态分布。得到了转动温度,从而获得了平均转动能和转动能的变化<ΔErot>,发现。对于v"=16,证实了振动—振动能量转移的4-1近共振过程。在一次碰撞条件下,通过速率方程分析,得到RH(v")-CO2振转速率系数。对于v"=15,J=32-48,速率系数在1.25-0.33×10-13cm3s-1.之间,对于v"=21,速率系数在2.47-1. 53×10-13cm3s-1之间,其能量相关性是明显的。     

激光激发Cs+H_2系统形成CsH分子机理的实验研究

在Cs-H2混合系统中用激光将Cs原子激发到6P3/2能级,研究了CsH分子的形成机制.利用光学吸收法得到6P3/2态的密度及其空间分布,能量合并过程6P3/2+6P3/2→6D+6S1/2产生6D态原子;猝灭过程Cs(6P3/2)+H2(v=0)→Cs(6S1/2)+H2(v=2)产生H2(v=2)态.由6P3/2态原子密度及6D→6P3/2与6P3/2→6S1/2的荧光比得到碰撞能量合并速率系数,在不同的H2密度下,测量了转移荧光强度I895,得到了H2(2,J)态的产生速率系数kH2(2,J)=1.     

Excitation and relaxation of metastable state NaK(1 3pi) at high vibrational levels

The authors have investigated collision vibrational energy transfer rate constants in NaK[1 3pi(v)] and He system. Pump laser excitation of the spin-forbidden band was used to produce very highly vibrationally excited metastable state NaK[1 3pi (v = 22, 21, 20)]. The probe laser was used to excite the 1 3pi (v = 22, 21, 20) to 5 3pi(v'). Laser induced fluorescence (LIF) from 5 3pi --> 1 3sigma+ transition was used to follow the collision dynamics. The semilog plots of time-resolved LIF was obtained. The slopes yielded the effective lifetimes. From such data several Stern-Volmer plots could be constructed and the relaxation rate constants could be extracted for the sum of all processes that give rise to the decay of the prepared vibrational state. The rate constants (in units of 10(-11) cm3 x s(-1)) for v being 22, 21 and 20 are 1.4 +/- 0.1, 1.2 +/- 0.1 and 1.0 +/- 0.1, respectively. The vibrational relaxation rate is increasing with vibrational quantum number. In order to determine the importance of multiquantum relaxation, it is necessary to measure the relative population of both the prepared state and collisionally populated states. By the kinetic equations governing up to delta(v) = 2 transitions, the time dependence of populations of the vibrational states were obtained. With the help of the integrating the population equations over all time, the importance of the two-quantum relaxation could be studied experimentally. By varying the delay between the pump and the probe laser, the He pressure dependent vibrational state specific decay could be measured. The time evolutions and relative intensities of the three states v = 22, 21 and 20 by preparing v = 22 were obtained. Using experimental data the rate constants (in units of 10(-11) cm3 x s(-1)) for v = 22 --> 21 and v = 22 --> 20 are 0.67 +/- 0.15 and 0.49 +/- 0.12, respectively. The single quantum relaxation accounts for only about 48% of the total relaxation out of v = 22. Multi-quantum relaxation (delta(v) > 1) was found to be important at high vibrational states.     

激光烧蚀Al热原子与CF4,CCl4,CH2Br2反应中激发态C2的形成

脉冲激光烧蚀平面铝靶产生的热原子与气相CF4,CCl4,CH2Br2的碰撞反应中,在430～600nm之间观测到激发态C2分子的发光光谱,它们可归属为Swan带的d^3Ⅱg=a^3Ⅱu跃迁中△v=2,1,0,-1,-2五个振动序列(v′≤6)。谱强度分析表明,C2激发态可很好的用热平衡描述,其振动温度达6000K左右。同时在△v=0和-1的振动带间观测到振荡的谱峰,它们是转动谱线叠加的结果。激光烧蚀Al产生的等离子体在膨胀中产生的激波及其本身的动能与反应气体碰撞使其解离产生C,然后复合形成C2。C2激发态d可能是通过激发态的Al(^2S)经近共振传能产生,也不排除在有足够碰撞能下优先形成C2激发态b,再通过与d态的v′=6能级交叉无辐射跃迁而进入d态。     

Cs(6 ~2D_(5/2))与H_2反应生成的CsH分子的转动和振动态分布

利用激光泵浦-探测技术,在样品池条件下,研究了Cs(6D5/2)态与H2反应生成的CsH分子基电子态的转动和振动的量子态分布。在Cs-H2混合蒸气中,脉冲激光双光子激发Cs(6D5/2)态,另一台调频脉冲激光器扫描CsHX1Σ+(v″,J″)→A1Σ+(v′,J′=J″±1)吸收线,发现CsH分子只有v″=0和1上的振动带上有布居而不布居在v″1的振动带上。v″=0和1上的转动带分布呈现单峰结构,其峰值位于J″=6～8处,转动带分布轮廓与池温下的统计分布接近。转动Boltzmann温度分别为(458±20)K(对v″=1)和(447±18)K(对v″=0),得到的CsH分子的转动温度稍低于池温。从转动态分布得到v″=1与v″=0上布居数之比约为0.897,从而计算出CsH基电子态上的平均转动能ER和平均振动能EV,有效能减去平均振转能得到平均平动能ET。CsH分子3种能量的相对比值fT∶fV∶     

氢分子振动态与铯分子基态碰撞中转动-振动能量转移

利用受激拉曼泵浦将H2激发到v=1，J=3态，研究了H2(1, 3)态与Cs2分子碰撞(1, 3)态的弛豫及Cs2(X1+g)振动态的激发过程。利用相干反斯托克斯拉曼散射(CARS)检测H2的振转态分布，由CARS峰值得到密度比[H2(1, 3)]/[H2(0, 3)]和[H2(1, 1)]/[H2(1, 3)]，由H2(v=0)振转态的Boltzmann分布确定H2(0, 3)的密度，由此得到[H2(1, 3)]和[H2(1, 1)]态的密度。激光诱导荧光光谱(LIF)确定被碰撞激发的Cs2(X1+g, v=11-15)各态。利用单模半导体激光作瞬时光吸收，对于v= 11, 12, 13, 14和15，积分吸收系数(单位：106cm-1s-1)分别是6.5，7.9，7.0，6.1和4.7，结合H2(1, 3)的密度，得到H2(1, 3)Cs2(X1+g, v)的转移速率系数，对于v=11-15，分别是(单位：10-13cm-1s-1)1. 40. 6，1.70. 7，1.50. 6，1.30.5和1.00. 4。利用吸收线Doppler增宽测量分别得到了Cs2(X1+g, v=11-15)的平动能。     

Characterization of the Ground State of Br(2) by Laser-Induced Fluorescence Fourier Transform Spectroscopy of the B(3)Pi(0(+))(u)-X(1)Sigma(+)(g) System

The laser-induced fluorescence (LIF) spectrum of the B(3)Pi(0(+))(u)-X(1)Sigma(+)(g) system of Br(2) was recorded by Fourier transform spectroscopy (FTS). The LIF spectra were obtained by using continuous-wave dye laser excitation in the spectral region 16 800-18 000 cm(-1). About 1800 rotationally resolved lines were recorded in 96 fluorescence progressions, originating from the 10 相似文献   

利用发射光谱研究脉冲电晕放电中的自由基

利用发射光谱技术在大气压下测量了以氮气为载气的不饱和水蒸气体系针-板式正脉冲电晕放电产生的OH(A^2∑→X^2Ⅱ0—O)自由基和O(3p^5P→3s^5S^02777．4nm),Ha(3P→2S 656．3nm)活性原子的发射光谱,并由N2(C^3Ⅱu→B^3Ⅱg)的△v=-3和△v=-4振动带序发射光谱强度计算得出N2(C,v)的相对振动布居及其振动温度,进而采用高斯分布拟合准确地求出了N2(C^3Ⅱu→B^3Ⅱg)的△v= 1振动带序发射光谱强度,从而可以由N2(C^3Ⅱu→B^3Ⅱg)的△v= 1振动带序与OH(A^2∑→X^2Ⅱ0—0)的重叠发射光谱中准确求出OH(A^2∑→X^2Ⅱ0—0)自由基的发射光谱强度。由发射光谱强度得到了激发态OH(A^3∑)自由基和O(3p^5P),Ha(3P)活性原子的布居。还研究了激发态OH(A^2∑)自由基和O(3p^5P),Ha(3P)活性原子的布居随放电电压和放电频率的变化以及氧气对激发态OH(A^2∑)自由基和O(3p^5P),Ha(3P)活性原子布居的影响。     

Collision-induced vibrational energy transfer: K2[1(1) sigmau+ (nu'=2)]+He, H2-->K2[1(1) sigmau+(nu'=1,3)]+He, H2

Collisional energy transfer processes K2[1(1) sigmau+ (nu'=2)]+He, H2-->K2[1(1) sigmau+(nu'=1,3)]+He, H2 were studied by laser induced fluorescence under gas cell conditions. During the experiments, the cell temperature was kept constant at 420K. The buffer gas pressure was varied over the range from 40 to 250 Pa, Kz molecules were irradiated with pulses of radiation from an OPO laser, populating K2[1(1) sigmau+ (nu'=2)] by photon absorption. The resulting fluorescence included the direct component emitted in the decay of the optically excited state and the sensitized components arising from collisionally populated states. The decay signal of time-resolved fluorescence from 1(1) sigmau+ (nu'=2)]-->1(1) sigmag+(nu"=0) transition was monitored. In the early period after excitation, only very little population in states v'= 1 or 3 had yet accumulated, the rate of collisional activation to the state nu'=2 was negligible. The decay curve of the nu' = 2-->nu" = 0 was treated as a single exponential function. From the measurement of the time-resolved fluorescence, the semilog plot was shown. The slope yielded the effective lifetime of the nu' = 2--> nu' = 0 transition. Based on the Stern-Volmer equation, the radiative lifetime (36 +/- 7) ns was obtained. The total cross sections for deactivation of 1(1) sigmau1 (nu'=2) state by means of collisions with He and H2 are (3.0 +/- 0.5) x 10(-16) cm2 and (6.4 +/- 1.2) x 10(-15) cm2, respectively. The radiative lifetimes of 1(1) sigmau+(nu' = 1,3) states can also be determined through time-resolved fluorescence in pure K vapor. The time-integrated intensities of 1(1)sigmau+(nu' = 1,2,3)-->1(1) sigmag+(nu"=0) transition at different He or Hz pressure were measured. The ratio of fluorescence intensities versus 1/P(He, H2) can be fitted by a straight line. The slopes yield the cross sections sigma(nu'=2-->nu'=1) = (1.4 +/- 0.5) x 10(-16) cm2 and (3.2 +/- 1.0) x 10(-15) cm2; sigma(nu'=2-->nu'=3)= (1.2 +/- 0.4) x 10(-16) cm2 and (2.6 +/- 0.9) x 10(-15) cm2 for He and H2, respectively. Cross sections for the effective quenching of the nu' = 1,2,3 states were also determined. To our knowledge, the cross-sections for these processes are reported for first time.     

氢分子振动态与铯分子基态碰撞中转动-振动能量转移

利用受激拉曼泵浦将H2激发到v=1,J=3态,研究了H2(1, 3)态与Cs2分子碰撞(1, 3)态的弛豫及Cs2(X1+g)振动态的激发过程。利用相干反斯托克斯拉曼散射(CARS)检测H2的振转态分布,由CARS峰值得到密度比[H2(1, 3)]/[H2(0, 3)]和[H2(1, 1)]/[H2(1, 3)],由H2(v=0)振转态的Boltzmann分布确定H2(0, 3)的密度,由此得到[H2(1, 3)]和[H2(1, 1)]态的密度。激光诱导荧光光谱(LIF)确定被碰撞激发的Cs2(X1+g, v=11-15)各态。利用单模半导体激光作瞬时光吸收,对于v= 11, 12, 13, 14和15,积分吸收系数(单位：106cm-1s-1)分别是6.5,7.9,7.0,6.1和4.7,结合H2(1, 3)的密度,得到H2(1, 3)Cs2(X1+g, v)的转移速率系数,对于v=11-15,分别是(单位：10-13cm-1s-1)1. 40. 6,1.70. 7,1.50. 6,1.30.5和1.00. 4。利用吸收线Doppler增宽测量分别得到了Cs2(X1+g, v=11-15)的平动能。