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丙三醇溶液声致发光中的黑体辐射谱 总被引:1,自引:0,他引:1
利用U型管圆锥泡声致发光装置,测量到了丙三醇溶液中圆锥泡声致发光的光谱和光脉冲。结果表明,测量得到的发光光谱为光滑的连续谱,且与理论模拟得到的黑体辐射谱相吻合,拟合温度分布于2 600~3 500 K范围内。文章从空间和时间两方面分析了圆锥泡空化发光中存在黑体辐射的原因:较大的气泡体积(气泡塌缩半径为1.4 cm)与较长的发光时间(几十微秒)。另外,实验研究表明随着发光波长的增长,光脉冲宽度变宽,从而进一步证明了圆锥泡声致发光中的黑体辐射机制。最后,利用测量得到的发光光谱和脉冲计算得到了发光光强为0.18 J,远远高于其他方式得到的声致发光光强。 相似文献
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在U型管声致发光装置的基础上建立了一套新型的声致发光装置—直管圆锥泡声致发光装置,详细地介绍了此装置的结构和实验操作步骤,利用此装置得到了超强的发光脉冲。测量得到了乙二醇溶液中圆锥泡声致发光的发光脉冲,结果显示脉冲半宽度大约为80 μs左右,远远高于其他声致发光形式所产生的脉冲宽度,这主要是由于圆锥泡可以获得远远高于超声声致发光中气泡所能得到的能量。发光光谱为一从紫外光至可见光波长范围的连续谱,上面叠加C2有d3Πg→d3Πu的跃迁形成的五个序列谱带,分别对应于Δν=-2,Δν=-1,Δν=0,Δν=1和Δν=2;同时叠加有CN的B2Σ+→X 2Σ+跃迁形成的3个序列谱带和CH的A2Δ→X 2Π 跃迁谱带。特别是实验中测量得到了斯旺带光谱序列谱带清晰的振动结构。最后,通过与理论模拟得到的斯旺带光谱相对强度的比较,估算得到了C2分子的振动温度大约为(4 200±200) K。 相似文献
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介绍两种使用流体动力学实现声致发光的方法:刹管法和U管圆锥泡法.这两种方法的设备简单,操作方便,容易在普通物理实验中进行,所得结果和传统单泡声致发光有所不同.U管圆锥泡法创造了发光功率和单脉冲能量的新记录,并首次用条纹相机得到了时间分辨发射光谱. 相似文献
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在溶有稀有气体的稀土盐氯化铽水溶液中进行了单泡声致发光光谱的研究. 在固定驱动超声频率、不同驱动声压下, 观察到了一系列OH自由基从第一激发态A2∑+到基态X2Π 各振动能级跃迁所产生的谱线, 包括波长307 nm处的(0, 0)跃迁谱线, 335 nm处的(0, 1)跃迁谱线以及276 nm处的(1, 0) 跃迁谱线等. 实验结果表明较高的驱动声压有利于 276 nm处谱线的产生, 而较低的驱动声压则有利于 307 与 335 nm 处谱线的产生. 通过定义线状光谱与连续谱的光强比, 定量地表征了线状光谱在总光谱中的相对强度, 并给出了驱动声压对各跃迁谱线光强比的影响.
关键词:
单泡声致发光
驱动声压
线状光谱
光强比 相似文献
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买买提吐送.买买提明 《应用声学》2013,32(4):325-封三
对不同厚度液体进行光强测量,深入探索空化气泡的运动,研究发光机理很有意义。用超声激励法在磷酸液体中实现多泡声致发光,研究不同共振频率下发光的特点。利用光电倍增管多次测量发光强度相互比较,结果是在液体厚度10 cm、驱动频率f=21.061kHz和f=20.316kHz时,周期性较好为50μs,液体通过漩涡集中气泡可以使更多气泡发光;在液体厚度3 mm、驱动频率f=17.91kHz和f=19kHz时,周期性很好为25μs;且光信号都较强。结论是磷酸中声致发光强度、周期与液体厚度、驱动频率密切相关。本文以磷酸液多泡声致发光实验研究为基础,从内部和外部原理来出发,详细介绍了光电倍增管在多泡声致发光光强测量中的实用,为今后研究者提供了一些经验。根据实验过程中遇到的一些实际问题提出了建议和改善意见。 相似文献
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A modified U-tube conical bubble sonoluminescence device is used to
study the conical bubble photoluminescence. The spectra of conical
bubble sonoluminescence at different concentrations of rhodamine 6G
(Rh6G) solution in 1,2-propanediol have been measured. Results show
that the sonoluminescence from the conical bubbles can directly
excite Rh6G, which in turn can fluoresce. The light emission of this
kind is referred to as conical bubble photoluminescence. The maximum
of fluorescence spectral line intensity in the conical bubble
photoluminescence has a red shift in relative to that of the
standard photo-excited fluorescence, which is due to the higher
self-absorption of Rh6G, and the spectral line of conical bubble
photoluminescence is broadened in width compared with that of
photo-excited fluorescence. 相似文献
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We review recent work on the use of sonoluminescence (SL) to probe spectroscopically the conditions created during cavitation, both in clouds of collapsing bubbles (multibubble sonoluminescence, (MBSL)) and in single bubble events. The effective MBSL temperature can be controlled by the vapor pressure of the liquid or the thermal conductivity of the dissolved gas over a range from ~1600 to ~9000K. The effective pressure during MBSL is ~300bar, based on atomic line shifts. Given nanosecond emission times, this means that cooling rates are >10(12)K/s. In sulfuric and phosphoric acid, the low volatility and high solubility of any sonolysis products make bubble collapse more efficient and evidence for an optically opaque plasma core is found. 相似文献
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Computational simulation of ionization processes in single-bubble and multi-bubble sonoluminescence 下载免费PDF全文
Jin-Fu Liang 《中国物理 B》2022,31(11):117802-117802
The most recent spectroscopic studies of moving-single bubble sonoluminescence (MSBSL) and multi-bubble sonoluminescence (MBSL) have revealed that hydrated electrons (e$_{{\rm aq}}^{-}$) are generated in MSBSL but absent in MBSL. To explore the mechanism of this phenomenon, we numerically simulate the ionization processes in single- and multi-bubble sonoluminescence in aqueous solution of terbium chloride (TbCl$_{3}$). The results show that the maximum degree of ionization of single-bubble sonoluminescence (SBSL) is approximately 10000 times greater than that of MBSL under certain special physical parameters. The hydrated electrons (e$_{{{\rm aq}}}^{-}$) formed in SBSL are far more than those in MBSL provided these electrons are ejected from a bubble into a liquid. Therefore, the quenching of e$_{{{\rm aq}}}^{-}$ to SBSL spectrum is stronger than that of the MBSL spectrum. This may be the reason that the trivalent terbium [Tb(III)] ion line intensities from SBSL in the TbCl$_{3}$ aqueous solutions with the acceptor of e$_{{{\rm aq}}}^{-}$ are stronger than those of TbCl$_{3}$ aqueous solutions without the acceptor of e$_{{{\rm aq}}}^{-}$. Whereas the Tb(III) ion line intensities from MBSL are not variational, which is significant for exploring the mechanism behind the cavitation and sonoluminescence. 相似文献
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《应用光谱学评论》2013,48(3):399-436
Abstract Sonoluminescence is the light emission phenomenon from collapsing bubbles in liquid irradiated by an ultrasonic wave. In the present review, theoretical and experimental studies of the two types of sonoluminescence [single‐bubble sonoluminescence (SBSL) and multibubble sonoluminescence (MBSL)] are described. SBSL is a sonoluminescence from a single stably pulsating bubble trapped at the pressure antinode of a standing ultrasonic wave. MBSL is a sonoluminescence occurring from many bubbles in liquid irradiated by an ultrasonic wave. The theoretical and experimental studies suggest that SBSL originates in emissions from plasma inside the heated bubble at the bubble collapse, whereas MBSL originates both in emissions from plasma and in chemiluminescence inside heated bubbles at the bubble collapse. Unsolved problems of sonoluminescence have also been explained in detail. 相似文献
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Key to the dynamics of the type of bubble collapse which is associated with such phenomena as sonoluminescence and the emission of strong rebound pressures into the liquid is the role of the liquid inertia. Following the initial formulation of the collapse of an empty spherical cavity, such collapses have been termed "Rayleigh-like." Today this type of cavitation is termed "inertial," reflecting the dominant role of the liquid inertia in the early stages of the collapse. While the inertia in models of spherical bubble collapses depends primarily on the liquid, experimental control of the liquid inertia has not readily been achievable without changing the liquid density and, consequently, changing other liquid properties. In this paper, novel experimental apparatus is described whereby the inertia at the early stages of the collapse of a conical bubble can easily be controlled. The collapse is capable of producing luminescence. The similarity between the collapses of spherical and conical bubbles is investigated analytically, and compared with experimental measurements of the gas pressures generated by the collapse, the bubble wall speeds, and the collapse times. 相似文献