Investigating the apparent anomalous cooling of soot during laser-induced incandescence experiments

IF 2 3区物理与天体物理 Q3 OPTICS

Applied Physics B Pub Date : 2025-12-18 DOI:10.1007/s00340-025-08550-8

Stephen Robinson-Enebeli, Christof Schulz, Kyle J. Daun

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Abstract

While time-resolved laser-induced incandescence (TiRe-LII) has become a standard laser-based diagnostic for soot, there remain unexplained observations in some datasets. One such effect is the so-called “anomalous cooling”, in which the pyrometric temperature decays faster than can be explained by conventional heat transfer models immediately following the peak temperature. This work investigates this phenomenon through experiments on soot entrained in different bath gases and irradiated in the low-fluence regime, where particle sublimation is minimal. The anomalous cooling phenomenon is caused by the contribution of particles in the probe volume that have been heated beyond the sublimation threshold to the overall incandescence signal, due to nonuniform laser fluence. Particles in these “hot spot” regions feature a faster cooling rate due to sublimation, contributing to the effect of apparent anomalous cooling. Particle-size polydispersity also plays a notable but minor role. The effect depends on the bath-gas composition, which is attributed to differences in species-specific heat transfer.

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研究在激光诱导白炽实验中烟灰的明显异常冷却

虽然时间分辨激光诱导白炽灯（TiRe-LII）已成为基于激光诊断烟灰的标准方法，但在一些数据集中仍存在无法解释的观察结果。其中一种效应就是所谓的“反常冷却”，即高温衰减速度比传统传热模型所能解释的要快。本研究通过对不同浴气中夹带的煤烟进行实验，并在颗粒升华最小的低通量状态下辐照，研究了这一现象。异常冷却现象是由探针体积中被加热到超过升华阈值的粒子对整个白炽信号的贡献引起的，这是由于不均匀的激光影响。这些“热点”区域的粒子由于升华而具有更快的冷却速度，从而导致明显的异常冷却效果。粒径多分散性也起着显著但次要的作用。这种影响取决于浴气成分，这是由于物种特有的传热差异造成的。

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来源期刊

Applied Physics B 物理-光学

CiteScore

4.00

自引率

4.80%

发文量

202

审稿时长

3.0 months

期刊介绍： Features publication of experimental and theoretical investigations in applied physics Offers invited reviews in addition to regular papers Coverage includes laser physics, linear and nonlinear optics, ultrafast phenomena, photonic devices, optical and laser materials, quantum optics, laser spectroscopy of atoms, molecules and clusters, and more 94% of authors who answered a survey reported that they would definitely publish or probably publish in the journal again Publishing essential research results in two of the most important areas of applied physics, both Applied Physics sections figure among the top most cited journals in this field. In addition to regular papers Applied Physics B: Lasers and Optics features invited reviews. Fields of topical interest are covered by feature issues. The journal also includes a rapid communication section for the speedy publication of important and particularly interesting results.