Frigerio Leandro, Latty Kyle, Burger Miloš, Hartig Kyle C, Jovanovic Igor
Opt Lett. 2024 Sep 1;49(17):4942-4945. doi: 10.1364/OL.531216.
Ultrafast laser pulse filamentation in the air can be used for remote sensing by exciting a characteristic optical emission, which is usually referred to as filamentation-induced breakdown spectroscopy. In environments that impede light propagation, such as fog, haze, or clouds, scattering makes it challenging to propagate laser beams and retrieve generated optical signatures. We demonstrate the effectiveness of laser filamentation for simultaneously clearing the path for intense femtosecond pulse propagation in a highly scattering medium, generation of luminous plasma on a solid target, and counter-propagation of a characteristic spectroscopic signal over a cleared channel along the filament path. In a dense cloud, the counter-propagating signal predominantly transits the cleared on-axis path but is highly affected by the negative thermal lensing of a Gaussian beam. These insights enhance our understanding of laser filamentation in atmospheric sensing and could substantially improve remote detection capabilities in poor visibility conditions.
空气中的超快激光脉冲丝状化可通过激发一种特征特征光发射特性用于遥感,这种光发射特性通常被称为丝状化诱导击穿光谱学。在阻碍光传播的环境中,如雾、霾或云层,散射使得激光束的传播以及获取产生的光学信号具有挑战性。我们展示了激光丝状化在高散射介质中同时为强飞秒脉冲传播清除路径、在固体靶上产生发光等离子体以及沿丝状路径在清除通道上反向传播特征光谱信号的有效性。在浓密云层中,反向传播信号主要通过清除的轴上路径传输,但受到高斯光束负热透镜效应的强烈影响。这些见解增进了我们对大气传感中激光丝状化的理解,并可大幅提高能见度不佳条件下的远程探测能力。