»ã±¨±êÌâ (Title)£ºÇ¿³¡ÖзÖ×ÓÀë×ӵIJúÉú¡¢ÑÝ»¯¼°·øÉä

»ã±¨ÈË (Speaker)£ºÐ»ºìÇ¿£¨¶«»ªÀí¹¤´óѧ£©

»ã±¨¹¦·ò (Time)£º2025Äê11ÔÂ18ÈÕ (Öܶþ) 14:00-16:00

»ã±¨µØÖ· (Place)£ºÌÚѶ»áÒé128-831-323

Ô¼ÇëÈË (Inviter)£º´÷êÊ

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ÌáÒª (Abstract)£ºIons represent one of the most abundant products when atoms or molecules interact with an intense femtosecond laser field. Nevertheless, our current understanding of their quantum properties remains limited. Over the past decade, the observation of coherent ultraviolet-to-visible emissions from nitrogen molecular ions generated via strong-field ionization has sparked growing interest in ion-related physics. Significant efforts have been devoted to uncovering the mechanisms behind these novel laser-like radiations and exploring their potential applications, such as in remote atmospheric sensing. Interestingly, the N?? system exhibits a ¡°kaleidoscopic¡± nature, allowing experimenters to observe a variety of phenomena under different laser parameters¡ªyet this very diversity complicates the interpretation of the underlying physical processes. In this talk, I will present recent advances in elucidating the complex physical mechanism behind ionic lasing from multiple perspectives¡ªa topic of ongoing debate in the field. By introducing a strong-field ionization-coupling model that accounts for electronic, vibrational, and rotational states, we are able to fully characterize ionic dynamics in intense laser fields. This model provides a unified physical picture for the emergence of N?? lasing. Furthermore, I will discuss the development of a stimulated and coherent Raman scattering technique based on ionic air lasing, which enables non-invasive, high-sensitivity detection of trace gases and air pollutants.