飞秒激光诱导水中的纳米空化：对光学击穿阈值和细胞手术的影响。

Femtosecond-laser-induced nanocavitation in water: implications for optical breakdown threshold and cell surgery.

作者信息

Vogel Alfred, Linz Norbert, Freidank Sebastian, Paltauf Günther

机构信息

Institute of Biomedical Optics, University of Lübeck, Peter-Monnik-Weg 4, Lübeck, Germany.

出版信息

Phys Rev Lett. 2008 Jan 25;100(3):038102. doi: 10.1103/PhysRevLett.100.038102. Epub 2008 Jan 23.

DOI:10.1103/PhysRevLett.100.038102

PMID:18233040

Abstract

We determined the bubble radius R_(max) for femtosecond optical breakdown in water at 347, 520, and 1040 nm with an unprecedented accuracy (+/-10 nm). At threshold, R_(max) was smaller than the diffraction-limited focus radius and ranged from 190 nm to 320 nm. The increase of R_(max) with laser energy E_(L) is slowest at 347 nm, providing optimum control of cell surgery. Experimental results agree with a model of bubble formation in heated and thermoelastically stretched liquids. Theory predicts a threshold temperature T_(th) approximately equal to 168 degrees C. For T>300 degrees C, a phase explosion sets in, and R_(max) increases rapidly with E_(L).

摘要

我们以前所未有的精度（±10纳米）测定了在347、520和1040纳米波长下水中飞秒光击穿的气泡半径R_(max)。在阈值时，R_(max)小于衍射极限聚焦半径，范围为190纳米至320纳米。R_(max)随激光能量E_(L)的增加在347纳米波长下最慢，这为细胞手术提供了最佳控制。实验结果与加热和热弹性拉伸液体中气泡形成的模型相符。理论预测阈值温度T_(th)约等于168摄氏度。对于T>300摄氏度，会发生相爆炸，且R_(max)随E_(L)迅速增加。

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飞秒激光诱导水中的纳米空化：对光学击穿阈值和细胞手术的影响。

Femtosecond-laser-induced nanocavitation in water: implications for optical breakdown threshold and cell surgery.

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