Confined micro-explosion induced by ultrashort laser pulse at SiO 2/Si interface

Ludovic Rapp; Bianca Haberl; Jodie E. Bradby; Eugene G. Gamaly; Jim S. Williams; Andrei V. Rode

doi:10.1007/s00339-013-8161-x

Confined micro-explosion induced by ultrashort laser pulse at SiO ₂/Si interface

Ludovic Rapp, Bianca Haberl, Jodie E. Bradby, Eugene G. Gamaly, Jim S. Williams, Andrei V. Rode^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

13 Citations (Scopus)

Abstract

Ultrashort laser pulses tightly focused inside a transparent material present an example of laser interaction with matter where all the laser-affected material remains inside the bulk, thus the mass is conserved. In this paper, we present the case where the high intensity of a laser pulse is above the threshold for optical breakdown, and the material is ionised in the focal area. We consider in detail a special case where a micro-explosion is formed at the boundary of a silicon surface buried under a 10-micron-thick oxidised layer, providing the opportunity to affect the silicon crystal by a strong shock wave and creating new material phases from the plasma state. We summarise the main conclusions on ultrafast laser-induced material modifications in confined geometry and discuss the prospects of confined micro-explosion for forming new silicon phases.

Original language	English
Pages (from-to)	33-43
Number of pages	11
Journal	Applied Physics A: Materials Science and Processing
Volume	114
Issue number	1
DOIs	https://doi.org/10.1007/s00339-013-8161-x
Publication status	Published - Jan 2014

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title = "Confined micro-explosion induced by ultrashort laser pulse at SiO 2/Si interface",

abstract = "Ultrashort laser pulses tightly focused inside a transparent material present an example of laser interaction with matter where all the laser-affected material remains inside the bulk, thus the mass is conserved. In this paper, we present the case where the high intensity of a laser pulse is above the threshold for optical breakdown, and the material is ionised in the focal area. We consider in detail a special case where a micro-explosion is formed at the boundary of a silicon surface buried under a 10-micron-thick oxidised layer, providing the opportunity to affect the silicon crystal by a strong shock wave and creating new material phases from the plasma state. We summarise the main conclusions on ultrafast laser-induced material modifications in confined geometry and discuss the prospects of confined micro-explosion for forming new silicon phases.",

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AU - Rapp, Ludovic

AU - Haberl, Bianca

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AU - Gamaly, Eugene G.

AU - Williams, Jim S.

AU - Rode, Andrei V.

PY - 2014/1

Y1 - 2014/1

N2 - Ultrashort laser pulses tightly focused inside a transparent material present an example of laser interaction with matter where all the laser-affected material remains inside the bulk, thus the mass is conserved. In this paper, we present the case where the high intensity of a laser pulse is above the threshold for optical breakdown, and the material is ionised in the focal area. We consider in detail a special case where a micro-explosion is formed at the boundary of a silicon surface buried under a 10-micron-thick oxidised layer, providing the opportunity to affect the silicon crystal by a strong shock wave and creating new material phases from the plasma state. We summarise the main conclusions on ultrafast laser-induced material modifications in confined geometry and discuss the prospects of confined micro-explosion for forming new silicon phases.

AB - Ultrashort laser pulses tightly focused inside a transparent material present an example of laser interaction with matter where all the laser-affected material remains inside the bulk, thus the mass is conserved. In this paper, we present the case where the high intensity of a laser pulse is above the threshold for optical breakdown, and the material is ionised in the focal area. We consider in detail a special case where a micro-explosion is formed at the boundary of a silicon surface buried under a 10-micron-thick oxidised layer, providing the opportunity to affect the silicon crystal by a strong shock wave and creating new material phases from the plasma state. We summarise the main conclusions on ultrafast laser-induced material modifications in confined geometry and discuss the prospects of confined micro-explosion for forming new silicon phases.

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JO - Applied Physics A: Materials Science and Processing

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Confined micro-explosion induced by ultrashort laser pulse at SiO ₂/Si interface

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