CO2 laser micromachining of nanocrystalline diamond films grown on doped silicon substrates

Jens Richter; Aly Abdou; Oliver A. Williams; Jeremy Witzens; Maziar P. Nezhad

doi:10.1364/OME.6.003916

CO2 laser micromachining of nanocrystalline diamond films grown on doped silicon substrates

Jens Richter, Aly Abdou, Oliver A. Williams, Jeremy Witzens, Maziar P. Nezhad

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Abstract

We demonstrate that nanocrystalline diamond films grown on highly doped silicon substrates can be patterned using a CO2 laser operating at a wavelength of 10.6 μm, where both low doped silicon and diamond exhibit negligible optical absorption. The patterning is initiated by free carrier absorption in the silicon substrate and further enhanced by the thermal runaway effect, which results in surface heating in the silicon substrate and subsequent thermal ablation of the diamond film in an oxygen rich atmosphere. Using this approach, micron-scale grating and dot patterns are patterned in thin film diamond. The localized heating is simulated and analyzed using concurrent optical and thermal finite element modelling. The laser patterning method described here offers a cost effective and rapid solution for micro-structuring diamond films.

Original language	English
Pages (from-to)	3916-3926
Journal	Optical Materials Express
Volume	6
Issue number	12
DOIs	https://doi.org/10.1364/OME.6.003916
Publication status	Published - 23 Nov 2016

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title = "CO2 laser micromachining of nanocrystalline diamond films grown on doped silicon substrates",

abstract = "We demonstrate that nanocrystalline diamond films grown on highly doped silicon substrates can be patterned using a CO2 laser operating at a wavelength of 10.6 μm, where both low doped silicon and diamond exhibit negligible optical absorption. The patterning is initiated by free carrier absorption in the silicon substrate and further enhanced by the thermal runaway effect, which results in surface heating in the silicon substrate and subsequent thermal ablation of the diamond film in an oxygen rich atmosphere. Using this approach, micron-scale grating and dot patterns are patterned in thin film diamond. The localized heating is simulated and analyzed using concurrent optical and thermal finite element modelling. The laser patterning method described here offers a cost effective and rapid solution for micro-structuring diamond films.",

author = "Jens Richter and Aly Abdou and Williams, \{Oliver A.\} and Jeremy Witzens and Nezhad, \{Maziar P.\}",

year = "2016",

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doi = "10.1364/OME.6.003916",

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T1 - CO2 laser micromachining of nanocrystalline diamond films grown on doped silicon substrates

AU - Richter, Jens

AU - Abdou, Aly

AU - Williams, Oliver A.

AU - Witzens, Jeremy

AU - Nezhad, Maziar P.

PY - 2016/11/23

Y1 - 2016/11/23

N2 - We demonstrate that nanocrystalline diamond films grown on highly doped silicon substrates can be patterned using a CO2 laser operating at a wavelength of 10.6 μm, where both low doped silicon and diamond exhibit negligible optical absorption. The patterning is initiated by free carrier absorption in the silicon substrate and further enhanced by the thermal runaway effect, which results in surface heating in the silicon substrate and subsequent thermal ablation of the diamond film in an oxygen rich atmosphere. Using this approach, micron-scale grating and dot patterns are patterned in thin film diamond. The localized heating is simulated and analyzed using concurrent optical and thermal finite element modelling. The laser patterning method described here offers a cost effective and rapid solution for micro-structuring diamond films.

AB - We demonstrate that nanocrystalline diamond films grown on highly doped silicon substrates can be patterned using a CO2 laser operating at a wavelength of 10.6 μm, where both low doped silicon and diamond exhibit negligible optical absorption. The patterning is initiated by free carrier absorption in the silicon substrate and further enhanced by the thermal runaway effect, which results in surface heating in the silicon substrate and subsequent thermal ablation of the diamond film in an oxygen rich atmosphere. Using this approach, micron-scale grating and dot patterns are patterned in thin film diamond. The localized heating is simulated and analyzed using concurrent optical and thermal finite element modelling. The laser patterning method described here offers a cost effective and rapid solution for micro-structuring diamond films.

U2 - 10.1364/OME.6.003916

DO - 10.1364/OME.6.003916

M3 - Article

SN - 2159-3930

VL - 6

SP - 3916

EP - 3926

JO - Optical Materials Express

JF - Optical Materials Express

IS - 12

ER -

CO2 laser micromachining of nanocrystalline diamond films grown on doped silicon substrates

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