Premium
Inhibition and Enhancement of Quantized, Interference‐Driven, Ultrafast‐Laser Cleaving, and Intrafilm Ejection with Angle and Polarization Control
Author(s) -
Roper David M.,
Ho Stephen,
Haque Moez,
Jha Prasoon,
Herman Peter R.
Publication year - 2018
Publication title -
advanced materials technologies
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.184
H-Index - 42
ISSN - 2365-709X
DOI - 10.1002/admt.201700234
Subject(s) - materials science , thin film , microelectronics , optoelectronics , microscale chemistry , optics , microelectromechanical systems , ultrashort pulse , refractive index , polarization (electrochemistry) , laser , nanoscopic scale , interference (communication) , silicon , nanotechnology , computer science , physics , chemistry , mathematics education , mathematics , computer network , channel (broadcasting)
Abstract The combination of optical interference and ultrafast laser interaction within microscale transparent films offers novel high resolution means for nonlinear confinement of dissipated energy to facilitate 3D nanostructuring. This approach relies on the formation of nanoscale (≈40 nm) plasma disks stacked on half‐wavelength spacings, λ/2 n film (film refractive index, n film ), opening directions for intrafilm cleaving and nanostructuring of free‐standing blisters or embedded nanocavities with controllable surface topography. Given a limited number of film‐substrate systems suitable for generating high contrast interference fringes, this paper introduces angle and polarization control to manipulate fringe visibility in SiO x thin‐films (1 µm thickness) with silicon substrates. An enhancement or diminishment of quantized intrafilm processing is definitively demonstrated according to s‐ and p‐polarization states, respectively. Modeling of Gaussian beam walk‐off effects further explores film interference in tight focusing limits, predicting new asymmetry that manipulates intrafilm cleaving morphology. This research opens a path to quantized structuring of previously unsuitable low‐contrast thin‐film systems, while improving the design and control over novel surface and intrafilm morphologies. The development of intrafilm structuring in SiO x thin‐films is relevant to lab‐in‐film opportunities for assessing cell or subcellular species in CMOS‐compatible microelectronics and improving functionality of LED, lab‐on‐a‐chip and MEMS devices.