180 research outputs found
On the anisotropy of stress-distribution induced in glasses and crystals by non-ablative femtosecond laser exposure
Femtosecond laser exposure in the non-ablative regime induces a variety of
bulk structural modifications, in which anisotropy may depend on the
polarization of the writing beam. In this work, we investigate the correlation
between polarization state and stress anisotropy. In particular, we introduce a
methodology that allows for rapid analysis and visualization of laser-induced
stress anisotropy in glasses and crystals. Using radial and azimuthal
polarization, we also demonstrate stress states that are nearly isotropic.Comment: 15 pages, 9 Figure
Femtosecond laser direct-write waveplates based on stress-induced birefringence
The use of femtosecond lasers to introduce controlled stress states has
recently been demonstrated in silica glass. We use this technique, in
combination with chemical etching, to generate and control stress-induced
birefringence over a well-defined region of interest, demonstrating
direct-write wave plates with precisely tailored retardance levels. This
tailoring enables the fabrication of laser-written polarization optics that can
be tuned to any wavelength for which silica is transparent and with a clear
aperture free of any laser modifications. Using this approach, we achieve
sufficient retardance to act as a quarter-wave plate. The stress distribution
within the clear aperture is analyzed and modeled, providing a generic template
that can be used as a set of design rules for laser-machined polarization
devices.Comment: 14 pages, 8 figures Revised version, with updated title and abstract
to reflect use of stress-induced birefringence. Sections 4.1 and 4.3 also
updated (1D and 2D model) with more accurate descriptions of stressor region
and to correct an implementation error in the 2D mode
Formation of in-volume nanogratings with sub-100 nm periods in glass by femtosecond laser irradiation
We present direct experimental observation of the morphological evolution
during the formation of nanogratings with sub-100-nm periods with the
increasing number of pulses. Theoretical simulation shows that the constructive
interference of the scattering light from original nanoplanes will create an
intensity maximum located between the two adjacent nanoplanes, resulting in
shortening of the nanograting period by half. The proposed mechanism enables
explaining the formation of nanogratings with periods beyond that predicted by
the nanoplasmonic model.Comment: 4 pages, 3 figure
Molding topologically-complex 3D polymer microstructures from femtosecond laser machined glass
The fabrication of complex, three-dimensional microscale shapes that can be replicated over large surfaces is an ongoing challenge, albeit one with a wide range of possible applications such as engineered surfaces with tuned wetting properties, scaffolds for cell studies, or surfaces with tailored optical properties. In this work, we use a two-step femtosecond laser direct-write technique and wet-etching process to fabricate monolithic glass micromolds with complex three-dimensional surface topologies, and demonstrate the replication of these structures in a soft polymer (polydimethylsiloxane, PDMS). To estimate the forces experienced during the demolding for one representative structure, we use a combination of two models – a simple linear elastic model and a numerical hyperelastic model. These models are used to support the high experimental success rates of the demolding process observed, despite the high strain induced in the material during demolding. Since the process used is scalable, this work opens new avenues for low-cost fabrication of surfaces having complex microscale patterns with three-dimensional geometries
A Monolithic Micro-Tensile Tester for Investigating Silicon Dioxide Polymorph Micromechanics, Fabricated and Operated Using a Femtosecond Laser
Mechanical testing of materials at the microscales is challenging. It requires delicate procedures not only for producing and handling the specimen to be tested, but also for applying an accurate and controlled force. This endeavor is even more challenging when it comes to investigating the behavior of brittle materials such as glass. Here, we present a microtensile tester for investigating silica glass polymorphs. The instrument is entirely made of silica and for which the same femtosecond laser is not only used for fabricating the device, but also for operating it (loading the specimen) as well as for performing in situ measurements. As a proof-of-concept, we present a stress-strain curve of fused silica for unprecedented high tensile stress of 2.4 GPa, as well as preliminary results of the elastic modulus of femtosecond laser-affected zones of fused silica, providing new insights on their microstructures and mechanical behavior
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