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Versalaser Cutting/Engraving Tool

CAC Name: Versalaser Engraver/Cutter Tool-Rm 224

CO2 laser cutter/engraver

CNF Versalaser
Manager: Beth Rhoades
Backup: Christopher Alpha
Equipment Training
Training takes 1 hour and is hands on. Bring your substrate with you. Please contact the tool manager to schedule training.

Description:

The Universal Laser Systems VersaLaser VLS3.50 is a CO2 laser that emits in the infrared spectrum to cut or etch patterns by vaporizing the substrate. The tool is equipped with optics that focus to spot sizes of 25.4 or 127 microns. The tool accommodates substrates up to 24 x 16 inches and several inches thick.

The laser is controlled by Corel Draw or AutoCAD plotting software. Designs are translated into varying depths, widths, and edge qualities. Cuts with microscale widths as small as 35-120 microns (depending on the substrate)can be achieved.

Capabilities:

Substrates that can be CUT through include: heat-resistant glass, plastics and other polymers, mylar, nylon, papers, rubber, PDMS (silicone).

These materials as well as many metals can be ENGRAVED (see attached list). Unfortunately, silicon wafers and some materials such as gold and brass are generally impervious to the laser's wavelength.

Processes Available:

Processes are in active development! Users have reported success with the following:

--through holes & channels in glass & quartz wafers for anodic bonding or other uses
--microtoroid fabrication in thin layers of silicon oxide
--micromachining plexiglass & PMMA for molds or parts
--rapid prototyping of polyimide or kapton tape devices
--precision-cut rubilith masks
--cutting gaskets & seals in rubber or double-sided tapes
--direct cutting or etching of PDMS
--marking metals & silicon wafers with metal marking compounds
--creating simple paper-based microfluidic devices & stencils
--microfluidic channels in polymers (Zeonor, PMMA, PDMS, acrylic)


We anticipate that a very useful process is the fabrication of proto-types or non-traditional material-based microfluidic device. Users could design patterns, cut the layers in adhesive backed plastics and stack up to assemble 3-D microfluidic devices in a fraction of the time and cost that it would take for traditional PDMS-based microfluidic fabrication. We are currently working on developing microfluidic devices, patterning medical-grade tapes and cutting heat-resistant glass. Contact the tool managers to suggest other processes.


Additional Resources:

Equipment Information Sheet

Results:


An optical resonator made from a silica microtoroid with extremely smooth side walls that enable very narrow optical resonances. The microtoroid was fabricated by defining a 100 micron-dia. silica disk on the top of a silicon wafer, undercutting the rim with a xenon difluoride isotropic etch, and partially melting the overhanging rim with the Versalaser. The infrared light was absorbed by the silica, but passed through the silicon, melting the edges without affecting the underlying substrate. (Fabricated by David Hutchison, Applied Physics, PhD candidate, 2011).

Array of through holes (100-5000 microns dia.) in a 500 micron-thick fused silica wafer. Holes were cut with minimal damage to the edges by repeated, low-intensity passes of the laser. Typical settings allow a 1000 micron-dia. hole to be cut in under 20 seconds. Subsequent CMP processing can prepare the cut wafer for anodic bonding.


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