Next-generation printing: Precise and direct, using optical vortices
Innovative technique enables cost- and time-saving microprinting technologies
- Date:
- October 2, 2023
- Source:
- Osaka Metropolitan University
- Summary:
- Researchers have succeeded in printing uniformly sized droplets with a diameter of approximately 100 µm using a liquid film of fluorescent ink. This ink, with a viscosity roughly 100 times that of water, was irradiated with an optical vortex, resulting in prints of exceptional positional accuracy at the micrometer scale.
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Will printed photographs ever match the precision of a mirror's reflection? Even though the answer may still be no for a while, Osaka Metropolitan University scientists have made significant strides in precision printing with their innovative optical vortex laser-based technique that allows for the precise placement of minuscule droplets with micrometer-scale accuracy.
Inkjet technology is a well-known printing technique that emits microdroplets from a nozzle directly onto a surface. However, when the ink droplets are viscous, with high density, the nozzle often gets clogged, a concern that has prompted the search for more advanced technologies.
A research team led by Dr. Ken-ichi Yuyama, a lecturer at the Graduate School of Science of Osaka Metropolitan University, has succeeded in printing uniformly sized droplets, with a diameter of approximately 100 µm, using a liquid film of fluorescent ink -- which is approximately 100 times more viscous than water. This was achieved by irradiating the film with an optical vortex, resulting in prints of exceptional positional accuracy at the micrometer scale.
"Using a special laser beam known as an optical vortex, we have achieved stable printing of high-viscosity liquids," explained Dr. Yuyama. "This printing technique allows for the fabrication of microdroplet laser arrays and the micropatterning of conductive nanoinks, as well as bioinks for cell scaffolds, leading to the establishment of next-generation printed photonic or electronic devices."
Story Source:
Materials provided by Osaka Metropolitan University. Note: Content may be edited for style and length.
Journal Reference:
- Ken-ichi Yuyama, Haruki Kawaguchi, Rong Wei, Takashige Omatsu. Fabrication of an Array of Hemispherical Microlasers Using Optical Vortex Laser-Induced Forward Transfer. ACS Photonics, 2023; DOI: 10.1021/acsphotonics.3c01005
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