2019
DOI: 10.1002/advs.201900304
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Fast Acoustic Light Sculpting for On‐Demand Maskless Lithography

Abstract: Light interference is the primary enabler of a number of optical maskless techniques for the large‐scale processing of materials at the nanoscale. However, methods controlling interference phenomena can be limited in speed, ease of implementation, or the selection of pattern designs. Here, an optofluidic system that employs acoustic standing waves in a liquid to produce complex interference patterns at sub‐microsecond temporal resolution, faster than the pulse‐to‐pulse period of many commercial laser systems, … Show more

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Cited by 16 publications
(13 citation statements)
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“…In this case, there is an inherent transition time until the acoustic standing wave reaches a new steady‐state. For water, it has been measured to be about 600 ms, which corresponds to a frequency of ≈1.7 kHz . While lower than before, this speed it is still significantly higher than most state‐of‐the‐art active multifocus generators.…”
Section: Temporal Characteristics and Tunabilitymentioning
confidence: 79%
“…In this case, there is an inherent transition time until the acoustic standing wave reaches a new steady‐state. For water, it has been measured to be about 600 ms, which corresponds to a frequency of ≈1.7 kHz . While lower than before, this speed it is still significantly higher than most state‐of‐the‐art active multifocus generators.…”
Section: Temporal Characteristics and Tunabilitymentioning
confidence: 79%
“…The application of sinusoidal signals to the piezoelectric pair generates vibrations in the liquid. Propagation of these acoustic waves along the X-and Y-axes can be described by solving the damped acoustic wave equation with appropriate boundary conditions [33], [34]. On resonance, standing acoustic and, hence, density waves are present in the cavity at resonant frequencies given by the following equation:…”
Section: Acoustic Cavity: Design Implementation and Characterisationmentioning
confidence: 99%
“…To shed light on this point, we must first determine how the stationary acoustic waves alter the refractive index of the liquid. On resonance, the induced vibrations cause a periodic modulation of the density of the liquid, which, according to the Lorentz-Lorenz model, translates into a periodic refractive index that can be calculated with [33]:…”
Section: Laser Diffraction Through the Acoustic Cavitymentioning
confidence: 99%
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