Marangoni spreading on liquid substrates in new media art
With the advent of new media art, artists have harnessed fluid dynamics to create captivating visual narratives. A striking technique known as dendritic painting employs mixtures of ink and isopropanol atop paint, yielding intricate tree-like patterns. To unravel the intricacies of that technique, w...
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Zusammenfassung: | With the advent of new media art, artists have harnessed fluid dynamics to
create captivating visual narratives. A striking technique known as dendritic
painting employs mixtures of ink and isopropanol atop paint, yielding intricate
tree-like patterns. To unravel the intricacies of that technique, we examine
the spread of ink/alcohol droplets over liquid substrates with diverse
rheological properties. On Newtonian substrates, the droplet size evolution
exhibits two power laws, suggesting an underlying interplay between viscous and
Marangoni forces. The leading edge of the droplet spreads as a precursor film
with an exponent of 3/8, while its main body spreads with an exponent of 1/4.
For a weakly shear-thinning acrylic resin substrate, the same power laws
persist, but dendritic structures emerge, and the texture of the precursor film
roughens. The observed roughness and growth exponents (3/4 and 3/5) suggest a
connection to the quenched Kardar--Parisi--Zhang universality class, hinting at
the existence of quenched disorder in the liquid substrate. Mixing the resin
with acrylic paint renders it more viscous and shear-thinning, refining the
dendrite edges and further roughening the precursor film. At larger paint
concentrations, the substrate becomes a power-law fluid. The roughness and
growth exponents then approach 1/2 and 3/4, respectively, deviating from known
universality classes. The ensuing structures have a fractal dimension of 1.68,
characteristic of diffusion-limited aggregation. These findings underscore how
the non-linear rheological properties of the liquid substrate, coupled with the
Laplacian nature of Marangoni spreading, can overshadow the local kinetic
roughening of the droplet interface. |
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DOI: | 10.48550/arxiv.2312.05518 |