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Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega
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Computation | Free Full-Text | Contact Angle Effects on Pore and Corner Arc Menisci in Polygonal Capillary Tubes Studied with the Pseudopotential Multiphase Lattice Boltzmann Model
![Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega](https://pubs.acs.org/cms/10.1021/acsomega.2c04359/asset/images/large/ao2c04359_0007.jpeg)
Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega
![Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega](https://pubs.acs.org/cms/10.1021/acsomega.2c04359/asset/images/large/ao2c04359_0002.jpeg)
Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega
![The effect of isolated ridges and grooves on static menisci in rectangular channels | Journal of Fluid Mechanics | Cambridge Core The effect of isolated ridges and grooves on static menisci in rectangular channels | Journal of Fluid Mechanics | Cambridge Core](https://static.cambridge.org/content/id/urn%3Acambridge.org%3Aid%3Aarticle%3AS002211202200026X/resource/name/S002211202200026X_figAb.png?pub-status=live)
The effect of isolated ridges and grooves on static menisci in rectangular channels | Journal of Fluid Mechanics | Cambridge Core
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Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega
![Computation | Free Full-Text | Contact Angle Effects on Pore and Corner Arc Menisci in Polygonal Capillary Tubes Studied with the Pseudopotential Multiphase Lattice Boltzmann Model Computation | Free Full-Text | Contact Angle Effects on Pore and Corner Arc Menisci in Polygonal Capillary Tubes Studied with the Pseudopotential Multiphase Lattice Boltzmann Model](https://www.mdpi.com/computation/computation-04-00012/article_deploy/html/images/computation-04-00012-g001.png)
Computation | Free Full-Text | Contact Angle Effects on Pore and Corner Arc Menisci in Polygonal Capillary Tubes Studied with the Pseudopotential Multiphase Lattice Boltzmann Model
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Capillary surfaces in and around exotic cylinders with application to stability analysis | Journal of Fluid Mechanics | Cambridge Core
![Meniscus depth vs. the capillary size for various contact angles for... | Download Scientific Diagram Meniscus depth vs. the capillary size for various contact angles for... | Download Scientific Diagram](https://www.researchgate.net/publication/330595152/figure/fig9/AS:959302391037960@1605726921860/Meniscus-depth-vs-the-capillary-size-for-various-contact-angles-for-the-liquid-water.png)
Meniscus depth vs. the capillary size for various contact angles for... | Download Scientific Diagram
![A cylindrical capillary tube of 0.2 mm radius is made by joining two capillaries T 1 and T 2 of different materials having water contact angles of 0∘ and 60∘ respectively. The A cylindrical capillary tube of 0.2 mm radius is made by joining two capillaries T 1 and T 2 of different materials having water contact angles of 0∘ and 60∘ respectively. The](https://s3-us-west-2.amazonaws.com/infinitestudent-images/ckeditor_assets/pictures/529192/original_6-1.jpg)