![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_0008.jpeg)
Calculation of the Meniscus Shape Formed under Gravitational Force by Solving the Young–Laplace Differential Equation Using the Bézier Curve Method | ACS Omega
Why are solutions measured at the bottom of the meniscus? Isn't there still liquid above it, or are the measuring tools made to take that into account? - Quora
![Capillary actions of the air-water surface. (a) Capillary-rise of water... | Download Scientific Diagram Capillary actions of the air-water surface. (a) Capillary-rise of water... | Download Scientific Diagram](https://www.researchgate.net/publication/330819489/figure/fig2/AS:721722235973635@1549083398364/Capillary-actions-of-the-air-water-surface-a-Capillary-rise-of-water-inside-a-vertical.png)
Capillary actions of the air-water surface. (a) Capillary-rise of water... | Download Scientific Diagram
![Cross section of a meniscus in a cylindrical tube with θ = 10° and a... | Download Scientific Diagram Cross section of a meniscus in a cylindrical tube with θ = 10° and a... | Download Scientific Diagram](https://www.researchgate.net/publication/7869134/figure/fig3/AS:667202936111120@1536084984260/Cross-section-of-a-meniscus-in-a-cylindrical-tube-with-th-10-and-a-normalized-volume-of.png)
Cross section of a meniscus in a cylindrical tube with θ = 10° and a... | Download Scientific Diagram
![A cylindrical capillary tube of 0.2 mm radius is made by joining two capillaries T1 and T2 of different materials having water contact angles of 0^o and 60^o respectively. The capillary tube A cylindrical capillary tube of 0.2 mm radius is made by joining two capillaries T1 and T2 of different materials having water contact angles of 0^o and 60^o respectively. The capillary tube](https://haygot.s3.amazonaws.com/questions/1633323_c90274c36f0e456a8fa9f3f0aa155215.png)
A cylindrical capillary tube of 0.2 mm radius is made by joining two capillaries T1 and T2 of different materials having water contact angles of 0^o and 60^o respectively. The capillary tube
![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
![Meniscus height h vs time t for tube diameters d ϭ 4, 9, and 11 mm,... | Download Scientific Diagram Meniscus height h vs time t for tube diameters d ϭ 4, 9, and 11 mm,... | Download Scientific Diagram](https://www.researchgate.net/profile/Michael-Dreyer/publication/228856484/figure/fig3/AS:300864389566465@1448743068290/Meniscus-height-h-vs-time-t-for-tube-diameters-d-4-9-and-11-mm-initial-liquid_Q640.jpg)
Meniscus height h vs time t for tube diameters d ϭ 4, 9, and 11 mm,... | Download Scientific Diagram
![Capillary surfaces in and around exotic cylinders with application to stability analysis | Journal of Fluid Mechanics | Cambridge Core Capillary surfaces in and around exotic cylinders with application to stability analysis | Journal of Fluid Mechanics | Cambridge Core](https://static.cambridge.org/content/id/urn%3Acambridge.org%3Aid%3Aarticle%3AS0022112019008243/resource/name/S0022112019008243_figAb.gif?pub-status=live)
Capillary surfaces in and around exotic cylinders with application to stability analysis | Journal of Fluid Mechanics | Cambridge Core
![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-g006.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
![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_0009.jpeg)