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Surface Tension of Fluid01:22

Surface Tension of Fluid

484
Surface tension is a fundamental property of fluids, occurring at the boundary between a liquid and a gas or between two immiscible liquids. This phenomenon arises from the cohesive forces between molecules at the fluid's surface, creating an effect similar to a stretched elastic membrane. Inside each fluid, molecules are equally attracted in all directions by neighboring molecules, but surface molecules experience a net inward force, resulting in surface tension.
Surface tension varies...
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Cohesion01:07

Cohesion

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Cohesion is the attraction between molecules of the same type, such as water molecules. Water molecules have an overall neutral charge but are polar molecule. An oxygen atom in one water molecule has a partial negative charge that can bind to a hydrogen atom with a partial positive charge in a second water molecule, forming a hydrogen bond. Each water molecule can form up to four hydrogen bonds with other water molecules. Hydrogen bonds are responsible for water's cohesive nature.
On a...
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Surface Tension, Capillary Action, and Viscosity02:57

Surface Tension, Capillary Action, and Viscosity

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Surface Tension
The various IMFs between identical molecules of a substance are examples of cohesive forces. The molecules within a liquid are surrounded by other molecules and are attracted equally in all directions by the cohesive forces within the liquid. However, the molecules on the surface of a liquid are attracted only by about one-half as many molecules. Because of the unbalanced molecular attractions on the surface molecules, liquids contract to form a shape that minimizes the number...
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Adhesion01:14

Adhesion

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Adhesion occurs when one type of molecule is attracted to a different molecule. Water exhibits adhesive properties in the presence of polar surfaces, such as glass or cellulose in plants. For instance, when water is poured into a glass, the positively charged hydrogen molecules of water are more attracted to the negatively charged oxygen molecules in the silica than to the oxygen in neighboring water molecules.
Capillary action is a result of water’s adhesive tendencies. When a narrow...
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Capillarity in Fluid01:19

Capillarity in Fluid

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Capillarity describes the movement of liquid in small spaces without external forces acting on it. The capillarity is driven by surface tension and adhesive interactions between the liquid and surrounding solid surfaces. This effect is often seen in narrow tubes, porous materials, and fine particles.
Surface tension is crucial to capillarity. It results from cohesive forces between liquid molecules at the liquid-air boundary, forming a skin that resists external forces. When the capillary tube...
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Rise of Liquid in a Capillary Tube01:18

Rise of Liquid in a Capillary Tube

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When very thin cylindrical tubes, called capillaries, are dipped in a liquid, the liquid rises or falls in the tube compared to the surrounding liquid. This phenomenon is called capillary action. Capillary action occurs due to the combination of two opposing forces: the cohesive forces of the liquid, which cause it to stick to itself and form a rounded shape, and the adhesive forces between the liquid and the walls of the container, which cause the liquid to be attracted to the container walls.
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Updated: Sep 10, 2025

Aqueous Droplets Used as Enzymatic Microreactors and Their Electromagnetic Actuation
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Aqueous Droplets Used as Enzymatic Microreactors and Their Electromagnetic Actuation

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Proyección de propiedades de humedad con gotas autopropulsadas

Bernardo Boatini1, Cristina Gavazzoni1, Leonardo Gregory Brunnet1

  • 1Instituto de Física, Universidade Federal do Rio Grande do Sul, Caixa Postal 15051, CEP 91501-970, Porto Alegre, Rio Grande do Sul, Brazil. b.boattini@gmail.com.

Soft matter
|August 26, 2025
PubMed
Resumen
Este resumen es generado por máquina.

La física de la materia activa ofrece un nuevo método para estudiar la metastabilidad de las gotas en las superficies. El aumento de la actividad de las gotas ayuda a superar las barreras energéticas, lo que permite la exploración y la supresión de los estados de humedad metastables.

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Área de la Ciencia:

  • La física
  • Ciencias de los materiales
  • Ciencias de la superficie

Sus antecedentes:

  • Los fenómenos de humedad son críticos para las tecnologías que utilizan superficies hidrofóbicas o hidrofílicas.
  • Los sustratos pueden exhibir múltiples estados de humedad (metastabilidad) debido a las condiciones de la superficie o al historial de gotas.
  • El control de los estados metestables es vital para las aplicaciones, sin embargo, los métodos de estudio actuales son complejos o costosos.

Objetivo del estudio:

  • Introducir un enfoque alternativo para el estudio de la metestabilidad de las gotas utilizando conceptos de física de la materia activa.
  • Investigar el comportamiento de las gotas en una superficie con un nuevo modelo computacional.
  • Demostrar cómo la actividad de las gotas influye en la exploración y supresión de los estados de humedad metastables.

Principales métodos:

  • Se empleó un modelo de Potts celular de 3 estados, incorporando un término de polaridad para simular una gota autopropulsada.
  • El modelo se aplicó a un sustrato pilar conocido por exhibir estados de humedad metastables.
  • Se utilizaron mediciones del ángulo de contacto para cuantificar la metestabilidad.

Principales resultados:

  • El aumento de la actividad de las gotas le permitió superar las barreras de energía libre entre los estados metestables.
  • La actividad facilitó la exploración de estados de humedad metastables consecutivos.
  • La metestabilidad fue suprimida por completo con suficiente actividad.
  • La actividad redujo la diferencia entre los estados seco y húmedo.

Conclusiones:

  • La física de la materia activa proporciona un nuevo marco computacionalmente eficiente para estudiar la metestabilidad de las gotas.
  • La actividad de las gotas es un factor clave para controlar el comportamiento de la humedad en superficies complejas.
  • Este enfoque ofrece un método fiable para identificar y cuantificar la metestabilidad a través de mediciones de ángulo de contacto.