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Related Concept Videos

Solubility03:00

Solubility

Solution, Solubility, and Solubility Equilibrium
A solution is a homogeneous mixture composed of a solvent, the major component, and a solute, the minor component. The physical state of a solution—solid, liquid, or gas—is typically the same as that of the solvent. Solute concentrations are often described with qualitative terms such as dilute (of relatively low concentration) and concentrated (of relatively high concentration).
In a solution, the solute particles (molecules, atoms, and/or ions)...
Hydrolysis01:15

Hydrolysis

Overview
Hydrolysis is a chemical reaction in which the addition of water breaks down a polymer into its simpler monomer units. For example, peptides break into amino acids, carbohydrates into simple sugars, and DNA into nucleotides. Enzymes often facilitate these processes.
Hydrolysis Reverses Dehydration Synthesis
Complex carbohydrates can be broken down by breaking the bonds between individual sugar units. The reaction breaks a glycosidic bond as water is added to the compound. The...
Entropy and Solvation02:05

Entropy and Solvation

The process of surrounding a solute with solvent is called solvation. It involves evenly distributing the solute within the solvent. The rule of thumb for determining a solvent for a given compound is that like dissolves like. A good solvent has molecular characteristics similar to those of the compound to be dissolved. For example, polar solutions dissolve polar solutes, and apolar solvents dissolve apolar solutes. A polar solvent is a solvent that has a high dielectric constant (ϵ ≥ 15); an...
Cohesion01:07

Cohesion

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 surface,...
Surface Tension, Capillary Action, and Viscosity02:57

Surface Tension, Capillary Action, and Viscosity

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...
Surface Active Agents01:27

Surface Active Agents

Surfactants, named for their behavior at interfaces, positively adsorb at the interfaces of two phases, reducing interfacial tension. Their versatility as emulsifiers, detergents, and foaming agents stems from this ability. Surfactants, often termed amphiphiles, share the property of amphipathy, with molecules having both hydrophilic and hydrophobic portions. The hydrophilic part is called the head, and the hydrophobic part, including an elongated alkyl substituent, forms the tail.Surfactants...

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Related Experiment Video

Updated: May 14, 2026

Fabrication of Superhydrophobic Metal Surfaces for Anti-Icing Applications
11:20

Fabrication of Superhydrophobic Metal Surfaces for Anti-Icing Applications

Published on: August 15, 2018

How superhydrophobicity breaks down.

Periklis Papadopoulos1, Lena Mammen, Xu Deng

  • 1Physics at Interfaces, Max Planck Institute for Polymer Research, D-55128 Mainz, Germany.

Proceedings of the National Academy of Sciences of the United States of America
|February 6, 2013
PubMed
Summary
This summary is machine-generated.

Superhydrophobic surfaces repel water due to trapped air. This study visualizes how water drops penetrate these surfaces, revealing key dynamics for designing better water-repellent materials.

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Rendering SiO2/Si Surfaces Omniphobic by Carving Gas-Entrapping Microtextures Comprising Reentrant and Doubly Reentrant Cavities or Pillars
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Rendering SiO2/Si Surfaces Omniphobic by Carving Gas-Entrapping Microtextures Comprising Reentrant and Doubly Reentrant Cavities or Pillars

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Measuring the Interaction Force Between a Droplet and a Super-hydrophobic Substrate by the Optical Lever Method
07:18

Measuring the Interaction Force Between a Droplet and a Super-hydrophobic Substrate by the Optical Lever Method

Published on: June 14, 2019

Related Experiment Videos

Last Updated: May 14, 2026

Fabrication of Superhydrophobic Metal Surfaces for Anti-Icing Applications
11:20

Fabrication of Superhydrophobic Metal Surfaces for Anti-Icing Applications

Published on: August 15, 2018

Rendering SiO2/Si Surfaces Omniphobic by Carving Gas-Entrapping Microtextures Comprising Reentrant and Doubly Reentrant Cavities or Pillars
08:02

Rendering SiO2/Si Surfaces Omniphobic by Carving Gas-Entrapping Microtextures Comprising Reentrant and Doubly Reentrant Cavities or Pillars

Published on: February 11, 2020

Measuring the Interaction Force Between a Droplet and a Super-hydrophobic Substrate by the Optical Lever Method
07:18

Measuring the Interaction Force Between a Droplet and a Super-hydrophobic Substrate by the Optical Lever Method

Published on: June 14, 2019

Area of Science:

  • Surface science
  • Fluid dynamics
  • Materials science

Background:

  • Superhydrophobic surfaces exhibit self-cleaning properties by minimizing contact with liquids.
  • The Cassie state, characterized by an air cushion, is crucial for superhydrophobicity and competes with the Wenzel state (complete wetting).
  • Preventing liquid impalement into surface structures is vital for maintaining superhydrophobicity.

Purpose of the Study:

  • To visualize and understand the three-dimensional dynamics of liquid impalement on superhydrophobic surfaces.
  • To investigate the transition from the Cassie state to the Wenzel state during drop evaporation.
  • To provide insights for the development and characterization of advanced superhydrophobic materials.

Main Methods:

  • Three-dimensional imaging of droplet dynamics using confocal microscopy.
  • Observation of droplet evaporation from a pillar array surface.
  • Analysis of liquid-air interface behavior and depinning phenomena.

Main Results:

  • Droplet rims recede via stepwise depinning from pillar edges during evaporation.
  • Finger-like necks form due to adhesion before impalement occurs.
  • Complete wetting initiates rapidly once the water-air interface contacts the substrate.

Conclusions:

  • Visualizing impalement dynamics offers critical understanding for superhydrophobic surface design.
  • The study elucidates the mechanisms leading to the loss of superhydrophobicity.
  • Findings will aid in engineering more robust and effective superhydrophobic surfaces.