Relationship between Excess Pressure and Surface Tension for a Drop on a Fibre

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SUMMARY

The discussion focuses on the relationship between excess pressure and surface tension for a drop on a fiber, specifically using the Young-Laplace equation, which states that $$\Delta{P} = \sigma{(\frac{1}{R_1}+\frac{1}{R_2})}$$. Participants clarify that two radii of curvature, ##R_1## and ##R_2##, are required, lying in planes at right angles to each other and to the tangent plane of the surface. The curvature of radius is defined as $$R=\frac{y''}{(1+y'^2)^\frac 3 2 }$$, but the second radius requires consideration of an angle θ to determine the correct plane for calculation.

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  • Understanding of the Young-Laplace equation
  • Knowledge of curvature and its mathematical representation
  • Familiarity with the concept of radii of curvature in different planes
  • Basic principles of fluid mechanics
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  • Study the derivation and applications of the Young-Laplace equation
  • Learn about calculating curvature in multiple dimensions
  • Explore the implications of surface tension in fluid dynamics
  • Investigate the effects of fiber radius on droplet behavior
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Students and researchers in fluid mechanics, physicists studying surface phenomena, and engineers working with materials involving liquid droplets on fibers.

Raihan amin
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Homework Statement


Think of a drop of radius ##R## deposited on a fibre of radius ##b(b<<L)##.Find ##{\Delta{P}}##

Homework Equations


The relationship between excess pressure and the surface tension is given by Yong-Laplace equation,
$$\Delta{P} = \sigma{(\frac{1}{R_1}+\frac{1}{R_2})}$$

The Attempt at a Solution

[/B]
Here i can't figure out what will be ##R_1##and##R_2## .I know that the curvature of radius is defined as $$R=\frac{y''}{(1+y'^2)^\frac 3 2 }$$ if ##y'##is the derivative of y with respect to ##x##.But in the solution, they have used two different formula for ##R_1## and ##R_2##.
Can anyone help me understand these?
 

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Raihan amin said:

Homework Statement


Think of a drop of radius ##R## deposited on a fibre of radius ##b(b<<L)##.Find ##{\Delta{P}}##

Homework Equations


The relationship between excess pressure and the surface tension is given by Yong-Laplace equation,
$$\Delta{P} = \sigma{(\frac{1}{R_1}+\frac{1}{R_2})}$$

The Attempt at a Solution

[/B]
Here i can't figure out what will be ##R_1##and##R_2## .I know that the curvature of radius is defined as $$R=\frac{y''}{(1+y'^2)^\frac 3 2 }$$ if ##y'##is the derivative of y with respect to ##x##.But in the solution, they have used two different formula for ##R_1## and ##R_2##.
Can anyone help me understand these?
You need two radii of curvature lying in planes at right angles to each other and at right angles to the tangent plane of the surface.
The formula you quote is correct for the XY plane. The other plane is a bit tricky. A vertical slice gives a radius of y, but that plane is not at right angles to the tangent plane. To get the correct plane you have to tip it over at angle θ, as shown. The centre of curvature is still on the x-axis (is this obvious?) so the radius is y sec(θ).
 
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haruspex said:
The centre of curvature is still on the x-axis (is this obvious?) so the radius is y sec(θ).
Can you elaborate it,please ?
 
Raihan amin said:
Can you elaborate it,please ?
Are you asking for proof that the centre of curvature is still on the x axis? If not, what?
 
haruspex said:
Are you asking for proof that the centre of curvature is still on the x axis? If not, what?
Yes,i am asking for that
 
Raihan amin said:
Yes,i am asking for that
I can't think of a simple argument... looks reasonable but I need to think some more.
 

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