Potential Energy in Limit of Closest-Approach Solution

STEP 0: Pre-Calculation Summary
Formula Used
Potential Energy = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Distance Between Surfaces)
P.E = (-A*R1*R2)/((R1+R2)*6*r)
This formula uses 5 Variables
Variables Used
Potential Energy - (Measured in Joule) - Potential Energy is the energy that is stored in an object due to its position relative to some zero position.
Hamaker Coefficient - (Measured in Joule) - Hamaker coefficient A can be defined for a Van der Waals body–body interaction.
Radius of Spherical Body 1 - (Measured in Meter) - Radius of Spherical Body 1 represented as R1.
Radius of Spherical Body 2 - (Measured in Meter) - Radius of Spherical Body 2 represented as R1.
Distance Between Surfaces - (Measured in Meter) - Distance between surfaces is the length of the line segment between the 2 surfaces.
STEP 1: Convert Input(s) to Base Unit
Hamaker Coefficient: 1E-19 Joule --> 1E-19 Joule No Conversion Required
Radius of Spherical Body 1: 12 Angstrom --> 1.2E-09 Meter (Check conversion here)
Radius of Spherical Body 2: 15 Angstrom --> 1.5E-09 Meter (Check conversion here)
Distance Between Surfaces: 1.4E-09 Angstrom --> 1.4E-19 Meter (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
P.E = (-A*R1*R2)/((R1+R2)*6*r) --> (-1E-19*1.2E-09*1.5E-09)/((1.2E-09+1.5E-09)*6*1.4E-19)
Evaluating ... ...
P.E = -7.93650793650794E-11
STEP 3: Convert Result to Output's Unit
-7.93650793650794E-11 Joule --> No Conversion Required
FINAL ANSWER
-7.93650793650794E-11 -7.9E-11 Joule <-- Potential Energy
(Calculation completed in 00.004 seconds)

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21 Van der Waals Force Calculators

Van der Waals Interaction Energy between Two Spherical Bodies
Go Van der Waals interaction energy = (-(Hamaker Coefficient/6))*(((2*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Center-to-center Distance^2)-((Radius of Spherical Body 1+Radius of Spherical Body 2)^2)))+((2*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Center-to-center Distance^2)-((Radius of Spherical Body 1-Radius of Spherical Body 2)^2)))+ln(((Center-to-center Distance^2)-((Radius of Spherical Body 1+Radius of Spherical Body 2)^2))/((Center-to-center Distance^2)-((Radius of Spherical Body 1-Radius of Spherical Body 2)^2))))
Distance between Surfaces given Van Der Waals Force between Two Spheres
Go Distance Between Surfaces = sqrt((Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Potential Energy))
Van der Waals Force between Two Spheres
Go Van der Waals force = (Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*(Distance Between Surfaces^2))
Distance between Surfaces given Potential Energy in Limit of Close-Approach
Go Distance Between Surfaces = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Potential Energy)
Potential Energy in Limit of Closest-Approach
Go Potential Energy = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Distance Between Surfaces)
Radius of Spherical Body 1 given Van der Waals Force between Two Spheres
Go Radius of Spherical Body 1 = 1/((Hamaker Coefficient/(Van der Waals force*6*(Distance Between Surfaces^2)))-(1/Radius of Spherical Body 2))
Radius of Spherical Body 2 given Van Der Waals Force between Two Spheres
Go Radius of Spherical Body 2 = 1/((Hamaker Coefficient/(Van der Waals force*6*(Distance Between Surfaces^2)))-(1/Radius of Spherical Body 1))
Radius of Spherical Body 1 given Potential Energy in Limit of Closest-Approach
Go Radius of Spherical Body 1 = 1/((-Hamaker Coefficient/(Potential Energy*6*Distance Between Surfaces))-(1/Radius of Spherical Body 2))
Radius of Spherical Body 2 given Potential Energy in Limit of Closest-Approach
Go Radius of Spherical Body 2 = 1/((-Hamaker Coefficient/(Potential Energy*6*Distance Between Surfaces))-(1/Radius of Spherical Body 1))
Coefficient in Particle-Particle Pair Interaction
Go Coefficient of Particle–Particle Pair Interaction = Hamaker Coefficient/((pi^2)*Number Density of particle 1*Number Density of particle 2)
Radius of Spherical Body 1 given Center-to-Center Distance
Go Radius of Spherical Body 1 = Center-to-center Distance-Distance Between Surfaces-Radius of Spherical Body 2
Radius of Spherical Body 2 given Center-to-Center Distance
Go Radius of Spherical Body 2 = Center-to-center Distance-Distance Between Surfaces-Radius of Spherical Body 1
Distance between Surfaces given Center-to-Center Distance
Go Distance Between Surfaces = Center-to-center Distance-Radius of Spherical Body 1-Radius of Spherical Body 2
Center-to-Center Distance
Go Center-to-center Distance = Radius of Spherical Body 1+Radius of Spherical Body 2+Distance Between Surfaces
Distance between Surfaces given Van Der Waals Pair Potential
Go Distance Between Surfaces = ((0-Coefficient of Particle–Particle Pair Interaction)/Van der Waals pair potential)^(1/6)
Coefficient in Particle-Particle Pair Interaction given Van der Waals Pair Potential
Go Coefficient of Particle–Particle Pair Interaction = (-1*Van der Waals pair potential)*(Distance Between Surfaces^6)
Van Der Waals Pair Potential
Go Van der Waals pair potential = (0-Coefficient of Particle–Particle Pair Interaction)/(Distance Between Surfaces^6)
Molar Mass given Number and Mass Density
Go Molar Mass = ([Avaga-no]*Mass Density)/Number Density
Mass Density given Number density
Go Mass Density = (Number Density*Molar Mass)/[Avaga-no]
Concentration given Number Density
Go Molar Concentration = Number Density/[Avaga-no]
Mass of Single Atom
Go Atomic Mass = Molecular Weight/[Avaga-no]

Potential Energy in Limit of Closest-Approach Formula

Potential Energy = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Distance Between Surfaces)
P.E = (-A*R1*R2)/((R1+R2)*6*r)

What are main characteristics of Van der Waals forces?

1) They are weaker than normal covalent and ionic bonds.
2) Van der Waals forces are additive and cannot be saturated.
3) They have no directional characteristic.
4) They are all short-range forces and hence only interactions between the nearest particles need to be considered (instead of all the particles). Van der Waals attraction is greater if the molecules are closer.
5) Van der Waals forces are independent of temperature except for dipole – dipole interactions.

How to Calculate Potential Energy in Limit of Closest-Approach?

Potential Energy in Limit of Closest-Approach calculator uses Potential Energy = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Distance Between Surfaces) to calculate the Potential Energy, The Potential Energy in limit of closest-approach formula is defined as is the energy that is stored in an object by virtue to its position. Potential Energy is denoted by P.E symbol.

How to calculate Potential Energy in Limit of Closest-Approach using this online calculator? To use this online calculator for Potential Energy in Limit of Closest-Approach, enter Hamaker Coefficient (A), Radius of Spherical Body 1 (R1), Radius of Spherical Body 2 (R2) & Distance Between Surfaces (r) and hit the calculate button. Here is how the Potential Energy in Limit of Closest-Approach calculation can be explained with given input values -> -7.9E-11 = (-1E-19*1.2E-09*1.5E-09)/((1.2E-09+1.5E-09)*6*1.4E-19).

FAQ

What is Potential Energy in Limit of Closest-Approach?
The Potential Energy in limit of closest-approach formula is defined as is the energy that is stored in an object by virtue to its position and is represented as P.E = (-A*R1*R2)/((R1+R2)*6*r) or Potential Energy = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Distance Between Surfaces). Hamaker coefficient A can be defined for a Van der Waals body–body interaction, Radius of Spherical Body 1 represented as R1, Radius of Spherical Body 2 represented as R1 & Distance between surfaces is the length of the line segment between the 2 surfaces.
How to calculate Potential Energy in Limit of Closest-Approach?
The Potential Energy in limit of closest-approach formula is defined as is the energy that is stored in an object by virtue to its position is calculated using Potential Energy = (-Hamaker Coefficient*Radius of Spherical Body 1*Radius of Spherical Body 2)/((Radius of Spherical Body 1+Radius of Spherical Body 2)*6*Distance Between Surfaces). To calculate Potential Energy in Limit of Closest-Approach, you need Hamaker Coefficient (A), Radius of Spherical Body 1 (R1), Radius of Spherical Body 2 (R2) & Distance Between Surfaces (r). With our tool, you need to enter the respective value for Hamaker Coefficient, Radius of Spherical Body 1, Radius of Spherical Body 2 & Distance Between Surfaces and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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