Brownian Motion Formula
The Brownian motion is calculated using a parameter known as the diffusion constant. Its formula is given by the ratio of the product of gas constant and temperature to the product of six pi times Avogadro’s number, the viscosity of the fluid, and the radius of the particle.
It is denoted by the symbol D. It is a unitless quantity as it is the ratio of the same quantities and hence has no dimensional formula.
D = RT/6πrηNa
or
D = kBT/6πrη
Where,
- D is the diffusion constant,
- kB is the Boltzmann constant with the value of 1.381 × 10-23 J/K
- R is the gas constant with the value of 8.314 J K-1 mol-1,
- T is the temperature of the surroundings,
- π is a constant with the value of 3.14,
- r is the radius of Brownian particle,
- η is the fluid viscosity,
- Na is the Avogadro’s number, that is, 6.06 x 1023 mol-1.
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Brownian Motion Formula
Brownian Movement is defined as the random movement of particles inside a fluid. It is the random zig-zag motion of a particle, which is typically observed under a high-power ultra-microscope.
It can be interpreted as the uncontrolled or irregular movement of particles in a fluid caused by constant collision with other fast-moving molecules. The random movement of a particle is typically observed to be stronger in smaller particles, less viscous liquids, and higher temperatures. When these particles move, they collide with one another. The Brownian motion explains the random movement of tiny particles floating in fluids.
Table of Content
- Brownian Motion Formula
- Brownian Motion Formula Solved Examples