Stokes Law Derivation

Edited By Vishal kumar | Updated on Jul 02, 2025 04:44 PM IST

Introduction
In this article, our focus will be on stokes law its formula and derivation, limitations of stokes law etc.

What is stokes law?

The drag force that stops small spherical particles from falling through a fluid medium is described by Stokes' law, a mathematical equation 6πrηv, where r is the radius of the sphere, v is the velocity of the fall, η is the viscosity of the liquid,

The downward force is equal to , where is the density of the sphere, is the density of the liquid, and g is the acceleration due to gravity. At a constant rate of fall, known as the terminal velocity, the upward and downward forces are in equilibrium. The equation of the two expressions given above and the resolution of v, therefore, gives the required velocity expressed as

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What is stokes law?
Stokes law formula
Stokes law derivation
Limitation of stokes law
Some limitations of Stokes law are:

Stokes Law Derivation - Definition, Formula, FAQs

v =

However, since its validity is limited to conditions where the movement of the particle does not create turbulence in the liquid, various modifications have been made.

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Stokes law formula

r is the radius of the sphere, η is the fluid viscosity, and v is the sphere’s velocity.

The viscous force acting on a sphere is directly proportional to the following parameters, according to Stokes Law viscosity equation:

the sphere’s radius
coefficient of viscosity
the object’s velocity

It is represented as:

………………………………. (i)

K be the constant of proportionality is a numerical value and has no dimensions.

equating the dimensions of parameters on either side of equation (i), we get

Simplifying the above equation, we get,

Equating the superscripts of M, L and T respectively from above equation, we get

a=b=c=1

putting these values in (i)

F = knrv

k= 6for a spherical body

So,

Limitation of stokes law

Stokes' law for the resistance of a falling sphere is not only historically significant due to its use to determine the basic electronic charge, but it is still used today to calculate the viscosity of a liquid. Greenwood et al.³ recently presented a novel method for this. Use Atwood's machine to control the driving force of the balls that fall through the fluid being sought for viscosity. Despite their simplicity, they obtain experimental viscosity values that are systematically higher than the manual N values. The excess is not small and reaches up to 62%. They found with a K generally increasing to increase the diameter of the ball d. The only explanation they offer is that the 0.05mm thick wire being inserted into the liquid may have a greater effect than expected, although they find that explanation unlikely later in the article. Since glycerine is a Newtonian liquid in this range, the viscosity is a constant of the material and it is necessary to account for the apparent viscosity change above. This makes this experiment even more suitable for students because, despite the frankness of the method, the error is surprisingly large, and the experiment ends with a question rather than an answer.

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Some limitations of Stokes law are:

Negative density difference in Stokes equation

The Stokes equation is not valid if the density difference in the equation is negative, that is, if the particles are lighter than the scattering medium. This results in floatation or creaming, which is more commonly seen in emulsion systems.

High content of dispersed solids

When the solids content of a suspension is high, the Stokes equation may not reflect the actual sedimentation rate. A high solids content gives the system additional viscosity that must be taken into account when determining the correct settling rate. The equation only includes the viscosity of the medium.

Dielectric constant

The ignored dielectric constant in the Stokes equation is an important parameter in many situations. The electric potential between two charges has an inverse relationship to the dielectric constant of the medium. Therefore, the zeta potential depends on the dielectric constant of the medium.

It follows that in a vehicle with a low dielectric constant, the double layer is many times thicker than in an aqueous medium, which also leads to a different zeta potential and therefore the sedimentation is different.

Brownian motion

Brownian motion, a random (zigzag) motion of suspended particles in a liquid caused by their collision with rapidly moving atoms or molecules in the gas or liquid, is another factor that can affect accuracy of the results in Stokes Equation. Brownian motion counteracts sedimentation to a measurable degree. This can lead to a large deviation of the actual sedimentation rate from that calculated according to the Stokes equation.

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Stokes law of sedimentation

Small particles of a certain size range in liquid suspension tend to settle due to various forces acting on them. This behaviour of the particles is known as sedimentation.

Particles with a size less than 75 µm cannot be sieved because the smaller particles carry charges on their surface and tend to adhere to each other and to other particles, even to the sieves or the experimenter's hands. Dealing with such soils would be very difficult.

To analyse soils with these particles, we use the sedimentation analysis method.

A small particle in a liquid suspension, according to this law, tends to settle under its own weight due to gravity's effect. And due to the acceleration due to gravity, its downward speed keeps increasing.

But two forces,

One is the buoyant force that works upwards and due to the pressure difference acts on the body within the liquid.

seconds is the resistance force, which is a resistance force and acts against the direction of movement of the body.

These two forces begin to act on the particle in the opposite direction to the particle's motion and begin to decelerate the particle until it reaches equilibrium. And this makes the speed of the particles constant. That is, the particle now falls at a constant velocity called the terminal velocity.

Writing an equilibrium equation for this particle falling in a liquid yields the term for the terminal velocity.

Particle weight W down, buoyancy B and drag force D up.

As a result, the equilibrium equation will be W = B + D.

B + D = W

The weight of a particle can be calculated by multiplying its volume by its unit weight, gamma s.

The buoyant force is equal to the weight of the liquid, which in our instance is water. This particle has displaced, which is equal to the volume of the particle multiplied by the unit weight of water it displaces.

is the weight of particle of soil

is the weight of water

is the dynamic viscosity

Solving this equation,

Terminal velocity,

By using a simple equation of motion, we can see that the velocity of any particle falling through a height of He centimetre in time t minutes is He upon t.

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NCERT Physics Notes:

Frequently Asked Questions (FAQs)

1. State stokes law and derive an expression for it

The drag force that stops small spherical particles from falling through a fluid medium is described by Stokes' law, a mathematical equation.

According to Stokes law, the drag force F is equal to 6πrηv, where r is the radius of the sphere, η is the viscosity of the liquid, and v is the rate of fall.

2. Stokes law is valid for particle size ……………………...?

Stokes law- particle size –( 0.2mm to .0002mm)

3. How does the shape of a particle affect the applicability of Stokes' Law?

Stokes' Law assumes perfectly spherical particles. Non-spherical particles experience different drag forces due to their orientation and surface area. For such particles, modifications to Stokes' Law or alternative equations are needed to accurately predict drag forces.

4. What is the Stokes-Einstein equation and how does it relate to Stokes' Law?

The Stokes-Einstein equation combines Stokes' Law with principles of Brownian motion to relate the diffusion coefficient of a particle to its size and the fluid viscosity. It's crucial in understanding the behavior of colloidal particles and in fields like protein dynamics and nanoparticle characterization.

5. How does temperature affect the drag force predicted by Stokes' Law?

Temperature indirectly affects the drag force by changing the fluid's viscosity. Generally, as temperature increases, fluid viscosity decreases, leading to a lower drag force. This relationship is important in many industrial and natural processes where temperature variations occur.

6. What is the Cunningham correction factor and when is it used with Stokes' Law?

The Cunningham correction factor is applied to Stokes' Law when dealing with very small particles (typically less than 1 micrometer) in gases. It accounts for the breakdown of the continuum assumption of fluid mechanics at these scales, where the mean free path of gas molecules becomes significant compared to particle size.

7. How does Stokes' Law apply to the sedimentation of particles in a centrifuge?

In centrifugation, Stokes' Law is used to predict the sedimentation rate of particles. The gravitational force in the equation is replaced by the centrifugal force, allowing calculation of settling velocities in a centrifugal field. This is crucial in many separation and analysis techniques in biology and chemistry.

8. How does particle size affect the validity of Stokes' Law?

Stokes' Law is most accurate for small particles. As particle size increases, the assumptions of laminar flow and low Reynolds number may no longer hold, leading to deviations from the law. Generally, it's most applicable for particles with diameters less than about 100 micrometers in typical fluids.

9. Why is the Reynolds number important in the context of Stokes' Law?

The Reynolds number indicates whether flow around an object is laminar or turbulent. Stokes' Law assumes laminar flow, which occurs at low Reynolds numbers (typically less than 0.1). At higher Reynolds numbers, the flow becomes turbulent, and Stokes' Law no longer accurately predicts the drag force.

10. What is the difference between Stokes' drag and form drag?

Stokes' drag primarily results from viscous forces and dominates at low Reynolds numbers. Form drag, on the other hand, is caused by pressure differences and becomes significant at higher Reynolds numbers. Stokes' Law only accounts for viscous drag and is not applicable when form drag is substantial.

11. Why is Stokes' Law important in the study of atmospheric aerosols?

Stokes' Law helps predict the settling velocity of aerosol particles in the atmosphere. This is crucial for understanding air pollution dispersion, cloud formation processes, and the residence time of particles in the air. It's also used in designing air filtration systems.

12. How does Stokes' Law relate to Brownian motion?

Stokes' Law is used in the Einstein-Smoluchowski relation, which describes Brownian motion. It helps explain how the random motion of particles in a fluid is affected by fluid viscosity and particle size. This connection is crucial in understanding diffusion processes and colloidal stability.

13. What are the key assumptions in deriving Stokes' Law?

The main assumptions are: 1) The fluid is incompressible and Newtonian, 2) The flow is laminar (low Reynolds number), 3) The particle is a perfect sphere, 4) There's no slip at the particle surface, and 5) The fluid extends infinitely in all directions from the particle.

14. What is the significance of the 6π factor in Stokes' Law equation?

The 6π factor in Stokes' Law (F = 6πηrv) arises from the mathematical derivation involving the integration of stress over the surface of a sphere. It's not arbitrary but a result of solving the Navier-Stokes equations for the specific case of a sphere in laminar flow.

15. How does Stokes' Law relate to terminal velocity?

Stokes' Law is used to calculate the terminal velocity of a small sphere falling in a viscous fluid. When the drag force equals the gravitational force, the sphere reaches its terminal velocity. This concept is crucial in understanding particle settling in various natural and industrial processes.

16. How does fluid viscosity affect the drag force in Stokes' Law?

Fluid viscosity is directly proportional to the drag force in Stokes' Law. Higher viscosity fluids exert greater drag on moving particles. This relationship is linear, meaning doubling the viscosity will double the drag force, assuming all other factors remain constant.

17. How does Stokes' Law apply to the motion of blood cells in blood vessels?

Stokes' Law can be applied to understand the motion of individual blood cells in small blood vessels where flow is nearly laminar. It helps in modeling the behavior of red blood cells, white blood cells, and platelets, which is important in understanding microcirculation and designing artificial blood substitutes.

18. What is the significance of Stokes' Law in the design of air filtration systems?

Stokes' Law is crucial in designing air filters as it helps predict how particles of different sizes will behave in the filter medium. It's used to calculate the efficiency of particle capture by mechanisms like interception and inertial impaction, which is essential for creating effective air purification systems.

19. How does Stokes' Law contribute to our understanding of sediment transport in glaciers?

Stokes' Law helps in modeling the behavior of fine sediment particles suspended in glacial meltwater. It's used to predict settling rates and transport distances of different-sized particles, which is important for understanding glacial erosion processes, sediment deposition patterns, and their impact on landscapes.

20. How does Stokes' Law apply to the design of air quality monitoring equipment?

Stokes' Law is used in designing particle samplers and classifiers in air quality monitoring. It helps determine the cut-off sizes for different particle fractions (e.g., PM10, PM2.5) based on their settling velocities. This is crucial for accurate measurement and classification of airborne particulates.

21. What is the relationship between Stokes' Law and Archimedes' principle?

While Stokes' Law describes the drag force on a moving particle, Archimedes' principle describes the buoyant force on a submerged object. Together, they help determine the net force on a particle in a fluid, which is crucial for understanding settling or rising behavior in various applications like sedimentation or bubble dynamics.

22. How does Stokes' Law apply to the study of pollen dispersal in the air?

Stokes' Law is used to model the settling behavior of pollen grains in air. It helps predict how far pollen can travel before settling, which is important in understanding plant reproduction patterns, allergology, and paleoclimatology (through the study of ancient pollen deposits).

23. What is Stokes' Law and why is it important in fluid dynamics?

Stokes' Law describes the drag force experienced by a small, spherical object moving slowly through a viscous fluid. It's important because it helps us understand the behavior of particles in fluids, which has applications in fields like sedimentation, aerosol science, and blood flow in the body.

24. What is creeping flow and how does it relate to Stokes' Law?

Creeping flow, also known as Stokes flow, refers to very slow, viscous flow where inertial forces are negligible compared to viscous forces. This is the flow regime where Stokes' Law is valid. Understanding creeping flow is crucial in microfluidics, lubrication theory, and the movement of microorganisms.

25. How does Stokes' Law contribute to our understanding of sedimentation in rivers and oceans?

Stokes' Law helps predict the settling velocities of fine sediment particles in water bodies. This is crucial for understanding sediment transport, deposition patterns, and the formation of geological structures. It's also important in environmental studies related to pollutant transport and ecosystem health in aquatic environments.

26. What is the role of Stokes' Law in understanding the behavior of aerosols in the respiratory system?

Stokes' Law helps predict the deposition of inhaled particles in different parts of the respiratory tract. It's used to model how particles of various sizes settle in airways, which is crucial for understanding respiratory health risks, designing inhalation therapies, and developing protective equipment like masks.

27. How does Stokes' Law help in understanding the formation of raindrops?

Stokes' Law helps explain the initial growth of water droplets in clouds. It predicts the settling velocities of tiny water droplets, which influences their collision rates and coalescence. As droplets grow larger, they eventually deviate from Stokes' Law, leading to faster fall speeds and rain formation.

28. What is the Stokes number and why is it important in particle dynamics?

The Stokes number is a dimensionless quantity that characterizes the behavior of particles suspended in a fluid flow. It's the ratio of the particle's stopping distance to a characteristic dimension of the obstacle. A high Stokes number indicates that particles will continue in a straight path, while a low number means particles will follow fluid streamlines closely.

29. What is the limitation of Stokes' Law in predicting the behavior of non-Newtonian fluids?

Stokes' Law assumes a Newtonian fluid with constant viscosity. For non-Newtonian fluids, where viscosity changes with shear rate, Stokes' Law doesn't accurately predict drag forces. Modified versions or entirely different models are needed for fluids like blood, polymer solutions, or suspensions.

30. How does Stokes' Law contribute to the field of nanofluidics?

In nanofluidics, Stokes' Law helps in understanding the behavior of nanoparticles in fluids. However, at nanoscales, additional factors like Brownian motion and surface effects become significant. Modified versions of Stokes' Law are used to account for these nanoscale phenomena in applications like drug delivery and nanoparticle synthesis.

31. What is the significance of Stokes' Law in the oil industry, particularly in enhanced oil recovery?

Stokes' Law is important in understanding the behavior of oil droplets in water and vice versa during oil extraction. It helps in predicting the settling of water droplets in oil tanks and the rise of oil droplets in produced water. This knowledge is crucial for designing separation equipment and enhancing oil recovery techniques.

32. How does Stokes' Law apply to the study of volcanic ash dispersion?

Stokes' Law is used to model the settling of volcanic ash particles in the atmosphere. It helps predict ash fall patterns and the duration ash remains suspended in air, which is crucial for aviation safety, environmental impact assessments, and understanding long-term climatic effects of volcanic eruptions.

33. How does Stokes' Law contribute to the understanding of cloud droplet formation and growth?

Stokes' Law helps explain the initial growth of cloud droplets by collision and coalescence. It predicts the settling velocities of tiny water droplets, influencing their collision rates. This understanding is fundamental in cloud physics and precipitation formation processes.

34. What is the importance of Stokes' Law in the field of chromatography?

In chromatography, especially size-exclusion chromatography, Stokes' Law helps in understanding the separation of molecules based on their size. It's used to predict how particles of different sizes move through a porous medium, which is crucial for optimizing separation techniques in analytical chemistry and biochemistry.

35. What is the role of Stokes' Law in understanding the behavior of microplastics in aquatic environments?

Stokes' Law is applied to predict the settling and suspension behavior of microplastic particles in water bodies. This helps in understanding their distribution in different layers of water, their potential for long-distance transport, and their interaction with aquatic ecosystems, which is crucial for environmental impact assessments.

36. How does Stokes' Law apply to the study of dust particle behavior in interstellar space?

In astrophysics, Stokes' Law is used to model the behavior of dust particles in interstellar gas. It helps in understanding the dynamics of dust in nebulae, star-forming regions, and planetary atmospheres, which is crucial for theories of planet and star formation.

37. What is the importance of Stokes' Law in the field of microfluidics?

In microfluidics, Stokes' Law is fundamental in understanding particle behavior in small channels where flow is typically laminar. It's used in designing microfluidic devices for particle separation, cell sorting, and lab-on-a-chip applications, where precise control over particle movement is crucial.

38. How does Stokes' Law contribute to the study of sedimentation in wastewater treatment?

Stokes' Law is essential in designing sedimentation tanks in wastewater treatment plants. It helps predict the settling rates of different-sized particles, which is crucial for determining tank dimensions and retention times. This understanding is key to efficient solid-liquid separation in water treatment processes.

39. What is the significance of Stokes' Law in understanding the behavior of aerosols in clean room environments?

In clean room technology, Stokes' Law is used to predict the settling behavior of airborne particles. This is crucial for designing air filtration systems, determining air flow patterns, and establishing protocols to maintain ultra-clean environments necessary in semiconductor manufacturing, pharmaceutical production, and other sensitive industries.

40. How does Stokes' Law apply to the study of particle transport in porous media like soil?

Stokes' Law helps in modeling the movement of small particles through porous media such as soil. It's used to understand processes like groundwater contamination, soil erosion, and filtration. This application is crucial in environmental science, hydrology, and civil engineering.

41. What is the role of Stokes' Law in understanding the behavior of nanoparticles in biological systems?

In nanomedicine and toxicology, Stokes' Law is applied to predict the behavior of nanoparticles in blood vessels and tissues. It helps in understanding how nanoparticles move through the body, which is crucial for designing drug delivery systems and assessing potential health risks of nanomaterials.

42. How does Stokes' Law contribute to the field of rheology, especially in studying complex fluids?

While Stokes' Law itself assumes Newtonian fluids, it serves as a foundation for understanding more complex fluid behaviors. In rheology, modifications of Stokes' Law are used to study non-Newtonian fluids, helping to characterize materials like polymers, suspensions, and biological fluids.

43. What is the importance of Stokes' Law in understanding the formation and stability of emulsions?

Stokes' Law helps predict the rate at which droplets in an emulsion will rise or settle, which is crucial for understanding emulsion stability. This application is important in industries like food processing, cosmetics, and pharmaceuticals where emulsion stability is key to product quality and shelf life.

44. How does Stokes' Law apply to the study of particle deposition in the lungs during mechanical ventilation?

In medical applications, Stokes' Law is used to model particle deposition in different regions of the lungs during mechanical ventilation. This understanding is crucial for optimizing the delivery of aerosolized medications and for assessing potential risks associated with particle inhalation in ventilated patients.

45. What is the significance of Stokes' Law in understanding the behavior of bubbles in liquids?

Stokes' Law can be applied to predict the rise velocity of small bubbles in liquids. This is important in various fields including chemical engineering (e.g., in bubble column reactors), oceanography (understanding gas exchange at the ocean surface), and beverage industry (carbonation processes).

46. How does Stokes' Law contribute to the study of particle removal in swimming pool filtration systems?

Stokes' Law is used to understand the settling behavior of particles in swimming pool water and the efficiency of filtration systems. It helps in designing filters and determining circulation rates necessary to maintain water clarity, which is crucial for both aesthetics and hygiene in pool maintenance.

47. What is the role of Stokes' Law in understanding the behavior of dust particles in clean energy technologies like solar panels?

Stokes' Law helps in modeling dust particle deposition on solar panel surfaces. This understanding is crucial for developing effective cleaning strategies and designing self-cleaning surfaces, which is important for maintaining the efficiency of solar energy systems, especially in dusty environments.

48. How does Stokes' Law apply to the study of particle behavior in fuel injectors and combustion chambers?

In automotive and aerospace engineering, Stokes' Law is used to model the behavior of fuel droplets in injectors and combustion chambers. This helps in optimizing