Understanding Buoyancy and Drag Forces in Fluids: Causes and Differences

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SUMMARY

The discussion clarifies the distinction between buoyancy and drag forces experienced by objects in fluids. The buoyant force arises from the pressure differential created by the varying concentration of fluid molecules, with greater pressure on the lower surface of the object compared to the upper surface. In contrast, drag force is a result of the object's motion through the fluid, where increased speed leads to more frequent collisions with fluid molecules, resulting in greater resistance. Understanding these forces is essential for applications in fluid dynamics and engineering.

PREREQUISITES
  • Understanding of fluid dynamics principles
  • Knowledge of pressure differentials in fluids
  • Familiarity with Newton's laws of motion
  • Basic concepts of molecular behavior in gases
NEXT STEPS
  • Research the principles of Archimedes' principle in buoyancy
  • Study the equations governing drag force, such as the drag equation
  • Explore the effects of fluid viscosity on buoyancy and drag
  • Learn about computational fluid dynamics (CFD) simulations for analyzing fluid forces
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Students and professionals in physics, engineering, and environmental science who are interested in understanding fluid behavior and the forces acting on objects within fluids.

Cheman
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Why does an object in a fluid experience both a buoyancy force and a drag force? How are they different and what causes these two different forces?
Thanks. :-)
 
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The buoyant force is caused by the pressure differential across the top and bottom of the object. It exists regardless of motion.

Drag force is purely a motional force.

Both are caused by the impacts of nearby fluid molecules.
 
Thanks, but what do you mean by "pressure differential across the top and bottom of the object"? Could you please explain what this means, what causes this, etc?
Thanks. :-)
 
Pressure is a measure of the force applied per unit of area. In the case of an body in the air, the pressure results from air molecules impinging the surface of the body at high speeds. Because the concentration of air molecules decreases as one rises from the Earth (notice that there is a high concentration near the surface but clearly no air in space, the fall off is continous), the pressure exerted on the lower portion of the body is greater than that exerted on the upper portion of the body (less air molecules impinging the upper surface at a higher altitude). This difference in pressure, or pressure differential, is what causes the bouyant force.

Air drag is a little different in that it results from the body colliding into a large number of air molecules as it travels through the air. The faster it travels, the more air molecules the body has to push out of its way in a unit of time, so there is greater resistance at higher speeds.
 
With drag, is it that the object is colliding with eg - air molecules more often or hitting them harder, hence experiancing a greater force?
 

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