Free-falling body subject to air resistance

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SUMMARY

A free-falling body subject to air resistance experiences a decrease in acceleration until it reaches terminal velocity, where air resistance equals the weight of the body. This results in a curve with a decreasing slope that eventually flattens out to a constant velocity. For small objects, air resistance is approximately proportional to speed, represented by the equation f = -mg - kv. In contrast, for larger objects like feathers, air resistance is more accurately modeled as proportional to the square of velocity, expressed as f = -mg + kv².

PREREQUISITES
  • Understanding of Newton's laws of motion
  • Familiarity with basic physics concepts such as force and acceleration
  • Knowledge of the equations of motion under gravity
  • Concept of terminal velocity and its implications
NEXT STEPS
  • Study the effects of air resistance on different shapes and sizes of objects
  • Learn about the mathematical modeling of free fall with air resistance
  • Explore the differences in drag coefficients for various materials and shapes
  • Investigate the implications of terminal velocity in real-world applications
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Physics students, educators, and anyone interested in understanding the dynamics of free-falling objects and the effects of air resistance on motion.

polyperson
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If a free-falling body is not subject to air resistance, there is a linear relationship between v and t giving a line with constant slope (g) showing velocity increasing with time.

If air resistance is taken into account, my guess is that acceleration will decrease until the terminal velocity is reached (i.e. where air resistance = weight of body) giving a curve with decreasing slope which flattens out to constant velocity.

Is this correct or am I barking up the wrong tree? I made certain assumptions i.e that the body is heavy with a large surface area. I know that the curve for a feather would look different!
 
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polyperson said:
If a free-falling body is not subject to air resistance, there is a linear relationship between v and t giving a line with constant slope (g) showing velocity increasing with time.
If air resistance is taken into account, my guess is that acceleration will decrease until the terminal velocity is reached (i.e. where air resistance = weight of body) giving a curve with decreasing slope which flattens out to constant velocity.
Is this correct or am I barking up the wrong tree? I made certain assumptions i.e that the body is heavy with a large surface area. I know that the curve for a feather would look different!
Yes, that's correct. You can't be a whole lot more precise. For small objects, the air-resistance is reasonably close to being proportional to the speed: instead of f= -mg you have f= -mg- kv. For larger objects, such as your feather, it's closer to being proportional to v2: f= -mg+ kv2. (The difference in sign is to keep the air resistance upward. If a body is falling downward, v is negative but v2 is positive.)
 
Many thanks for that
 

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