What Causes the Coriolis Effect in Constant Velocity Circular Motion?

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Discussion Overview

The discussion revolves around the Coriolis Effect, particularly in the context of constant velocity circular motion. Participants explore its origins, implications, and the distinction between real and fictitious forces, while addressing misunderstandings related to the effect's dependence on radial and tangential velocities.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • One participant questions the explanation of the Coriolis Effect as being due to changes in radius, noting that an object moving at constant velocity on the edge of a circular system still experiences the effect.
  • Another participant asserts that the instructor may have misspoken, agreeing that an object moving tangentially in a rotating frame will experience a Coriolis force without radial motion.
  • A participant suggests separating the discussion into two cases: one with tangential velocity and no radial velocity, and another with radial velocity but no initial tangential velocity.
  • One contribution explains the Coriolis Effect as arising from the application of Newton's second law in a non-inertial frame, introducing the concept of fictitious forces to account for observed motion.
  • Another participant emphasizes that the Coriolis force is a fictitious force that appears when analyzing motion from a non-inertial frame, contrasting it with the inertial frame where Newton's laws apply directly.
  • A request for additional resources or articles on the Coriolis Effect indicates some participants still find the topic unclear.

Areas of Agreement / Disagreement

Participants express differing views on the nature and origin of the Coriolis Effect, with no consensus reached on a definitive explanation. Some agree on the role of fictitious forces, while others remain uncertain about the clarity of the concept.

Contextual Notes

Participants highlight the complexity of applying Newton's laws in non-inertial frames and the potential for misunderstanding the nature of forces involved, indicating a need for careful consideration of definitions and contexts.

boa_co
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Hi, everyone

We were told in class that the Coriolis Effect is due to the change in the radius in circular motion.

But an objtct moving with constant velocity on the edje of the circular system, like on the equator still experiencing Coriolis force, because the cross product 2wXv is not zero.

Why is that? There is no change in the radius, so what gives?
 
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See [thread=393932]this recent thread[/thread].
 
Your instructor misspoke, or you misinterpreted what he said. In any case, you are correct: An object moving tangentially in a rotating frame will experience a Coriolis force, even though there is no radial motion.
 
O.K. It's a bit more clear now. But where does the Coriolis Effect come from then?
 
It is not a real force it is more like an imaginary force bcause of the frame of reference you have chosen .
 
boa_co said:
O.K. It's a bit more clear now. But where does the Coriolis Effect come from then?

It's practical to first discuss two effects separately, and later combine them again.

- There is the case of tangential velocity (with respect to the rotating system), but no radial velocity. Then you get the effect that is the subject of the https://www.physicsforums.com/showthread.php?t=393932" that DH pointed out in an earlier message.

- There is the case of radial velocity, but no tangential velocity (initially).
In the case where the centripetal force is precisely enough to sustain the circumnavigating motion there is no radial velocity. To have some inward/outward radial velocity there needs to be a either a surplus of centripetal force, or not enough of it.

attachment.php?attachmentid=23280&d=1264285060.gif


The left hand side of the animation shows an object moving along an ellipse-shaped trajectory. A centripetal force sustains that trajectory, the animation depicts the case where the strength of the centripetal force is proportional to the distance to the central point.

Interestingly, the ellipse-shaped trajectory can be thought of as decomposed in a circle and an epi-circle.

The right hand side of the animation shows what the motion looks like as seen from a point of view that is rotating with constant angular velocity. As you can see the animation combines the cases of motion in radial direction and motion in tangential direction.

When a mass has a velocity with respect to the rotating system there is a tendency to deflect. This tendency to deflect is equally strong in all directions.
 
Last edited by a moderator:
boa_co said:
O.K. It's a bit more clear now. But where does the Coriolis Effect come from then?
Short answer:
It comes from trying to use Newton's second law in a regime where Newton's second law isn't valid.Long-winded answer:
Let's use the merry-go-round example of the centrifugal force and Coriolis effect. You are on the merry-go-round and throw a ball to someone else on the merry-go-round. Someone else standing on the ground outside the merry-go-round is watching this affair.

The behavior of the ball as perceived by that outside observer is easy to explain. Once the ball has left your hand the only force acting on the ball is gravity. The ball follows a nice simple arc, pretty much the same as the arc that would have been followed if the ball was thrown by someone standing on the ground. In particular, the only curve is vertical. The horizontal component of the ball's trajectory follows a straight line. The relevant equation is good old F=ma.

The behavior of the ball as perceived by you is a bit harder to explain. The trajectory curves both vertically and horizontally. If you want to explain things via F=ma, there must be some horizontal component to the force. There is of course no real force that is curving the ball horizontally. The problem is trying to use F=ma where F=ma is not valid.

That said, there is nothing wrong with creating those fictitious forces to explain the ball's trajectory. It does work. It is important to always remember that those forces are not quite real. They are called fictitious forces for a good reason.
 
boa_co said:
where does the Coriolis Effect come from then?

When no force acts upon an object and the object's motion is viewed from a non-inertial frame of reference, then the object appears to accelerate. In order to make this result consistent with F=ma, a fictitious force is postulated. For certain cases, this force is classified as a Coriolis force. (In other selected cases, the fictitious force is called a centrifugal force.) Relative to an inertial frame, these fictitious forces are not required, since Newton's 2nd law accurately governs the motion of an object relative to every inertial frame.
 
Thanks for your answers but it is just a bit fuzzy yet. Does anyone have a link to an article or some kind of resource about Coriolis?
 

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