Can a Fish Move a Ball in Water?

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In summary, the conversation discusses the possibility of a fish making a ball roll by swimming in a closed system. It is suggested that if the fish has the same mean density as water, the hamster method will not work, but theoretically it could induce a flow that could spin the ball via friction on the inner walls, resulting in rolling. Other scenarios, such as the fish pointing its nose at a point on the bottom of the ball and swimming vigorously downwards, are also considered. Overall, it is determined that the fish could potentially generate a small net force in one direction, but it would not be a significant enough force to make the ball roll.
  • #36
I have faith in conservation laws. In space if I "shove off" against the edge of the wheel rather than pushing against its center of mass, with the same amount of force in both cases, in one case the wheel will spin and move away somewhat conserving momentum and the other case the wheel will move away from me conserving momentum (not spinning). By analogy I am asking if the fish is creating vortices which eventually decay into heat, is the force imparted on the ball by the collision of the fish next to the bottom completely offset by these vortices and heat produced?
 
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  • #37
metastable said:
I have faith in conservation laws. In space if I "shove off" against the edge of the wheel rather than pushing against its center of mass, with the same amount of force in both cases, in one case the wheel will spin conserving momentum and the other case the wheel will move away from me conserving momentum. By analogy I am asking if the fish is creating vortices which eventually decay into heat, is the force imparted on the ball by the collision of the fish next to the bottom completely offset by these vortices and heat produced?
I cannot make sense of a question that can only be asked by analogy.
 
  • #38
Do the water molecules set in motion by the fishes tail have interactions with other water molecules before they traverse to the other side of the ball, and if these interactions produce vortices, can these vortices completely counteract the direct force applied to the ball by the kinetic energy of the fish impacting a point adjacent to the bottom?
 
  • #39
metastable said:
Do the water molecules set in motion by the fishes tail have interactions with other water molecules before they traverse to the other side of the ball, and if these interactions produce vortices, can these vortices completely counteract the direct force applied to the ball by the kinetic energy of the fish impacting a point adjacent to the bottom?
Again, you are failing to ask a coherent question.

A single force acting in a single direction imparts momentum. That is momentum. Momentum is conserved. It is not convertible into heat.
 
  • #40
figure_15_01_02a.jpg


"The figure above shows one of Joule’s most famous experimental setups for demonstrating the mechanical equivalent of heat. It demonstrated that work and heat can produce the same effects, and helped establish the principle of conservation of energy. Gravitational potential energy (PE) (work done by the gravitational force) is converted into kinetic energy (KE), and then randomized by viscosity and turbulence into increased average kinetic energy of atoms and molecules in the system, producing a temperature increase. His contributions to the field of thermodynamics were so significant that the SI unit of energy was named after him."

https://tophat.com/marketplace/scie...ax-college-physics-openstax-content/666/19511
 
  • #41
metastable said:
What if it has the same mean density as water, and it points its nose at a point on the bottom of the ball slightly to the side of the ball's point of contact with the ground and swims vigorously directly "downwards..." ?
metastable said:
...Or what if it starts swimming from the top of the ball, aiming directly towards a point just beside where the ball makes contact with the ground, building up kinetic energy as it swims downwards, and then it collides with the point next to the ball's point of contact with the ground it was aiming towards?
If we assume that the fish has the same density as the water, the water is in-compressible, and the ball is a rigid sphere, then the center of mass of ball+water+fish is fixed in the center of the ball, no matter what the fish does. Without the possibility to move the CoM relative to the ball you cannot "shove" or "rock" the ball around.
 
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  • #42
metastable said:
"The figure above shows one of Joule’s most famous experimental setups for demonstrating the mechanical equivalent of heat. It demonstrated that work and heat can produce the same effects, and helped establish the principle of conservation of energy. Gravitational potential energy (PE) (work done by the gravitational force) is converted into kinetic energy (KE), and then randomized by viscosity and turbulence into increased average kinetic energy of atoms and molecules in the system, producing a temperature increase. His contributions to the field of thermodynamics were so significant that the SI unit of energy was named after him."
OK, now you have TOTALLY changed what you are talking about. This thread has become a total mish mosh.
 
  • #43
220px-Tibur%C3%B3n.jpg

"Sharks are denser than water, and must swim continually, using dynamic liftfrom their pectoral fins.
Bone and muscle tissues of fish are denser than water. To maintain depth, bony fish increase buoyancy by means of a gas bladder. Some fish store oils or lipids for this same purpose. Fish without these features use dynamic lift instead. It is done using their pectoral fins in a manner similar to the use of wings by airplanes and birds. As these fish swim, their pectoral fins are positioned to create lift which allows the fish to maintain a certain depth. The two major drawbacks of this method are that these fish must stay moving to stay afloat and that they are incapable of swimming backwards or hovering.[9][10]"


https://en.wikipedia.org/wiki/Fish_locomotion#Dynamic_lift
"In physostomous swim bladders, a connection is retained between the swim bladder and the gut, the pneumatic duct, allowing the fish to fill up the swim bladder by "gulping" air. Excess gas can be removed in a similar manner."

https://en.wikipedia.org/wiki/Swim_bladder
 
  • #44
metastable said:
Sharks are denser than water, ...
If the fish is denser than water, then it can just do what the hamster does or what you have described in post #3 (no ballast needed).
 
  • #45
If there is no friction, can the hamster succeed ?+
 
  • #46
A.T. said:
Without the possibility to move the CoM relative to the ball you cannot "shove" or "rock" the ball around.
I'm having an extremely difficult time conceptualizing this. My mind keeps visualizing 2 "fish" which are neutrally buoyant swimming downwards towards a "see saw" at the bottom of a pool (or rod balanced on a fulcrum). They both hit at the same time but one fish is traveling downwards at twice the velocity of the other fish. Is the center of mass at time of impact balanced? Will the "see saw" or balanced rod deflect predictably one way or the other upon impact?
 
  • #47
1977ub said:
If there is no friction, can the hamster succeed ?+
No friction with the ground means no external horizontal force, so the CoM will not move horizontally, but the contact point can slide back and forth.
 
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  • #48
phinds said:
This thread has become a total mish mosh.

  1. True.
  2. As has been said before, momentum and energy are different things and one cannot convert one to the other.
  3. Metastable, your median time before responding has been something like three minutes. I think you should more carefully read what has already been posted - you shouldn't expect to immediately understand. Firing off replies that complicate the situation isn't going to help you understand nearly as much as thinking hard about what's already been written.
 
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  • #49
This is not a closed system, because the container is in contact with the floor. As long as the fish can swim away from the center of the ball and induce a circular flow of water, then the angular momentum of the water and ball have to be offset by the angular momentum of the Earth (the only point of interaction is at the contact point between ball and floor).

If the experiment was tried in space, free from any external forces, then the center of mass of the now closed system could not be moved.

I don't see how the fish in a ball differs that much from any other "self-propelled" vehicle, such as a unicycle, bicycle, motorcycle, car, ..., other than it's inefficient.

update - A better explanation is that the fish can swim forwards in the water to keep the center of mass of ball, fish, and water in front of the contact point. Then the pull of gravity and the upwards force from the floor combine to exert a forwards torque on the ball.
 
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  • #50
rcgldr said:
This is not a closed system, because the container is in contact with the floor. As long as the fish can swim away from the center of the ball and induce a circular flow of water, then the angular momentum of the water has to be offset by the angular momentum of the ball's container (as well as the very tiny effect on the earth), in which case the ball will roll as long as the angular momentum of the water remains non-zero.
I'm not good at this conservation of angular momentum, but won't the fish's angular momentum in one direction be exactly canceled by the water's momentum in the opposite direction? This isn't like other situations, where a rider could "grab" the machine and manipulate it.
 
  • #51
So assuming a neutrally buoyant fish can’t make the ball roll... then a scuba diver in a 55 gallon drum, submerged in a particular liquid in which they are neutrally buoyant... shouldn’t be able to put an arm against each side of the drum and make the drum tip over or traverse a single millimeter, simply by pushing their body mass violently from side to side?
 
  • #52
DaveC426913 said:
I'm not good at this conservation of angular momentum, but won't the fish's angular momentum in one direction be exactly canceled by the water's momentum in the opposite direction? This isn't like other situations, where a rider could "grab" the machine and manipulate it.
I updated my answer with a simpler explanation unrelated to angular momentum.

The fish swims in place at some fixed (relative to ball) point in front of and above the contact point of the ball. I'm assuming there's enough friction or something like vanes between the water and interior surface of the ball so that the spinning water also spins the ball, so there is resistance to the water spinning, at least while the ball is accelerating.

Since the fish is in front of the contact patch, then the center of mass of the ball, fish, and water is also in front of the contact patch, and gravity's downward pull at the center of mass and the floor's upward push at the contact point coexist with a forwards torque on the ball.

This situation is similar to a ball with an internal electric motor inside, except for the interface between the water and the interior surface of the ball. Both require the center of mass to be kept in front of the contact point in order to accelerate. Once at speed, then there only needs to be enough torque to overcome rolling resistance.
 
  • #53
metastable said:
So assuming a neutrally buoyant fish can’t make the ball roll...
I was taking about a fish with the same density as water. A neutrally buoyant fish with non-uniform density can move the CoM relative to the ball and thus can produce some roll motion that way.
 
  • #54
rcgldr said:
Since the fish is in front of the contact patch, then the center of mass of the ball, fish, and water is also in front of the contact patch...
This assumes that the fish is more dense than the water, which makes it trivial (hamster method). The method I described in #5 would work with a fish of the same density as the water, so the CoM is always exactly above the contact point. But it wouldn't work continuously against resistance, because the fish would have to swim faster and faster. This is analogous to an internal reaction wheel, that spins one-way, while the ball rolls the other way.
 
  • #55
jbriggs444 said:
It is a difficult situation. Our expectation is that if a rigid object bumps into something that a high impulsive force results. But the water complicates things. In this case we have zero net momentum both before and after the collision. Does a high impulsive force actually result? I am having a hard time wrapping an intuition around the situation.

We have an upward flow of water prior to the collision. So a good question would be what happens to that flow. One answer is that it should stop. But if it stops, there has to be a force making it stop. That force is negative pressure. Negative pressure that should be centered on the impact point and that should negate the impulse from the collision. I think we're going to have to get some cavitation going before we can impart much net force. And even then, it would only be temporary.

[Negative pressure is not unreasonable. If the water is under atmospheric pressure we can have up to 15 psi of negative gauge pressure before we hit zero absolute pressure. Even negative absolute pressure is physically reasonable. Water has surface tension. In the absence of nucleation sites, it will resist forming voids. A quick trip to Google yields http://discovermagazine.com/2003/mar/featscienceof which is less than authoritative, but quite readable. This hit is more authoritative]

A football filled with water (just the top pole cut off) and an angled coat hanger with a make shift fish on the end. Anything that can go on the end of the cost hanger but still get through the north pole. Once in rotate slowly in the horizontal plane.
Possible issues are the symmetry of the ball is reduced (a little) so centre of gravity a little skewed. Also some extra turbulence from the wire but a thin wire should not impact too much.
I think it's better
rcgldr said:
This is not a closed system, because the container is in contact with the floor. As long as the fish can swim away from the center of the ball and induce a circular flow of water, then the angular momentum of the water and ball have to be offset by the angular momentum of the Earth (the only point of interaction is at the contact point between ball and floor).

If the experiment was tried in space, free from any external forces, then the center of mass of the now closed system could not be moved.

I don't see how the fish in a ball differs that much from any other "self-propelled" vehicle, such as a unicycle, bicycle, motorcycle, car, ..., other than it's inefficient.

update - A better explanation is that the fish can swim forwards in the water to keep the center of mass of ball, fish, and water in front of the contact point. Then the pull of gravity and the upwards force from the floor combine to exert a forwards torque on the ball.
I think this is what I was thinking about in terms of creating an Eddy, the centre of gravity would shift as the fish swam round. The ball is resting on a relatively small point on the south pole so very little friction to overcome. If the the fish swam round fast enough the forces on the edges could move enough to cause the ball to oscillate. Even if it is small
 
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  • #56
rcgldr said:
A better explanation is that the fish can swim forwards in the water to keep the center of mass of ball, fish, and water in front of the contact point.
If the fish is the same density as the water and if the ball is full to the top then the center of mass cannot go in front of the contact point. This was exactly my confusion since that is the mechanism for the hamster, but that mechanism doesn’t work for the fish. But even without moving the center of mass we can still produce an external torque by friction.
 
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  • #57
Dale said:
If the fish is the same density as the water and if the ball is full to the top then the center of mass cannot go in front of the contact point.
This is true if the fish has uniform density. If the fish has the same mean density as water but non-uniformly distributed the total CoM can be moved relative to the ball.

It seems there are two general mechanisms:

1) If the CoM can move relative to the ball: Translate it in front of the contact (hamster method, works continuously against resistance)

2) If the CoM cannot move relative to the ball: Spin something inside so the ball spins the other way (flywheel method, continuous work against resistance limited by the max flywheel speed)
 
  • #58
Suppose the fish weighs 5kg and the water and ball weigh 5kg, and fish floats to the “side” of the ball (90 degrees from the ball’s contact point with the ground) where it uses its tail fin to push off the edge of the glass with an energetic impulse of 250 joules. When it reaches the other side it pushes with 500 joules. At the other side again 1000 joules. The energy of the impulse doubles with each push off the opposite sides.

To calculate the motion of the fish and the ball after the first interaction can I use:

m1v1 = m2v2

where m1 is the mass of the fish and m2 is the mass of the ball and water?
 
  • #59
A.T. said:
1) If the CoM can move relative to the ball: Translate it in front of the contact (hamster method, works continuously against resistance)
My understanding is that the whole point of the exercise with the fish is to remove mechanism 1, since that is obvious from experience with hamsters.
 
  • #60
...the fish crawls with its fins along the edge of the glass, applying tangential force directly to the glass via the friction with its fins. the “normal force” holding the fish against the glass in this case would the fish’s forward velocity combined with the curvature of the glass...
 
  • #61
metastable said:
...the fish crawls with its fins along the edge of the glass, applying tangential force directly to the glass via the friction with its fins. the “normal force” holding the fish against the glass in this case would the fish’s forward velocity combined with the curvature of the glass...
This is a workable mechanism. Simplify and turn the fish into an octopus that attaches its tentacles to the wall and pulls itself along. The result is that we have the fish (and water due to viscous drag) rotating one way and a resulting torque tending to rotate the ball the other.
 
  • #62
metastable said:
...the fish crawls with its fins along the edge of the glass, applying tangential force directly to the glass via the friction with its fins. the “normal force” holding the fish against the glass in this case would the fish’s forward velocity combined with the curvature of the glass...
It could also fix itself to the glass by suction, and use the fin to push water backwards. Both are variants of the flywheel method, with the water being the flywheel.
 
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  • #63
metastable said:
Suppose the fish weighs 5kg and the water and ball weigh 5kg, and fish floats to the “side” of the ball (90 degrees from the ball’s contact point with the ground) where it uses its tail fin to push off the edge of the glass with an energetic impulse of 250 joules. When it reaches the other side it pushes with 500 joules. At the other side again 1000 joules. The energy of the impulse doubles with each push off the opposite sides.

To calculate the motion of the fish and the ball after the first interaction can I use:

m1v1 = m2v2

where m1 is the mass of the fish and m2 is the mass of the ball and water?
If the water plus fish fill the ball then, when the fish pushes off, water fills the void he leaves behind. The total momentum of fish plus water remains constant and zero. Accordingly the momentum of the ball is zero.

Doubling zero many times still leaves zero.
 
  • #64
jbriggs444 said:
If the water plus fish fill the ball then, when the fish pushes off, water fills the void he leaves behind. The total momentum of fish plus water remains constant and zero. Accordingly the momentum of the ball is zero.
So if the ball is submerged in an aquarium, with a fish inside the ball and a fish outside the ball...

The fish outside the ball pushes its tailfin off the ball deriving an impulse in one direction, and the ball moves the opposite direction.

Scenario 2 is when the fish inside the ball pushes its tail off the glass with the same amount of force. If I understand correctly you are saying in Scenario 2, the ball won’t translate by even a millimeter at any point in time.
 
  • #65
metastable said:
If I understand correctly you are saying in Scenario 2, the ball won’t translate by even a millimeter at any point in time.
Correct.
 
  • #66
So the frontal area of the fish, its drag coefficient and fluid density of the water its submerged in has no bearing? I thought if we were to reduce the frontal area and drag coefficient of the fish—

then fish (as opposed to the water) retains more kinetic energy after the fish travels X distance, after it pushes off from the side of the ball with its tail fin.
 
  • #67
rcgldr said:
Since the fish is in front of the contact patch, then the center of mass of the ball, fish, and water is also in front of the contact patch...
Woah.
We assumed the fish has the same density as water.
So CoM is centre of ball.

[ edit: OK, I'm late to the table ]
 
  • #68
phinds said:
The ball, water, and fish are a closed system. What external force do you think there is that would make the ball move?
do not know. why do you think asked the question in the first place?
 
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  • #69
Immelmann said:
do not know. why do you think asked the question in the first place?
I was trying to get you to think.
 
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  • #70
not here to think buddy, just get an answer
 
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<h2>1. Can fish really move a ball?</h2><p>Yes, certain types of fish have been observed moving objects, including balls, with their mouths or fins. However, this behavior is not common among all fish species.</p><h2>2. How do fish move the ball?</h2><p>Fish typically use their mouths or fins to push or carry the ball. Some fish, such as archerfish, have evolved specialized mouth structures to shoot jets of water at the ball to move it.</p><h2>3. Why do fish move the ball?</h2><p>Fish may move objects, including balls, for a variety of reasons. Some do it as part of their natural foraging behavior, while others may do it out of curiosity or to play.</p><h2>4. Can fish be trained to move a ball?</h2><p>Yes, some fish have been successfully trained to move objects, including balls, in laboratory settings. This requires a lot of patience and positive reinforcement from the trainer.</p><h2>5. Is it harmful for fish to move a ball?</h2><p>In most cases, it is not harmful for fish to move a ball. However, if the ball is too heavy or has sharp edges, it could potentially injure the fish. It is important to use appropriate objects and to monitor the fish's behavior when conducting experiments or training. </p>

1. Can fish really move a ball?

Yes, certain types of fish have been observed moving objects, including balls, with their mouths or fins. However, this behavior is not common among all fish species.

2. How do fish move the ball?

Fish typically use their mouths or fins to push or carry the ball. Some fish, such as archerfish, have evolved specialized mouth structures to shoot jets of water at the ball to move it.

3. Why do fish move the ball?

Fish may move objects, including balls, for a variety of reasons. Some do it as part of their natural foraging behavior, while others may do it out of curiosity or to play.

4. Can fish be trained to move a ball?

Yes, some fish have been successfully trained to move objects, including balls, in laboratory settings. This requires a lot of patience and positive reinforcement from the trainer.

5. Is it harmful for fish to move a ball?

In most cases, it is not harmful for fish to move a ball. However, if the ball is too heavy or has sharp edges, it could potentially injure the fish. It is important to use appropriate objects and to monitor the fish's behavior when conducting experiments or training.

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