Well, you're still struggling with the idea that up and down are different, so there's amazement on both sides.
You will notice that the larger object does not have the same velocity before and after the collision.
Here you are putting the minus sign in by hand. You are just calling the final velocity -u instead of u. So when you conclude that "If u = -v the impulse is zero." you are saying that the final velocity, which is -u, is v. That is, no collision has taken place. The ball goes on its way.
Look, momentum is always conserved. Not just at some two points in the journey. The velocity of the falling ball is gt. Its momentum is mgt. It is a function of time. If you only look at the ball's momentum, it's clearly not constant. So its change is (in general) not zero.
This is ridiculous.
In the example given if u and v have the same sign
before and after collision it means the direction of the ball hasn’t changed; otherwise how do you differentiate the case when the direction has changed.
Where u = -v is an elastic collision against a stationary (massive) object.
In this case the impulse on the large ball is zero since it remains stationary throughout the collision where U = V = 0.
By Newton’s third law if J1 = mv – m(-u) and J2 = MV – MU then J1 = -J2 = 0 since J2 = 0.
Hence J1 = mv – m(-u) = 0 can only be true if u = -v where u and v are of the same magnitude but in opposite directions.
Needless to state the impulse has to be zero in this case otherwise momentum is not conserved as there is an external force.
Again with your geocentrism. The Earth is not an immovable object. If you treat it as one, then gravity is an external force. If you don't treat it as one, then the earth is in motion after the collision.
Either you treat the earth as fixed and gravity as an external force (in which case momentum is not conserved and your argument is wrong).
Or you treat the earth as movable and gravity as an internal force (in which case momentum is conserved and your final velocities are wrong).
This is so profoundly wrong.
The reason why momentum is conserved in both elastic and inelastic collisions is due to Newton’s third law.
On collision both the ball and Earth exert forces that are equal on each other but opposite in direction.
As a result the external force is zero and momentum is always conserved in the observer’s frame of reference.
Here is a
simple explanation for the connection between conservation of momentum, impulse and Newton’s third law.
The one-dimensional elastic collision of two objects is a
solved problem. We can
write the formula in closed form.
The collision is fully specied given the two initial velocities and masses of the colliding objects. Combining the above equations gives a solution to the final velocities for an elastic collision of two objects:
vf1 = [(m1 - m2)·vi1 + 2 m2·vi2]/(m1 + m2)
vf2 = [2 m1·vi1 - (m1 - m2)·vi2]/(m1 + m2)
In your preferred frame, the initial velocity of the ball (m1 = m) is v, and the initial velocity of the Earth (m2 = M) is zero.
Final velocity of the ball is vf1 = [(m1 - m2)·vi1 + 2 m2·vi2]/(m1 + m2)
= [(m - M)·v + 2 M·(0)]/(m + M)
= (m-M)/(m+M)v
Final velocity of the Earth is vf2 = [2 m1·vi1 - (m1 - m2)·vi2]/(m1 + m2)
= [2 m·v - (m - M)·(0)]/(m + M)
= 2mv/(m + M)
If one momentum is up and the other is down, and you get deltap by subtraction, then deltap cannot be zero.
Your finest effort so far in this thread in terms of obfuscation was to throw in a COM frame of reference as a red herring to confuse the issue when you were asked to address the elastic collision in the observer’s frame of reference.
Now the goalposts have been changed again as you have been caught out making claims the total momentum in a COM frame is non zero.
You seem to be blissfully unaware that your cut and paste job based on the observer’s frame of reference is acknowledging momentum is conserved; a point you have vehemently opposed apparently until now!!
When m2 is very large vf1 → -vi1 and vf2 → 0, which is exactly the condition one would expect of an elastic ball hitting a stationary Earth which remains stationary while the ball rebounds with the same magnitude initial velocity but in the opposite direction.
Did you actually try using the calculator?
If you plug in very large values for m2 with vfi = 0 there are no surprises that m2 remains stationary and vf1 = -vi1
The irony is if you got the maths right for the COM frame in the first place, it would have confirmed the Earth’s momentum in the observer’s frame remains zero throughout the elastic collision.
To set the record straight let me correct your mistake about the total momentum in the COM frame being mv instead of zero.
The velocity of the COM = mv/(M+m).
In the COM frame using the transformation v → v – mv/(M+m) :
Initial momentum of ball = m(v-mv/(M+m)) = mv - m²v/(M+m)
Initial momentum of Earth = -Mmv/(M+m)
Total momentum before collision = mv - m²v/(M+m) - Mmv/(M+m)
= v(m - (m² + Mm)/(M+m))
= v(m - m(M+m)/(M+m)) =0
= v(m – m) =0
Hence total momentum in the COM frame is zero before collision.
In the COM frame using the transformation -v → -v + mv/(M+m)
Final momentum of ball = m(-v+mv/(M+m)) = -mv + m²v/(M+m)
Final momentum of Earth = Mmv/(M+m)
Total momentum after collision = -mv + m²v/(M+m) + Mmv/(M+m)
= v(-m + (m² + Mm)/(M+m))
= v(-m + m(M+m)/(M+m)) =0
= v(-m + m) =0
Hence total momentum in the COM frame is zero after collision.
Your incorrect COM frame would result in the Earth acquiring momentum before the collision has even occurred in the observer’s frame of reference.
