Understanding the Physics Behind a Vertical String's Wave Pulse Travel Time?

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A vertical rope of mass m and length L is analyzed for the travel time of a transverse wave pulse. The initial approach to find the wave speed using the tension and mass per unit length is noted, but the calculation of time requires integration due to the variable speed along the rope. The correct expression for wave speed is derived as a function of distance from the bottom, leading to the need for integration to determine the total travel time. The integration ultimately shows that the time taken for the wave pulse to travel the length of the rope is t = 2(L/g)^(1/2). Clarification is sought on the tension formula used in the calculations.
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A rope of mass m and length L is suspended vertically. Show that a transverse wave pulse will travel the length of the tope in a time t = 2(L/g)^1/2.

stuck... i tried:

v = (T/u)^1/2 ; where T = m(X/L)g and u = m/L

the X is the distance from the bottom of the string...

so i got v= (xg)^1/2

t= (L-X)/ (xg)^1/2

which i can't simplify to t = 2(L/g)^1/2.

Where did I go wrong here? logic is making sense to me but I am no getting the answer. thanks.
 
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You found v as of function of x correctly, but then just multiplied by the distance to find the time. Since v is not constant, you must integrate:
v = \frac{dx}{dt} = (xg)^{1/2}
t = \int_{0}^{L}\frac{dx}{(xg)^{1/2}}
 
can you please expain why T = m(X/L)g? Thanks!
 

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