Question

How to solve this question?

Answer 1

a) Not answer
b) not answered
c) `L/Msqrt(k(M+m)`
d)`2L`
Read disclaimer

Explanation:

Disclaimer: I'm fairly sure my method is not that expected from the question, but I found it interesting and wanted to share my attempt anyway. I think its wrong because I effectively skipped parts a and b. Any feedback on this would be great!

Assumptions I've made which might be wrong:

• all the energy transferred in the spring is transferred into kinetic energy for the marble and piston when the piston returns to equilibrium
• the marble and piston travel together as a single particle until the piston returns to equilibrium piston, then the marble is projected off.

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Consider the problem in stages.

`"Energy in stretching the string"=1/2kL^2`

Due to the conservation of energy, this will all be transformed to kinetic energy when the piston returns to `x_0`, its starting position.

This is the kinetic energy possessed by the whole system, this being the piston and marble.

Let `x` be the final speed of the marble and piston combined.

`E_k=1/2(M+m)x^2`

`1/2kL^2=1/2(M+m)x^2`

`x^2=(kL^2)/(M+m)`

`color(blue)(x=sqrt((kL^2)/(M+m)`

Now, consider when the marble slips from the piston.

The piston will be stationary at the end, so has a final velocity of 0.
We can find the final speed of the marble using the conservation of momentum.

From conservation of momentum
Total momentum before = total momentum after

`(M+m)sqrt((kL^2)/(M+m))=Mv`

`Mv=sqrt((M+m)^2)sqrt((kL^2)/(M+m))`

`=sqrt((kL^2(M+m)^cancel2)/cancel(M+m))`

`M^2v^2=kL^2(M+m)`

`v^2=L^2/M^2k(M+m)`

`color(blue)(v=L/Msqrt(k(M+m))`

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for part d), we will do the inverse.

Let the marble be projected off at speed `2v`

From conservation of momentum
Momentum before=momentum after

`2Mv=x(M+m)`

`2Lsqrt(k(M+m))=x(M+m)`

`color(blue)(x=(2Lsqrt(k(M+m)))/(M+m)`

Now, we'll use our energy idea from earlier to find our new length back for the spring, `L_1`

`KE=1/2(M+m)((2Lsqrt(k(M+m)))/(M+m))^2`

`=cancel(M+m)/2*(4L^2kcancel((M+m)))/cancel((M+m)^2)`

`=2kL^2`

`E_"pot" " in spring"=1/2kL_1^2`

By conservation of energy;

`1/2cancelkL_1^2=2cancelkL^2`

`L_1^2=4L^2`

`color(blue)(L_1=2L`

So to get double the speed out, double the distance you pull the spring. (rather boring final answer, if I do say so).

Answer 2

See below.

Explanation:

Movement equation

`k(x-x_0) + (m+M)d^2/(dt^2)(x-x_0) = 0`

Multiplying by `d/(dt)(x-x_0)`

`1/2 k d/(dt)(x-x_0)^2+(m+M)1/2 d/(dt)(d/dt(x-x_0))^2 = 0`

Calling `x-x_0 = y` and `d/(dt)(x-x_0) = v` we have after integration

`1/2 y^2+1/2(m+M)v^2 = C`

this relationship works just until the marble loses contact with the piston.

Also integrating directly the movement equation

`k y +(m+M) ddot y = 0`

which is a harmonic movement equation results

`y = y_0 sin(sqrt(k/(m+M))t+phi_0)`

and

`v = dot y = sqrt(k/(m+M))y_0 cos(sqrt(k/(m+M))t+phi_0)`

Answer 3

See parts (c) and (d) as a separate answer.

Explanation:

(a) Keeping in view the given figure, and considering `x=x_0` as the origin, equation of motion for the system can be obtained from Newton's Second Law of Motion and Hook's Law as

`F_"net"=(M+m)(d^2x)/dt^2=-kx`

Rewriting it as a second order differential equation of SHM.

`(d^2x)/dt^2+(k)/(M+m)x=0` ......(1)

(b) Above equation has a general sinusoidal solution as

`x=Asin\ omegat+B cos\ omega t` ......(2)
where `omega=sqrt((k)/(M+m))`

Now velocity is given by

`dot x=omegaAcosomegat-omegaBsinomegat` ......(3)

Displacement at `t=0` is `=-L`. From (2) we get

`-L=Asin\ (omegaxx0)+B cos\ (omega xx0)`
`=>B=-L`

Velocity at `t=0` is `=0`. From (3) we get

`0=omegaAcos(omegaxx0)-omegaBsin(omegaxx0)`
`=>A=0`

Solution (2) becomes

`x=-L cos\ omega t`

Velocity becomes

`dot x=omegaLsinomegat`

It is clear that equation of motion and its solution are valid so long as piston and marble move together as single entity.

Answer 4

From other posted solution we got

Position

`x=-L cos\ omega t` ......`(i)`

Velocity

`dot x=omegaLsinomegat` ........`(ii)`

Explanation:

(c) Let velocity of the piston marble system be maximum at `t=T`. After this point, piston starts to slow down, the contact between the two is lost and marble carries on its forward motion with this constant velocity. Due to presence of `sin omegat` factor in the expression for velocity, maximum velocity is reached when

`sinomegaT=1`
`=>omegaT=pi/2`

`:.` from `(ii)`

`dotx_max=omegaL`
`=>dotx_max=sqrt(k/(m+M))L` ......`(iii)`

Inserting value of `omegaT` in expression for position we get

`x(T)=-L cos\ (pi/2)`
`x(T)=0=x_0`

(d) From `(iii)` we see that

`dot x_maxpropL`

Therefore, in order to achieve twice the speed of marble on separation the piston must be pushed/pulled back twice the initial value.

`=2L`