Elastic Collision?

2 ANSWERS

1. 
   

   In an elastic collision both kinetic energy and momentum are conserved.
   
   kinetic energy before = kinetic energy afterwards
   
   v = velocity of first object before collision = 5 m/s east
   
   u = velocity of first object after collision
   
   w = velocity of second object after collision
   
   m = mass of first object = 4 kg
   
   n = mass of second object = 6 kg
   
   (1/2)mv^2 = (1/2)mu^2 + (1/2)nw^2
   
   mv^2 = mu^2 + nw^2
   
   4(5^2) = 4u^2 + 6w^2
   
   100 = 4u^2 + 6w^2
   
   50 = 2u^2 + 3w^2
   
   Momemtum must be conserved. Since there is no movement in the N-S direction, this component of the momentum must be 0. Plus the component in E-W must equal that before the collision.
   
   Momentum before = mv
   
   After collision the first object is moving South of East at 30 degrees.
   
   p(N-S) = m*u*cos(30)
   
   p(E-W) = m*u*sin(30)
   
   For the second object if it moves off at an angle A:
   
   q(N-S) = n*w*cos(A)
   
   a(E-W) = n*w*sin(A)
   
   The N-S components must be equal so:
   
   m*u*cos(30) = n*w*cos(A)
   
   wcos(A) = (m*u)cos(30)/(n) = (4)(u)[SQRT(3)/2] / (6)
   
   wcos(A) = (u/3)SQRT(3)
   
   The momentum before must equal the sum of the E-W after:
   
   mv =  m*u*sin(30) + n*w*sin(A)
   
   4(5) = 4u(1/2) + 6wsin(A)
   
   20 = 2u + 6wsin(A)
   
   10 = u + 3wsin(A)
   
   This gives us three equations:
   
   50 = 2u^2 + 3w^2................. w^2 = [50 - 2u^2]/3
   
   wcos(A) = (u/3)SQRT(3) .... cos(A) = (u/w)SQRT(3)/3
   
   10 = u + 3wsin(A) ................ sin(A) = (10 - u)/(3w)
   
   Since we want to find u, we can use the second two and the fact sin^2 + cos^2 =1  to get an equation in just u and w. We can combine this with equation 1 which only uses u and w to eliminate w and get a solution for u.
   
   sin^2(A) + cos^2(A) = 1
   
   [(10 - u)/(3w)]^2 + [(u/w)SQRT(3)/3]^2 = 1
   
   100 - 20u + u^2 + 3u^2 = 9w^2
   
   From the conservation of energy equation:
   
   50 = 2u^2 + 3w^2 or 9w^2 = 150 - 6u^2
   
   100 - 20u + u^2 + 3u^2 = 150 - 6u^2
   
   10u^2 - 20u - 50 = 0
   
   u^2 - 2u - 5 = 0
   
   u = [2 +/- SQRT(4 + 20] / 2
   
   u = 1 +/- SQRT(6)
   
   u = 3.45 m/s

   Report (0) (0)  |   earlier  

2. 
   

   I don't think so...
   
   You don't need all that...PLUS there is a math error in it...
   
   The momentum equation in the EAST-WEST direction should be COSINE Not SINE.  The answer will thus be wrong.
   
   I could have an error somewhere, too...it is easy to make aritmatic errors when doing these.  If you follow my solution, you will not need to solve a quadratic either.  Use the method you find easiest to do on your own.  The physics is the same.  The order in which we did things is a bit different.
   
   1) Conserve momentum (in the vertical, i.e., North-South) and horizontal (i.e., East-West) directions...
   
   Call x the angle that the 6 kg mass makes with the East-West axis.
   
   NoSo dir: (Conservation of momentum)...
   
   4 Vsin(30) = 6vsin(x)  where V  velocity of 4 kg mass after collision and v is the 6 kg mass's velocity. And simplifying...
   
   (1/3) V = vsin(x)
   
   EaWe dir: (Conservation of momentum)...
   
   4 Vcos (30) = 6vcos(x)...so we have
   
   (1/3) V cos(30) = vcos(x) and so,
   
   (1/3)Sqrt(3)V = vcos(x)
   
   Now divide  (1/3) V = vsin(x) by (1/3)Sqrt(3)V = vcos(x) and get..
   
   tan(x) = SQRT(3) and x=60 degrees
   
   [Note: When we have a 2D system in an ellastic collision, the two masses will form a right angle when energy is conserved]
   
   The energy at the start is 1/2 m 5^2 = 50 J and after it is also 50J
   
   Take (1/3) V = vsin(x) with x=60 to get v=2/9 SQRT(3) V.  The Kinetic energy after is...
   
   1/2 4 V^2 + 1/2 6 [(2/9) * SQRT(3) V]^2 or
   
   2 V^2 + (4/9) V^2 = 50J so that V=4.52 m/s
   
   The other mass has a velocity of 1.74 m/s
   
   -Fred

   Report (0) (0)  |   earlier