A particle is at the position (x,y,z)=(1.3,2.5,3.3)m(x,y,z)=(1.3,2.5,3.3)m. It is traveling with a vector velocity (−5.1,3.0,−3.1)m/s(−5.1,3.0,−3.1)m/s. Its...

At time t = 4 sec, a particle of mass M = 4.5 kg is at...

At time t = 4 sec, a particle of mass M = 4.5 kg is at the position (x,y,z) = (4,4,6) m and has velocity (2,1,-2) m/s. 1)What is the x component of the particle's angular momentum about the origin? 2)What is the y component of the particle's angular momentum about the origin? 3)What is the z component of the particle's angular momentum about the origin? 4)Now an identical particle is placed at (x,y,z) = (-4,-4,-6) m, with velocity (-2,-1,2)...

At time t = 11.5 sec, a particle of mass M = 5 kg is at...

At time t = 11.5 sec, a particle of mass M = 5 kg is at the position (x,y,z) = (4,4,6) m and has velocity (2,1,-2) m/s. 1) What is the x component of the particle's angular momentum about the origin? 2) What is the y component of the particle's angular momentum about the origin? 3) What is the z component of the particle's angular momentum about the origin? 4) Now an identical particle is placed at (x,y,z) = (-4,-4,-6)...

A 3.65 kg particle with velocity v→=(8.97m/s)î-(4.43m/s)ĵ is at x = 7.38 m, y = 5.02...

A 3.65 kg particle with velocity v→=(8.97m/s)î-(4.43m/s)ĵ is at x = 7.38 m, y = 5.02 m. It is pulled by a 2.09 N force in the negative x direction. About the origin, what are (a) the particle's angular momentum, (b) the torque acting on the particle, and (c) the rate at which the angular momentum is changing?

At time t = 0, a 4.0 kg particle with velocity v with arrow = (5.0...

At time t = 0, a 4.0 kg particle with velocity v with arrow = (5.0 m/s) i hat − (6.0 m/s) j is at x = 4.0 m, y = 2.0 m. It is pulled by a 6.0 N force in the negative x direction. (a) What is the angular momentum of the particle about the origin? (Express your answer in vector form.) (b) What torque about the origin acts on the particle? (Express your answer in vector form.)...

A particle of mass 2.00 kg moves with position r(t) = x(t) i + y(t) j...

A particle of mass 2.00 kg moves with position r(t) = x(t) i + y(t) j where x(t) = 10t2 and y(t) = -3t + 2, with x and y in meters and t in seconds. (a) Find the momentum of the particle at time t = 1.00 s. (b) Find the angular momentum about the origin at time t = 3.00 s.

A 3.1-kg block is traveling in the −x direction at 5.4 m/s, and a 0.9-kg block...

A 3.1-kg block is traveling in the −x direction at 5.4 m/s, and a 0.9-kg block is traveling in the +x direction at 3.1 m/s. (a) Find the velocity vcm of the center of mass. _____m/s (b) Subtract vcm from the velocity of each block to find the velocity of each block in the center-of-mass reference frame. 3.1-kg block ____m/s 0.9-kg block ____ m/s (c) After they make a head-on elastic collision, the velocity of each block is reversed (in...

A 4 kg ball moving at 14 m/s in southwest. What is the A) x- (east-)...

A 4 kg ball moving at 14 m/s in southwest. What is the A) x- (east-) component and B) y- (north-) component of the momentum vector of this ball? It collides with a stationary 6 kg ball. C) What is the magnitude of the momentum vector of this ball? After the collision, the 4 kg ball moves at 13.5 m/s, at an angle of 50 degrees from west to south. What is its D) x-component and E) y-component of the...

A 14.00 kg particle starts from the origin at time zero. Its velocity as a function...

A 14.00 kg particle starts from the origin at time zero. Its velocity as a function of time is given by v with arrow = 9t2î + 4tĵ where v with arrow is in meters per second and t is in seconds. (Use the following as necessary: t.) (a) Find its position as a function of time. r =________ (c) Find its acceleration as a function of time. a=_______m/s^2 ( (d) Find the net force exerted on the particle as...

particle of mass m in R3 has position function r(t) =<x(t),y(t),z(t)>. Given that the tangent vector...

particle of mass m in R3 has position function r(t) =<x(t),y(t),z(t)>. Given that the tangent vector r0(t) has a constant length of 5, please prove that at all t values, the force F(t) acting on the particle is orthogonal to the tangent vector

A particle with negative charge q and mass m = 2.50×10−15 kg is traveling through a...

A particle with negative charge q and mass m = 2.50×10−15 kg is traveling through a region containing a uniform magnetic field B⃗ =(−0.110T)k^. At a particular instant of time the velocity of the particle is v⃗ =(1.00×106m/s)(−3i^+4j^+12k^) and the force F⃗ on the particle has a magnitude of 2.40 N . 1. Determine the acceleration a⃗ of the particle. Find the x-component in m/s^2. Find the y-component in m/s^2 2. Determine the radius of curvature R of the circular...