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24) ONE I 10-Kg FTBALL LINGMRN S FUNNINO D HE RUAT AT 1,75 m Ly toWARD...
A 10 kg penguin with an initial velocity of 6.0 m/s toward the
east runs onto a large area of level, frictionless ice. As the
penguin slides across the ice, it is pushed by the wind with a
force that is constant in magnitude and direction. The figure shows
the position of the penguin, at 1.0 s intervals, as it slides on
the ice; the positive direction of the x axis is toward
the east. The penguin first makes contact...
A racquet ball with mass m = 0.252 kg is moving toward the wall
at v = 18.2 m/s and at an angle of θ = 25° with respect to the
horizontal. The ball makes a perfectly elastic collision with the
solid, frictionless wall and rebounds at the same angle with
respect to the horizontal. The ball is in contact with the wall for
t = 0.06 s.
1)
What is the magnitude of the initial momentum of the racquet...
Two vehicles are approaching an intersection. One is a 2600 kg pickup traveling at 16.0 m/s from east to west (the −x- direction), and the other is a 1600 kg sedan going from south to north (the +y− direction at 23.0 m/s ). a. Find the x -component of the net momentum of this system. b. Find the y-component of the net momentum of this system. c. What is the magnitude of the net momentum? d. What is the direction...
Two vehicles are approaching an intersection. One is a 2400 kg pickup traveling at 13.0 m/s from east to west (the −x- direction), and the other is a 1300 kg sedan going from south to north (the +y− direction at 21.0 m/s ). Part A Find the x -component of the net momentum of this system. Part B Find the y-component of the net momentum of this system. Part C What is the magnitude of the net momentum? Part D...
One particle of mass m1 = 1.00 kg with an initial velocity of 5.40 m/s i collides with a second particle of mass m2 = 2.00 kg that is initially at rest. After the collision mı goes off with a final speed of 4.20 m/s in a direction 32.0° above i. V 5.4 ms (a) Find the final velocity (in terms of magnitude AND direction) of m2. agnitude AND direction) of m. Vi = 4.2 m/s (HINT: Find the direction...
A 76.7 kg linebacker (X) is running at 6.83 m/s directly toward the sideline of a football field. He tackles a 87.8 kg running back (O) moving at 9.49 m/s straight toward the goal line, perpendicular to the original direction of the linebacker. As a result of the collision, both players momentarily leave the ground and go out-of-bounds at an angle o relative to the sideline, as shown in the diagrams. Before impact After impact What is the common speed...
A6.65 kg bowling bal moving at 10.0 m/ s colides with a 1.60 kg bowling pin, scattering It with a speed of 8.00 m/s and at an angle of 36.0% with respect to the initial direction of the (a) Calculate the final velocity (magnitude in m/s and direction in degrees velocity (magnitude in m/s and direction in degrees counterclockwise from the original direction) of the bowling ball magnitude m/s direction counterdlockwise from the original direction of the bowling ball (b)...
A 78.5-kg linebacker ("X") is running at 7.19 m/s directly toward the sideline of a football field. He tackles a 96.9-kg runn8ing back ("O") moving at 9.27 m/s straight toward the goal line, perpendicular to the original direction of the linebacker. As a result of the collision both players momentarily leave the ground and go out-of-bounds at an angle phi relative to the sideline, as shown in the diagrams below. What is the concern speed of the players, immediately after...
1. A 10,000 KG truck is traveling at +20 m/s. What would
happen to the momentum of the truck if it increases in velocity in
the same direction?
2. A 120 KG rugby player is running toward another player at 5
m/s. How much force needs to be applied over one second in order to
bring him to a stop?
3. if the acceleration of an object decreases, what happens to
the inertia?
A 10,000kg truck is traveling at +20m/s....
4. A 110 kg ice hockey player skates at 3.0 m/s toward a railing at the edge of the ice and then stops himself by grasping the railing with his outstretched arms. During the stopping process, his center of mass moves 30 cm toward the railing. (a) What is the change in the kinetic energy of his center of mass during this process? (b) What average force must he exert on the railing? Answer | (a) -495 J; (b) 1650...