Ask Question
PhysicsPhysics
7 June, 19:50

You throw a ball of mass 1.0 kg straight up. You observe that it takes 3.4 s to go up and down, returning to your hand. Assuming we can neglect air resistance, the time it takes to go up to the top is half the total time, 1.7 s. Note that at the top the momentum is momentarily zero, as it changes from heading upward to heading downward.

+5
Answers (1)
  1. 7 June, 21:37
    0
    Incomplete question

    This is the complete question

    You throw a ball of mass 1 kg straight up. You observe that it takes 3.4s to go up and down, returning to your hand. Assuming we can neglect air resistance, the time it takes to go up to the top is half the total time, 1.7s. Note that at the top the momentum is momentarily zero, as it changes from heading upward to heading downward.

    (a) Use the momentum principle to determine the speed that the ball had just AFTER it left your hand.

    vinitial = ? m/s

    (b) Use the Energy Principle to determine the maximum height above your hand reached by the ball.

    h = ? m

    Explanation:

    Mass of object is 1kg

    Total time to and fro is 3.4s

    i. e the time to reach maximum height will be half of total time = 1.7s

    g=9.81m/s²

    Question 1

    We need the initial velocity

    Using the free fall body

    v=u-gt. Against gravity upward

    at maximum height the body comes to rest before returning back, then v=0 at maximum height

    The time to reach max height is 1.7s

    So, v=u-gt

    0=u-9.81*1.7

    0=u-16.68

    Therefore, u=16.68m/s

    The initial velocity after the ball left the hand is 16.68m/s

    Now, using the principle of momentum

    The weight of the object is

    W=mg=9.81*1

    W=-9.81N. Downward

    Then, the force that is needed to throw the body upward is equal to the weight

    ΣF = mg=W

    F=W=-9.81

    From momentum

    F = (mv-mu) / t

    Since at max height, v=0

    Ft=mv-mu

    -9.81*1.7=0-1*u

    -16.677=-u

    Therefore, u=16.68m/s as expected from the equation of motion

    Question 2.

    Maximum height reach by the ball

    Using equation of motion

    v²=u²-2gH

    0²=16.68²-2*9.81*H

    0=278.12-19.62H

    19.62H=278.12

    Then, H=278.12/19.62

    H=14.18m

    Now using, energy principle

    Energy is conserved

    i. e kinetic energy is equal to P. E energy when the body is free falling

    K. E = ½mv²

    P. E=mgh

    K. E=P. E

    ½mv²=mgh

    ½v²=gh

    v²=2gh

    h=v²/2g

    Then,

    h=16.68²/2*9.81

    h=14.18m

    As expected, same as the equation of motion ... So both momentum and conservation of energy can be apply to free falling body.
Know the Answer?
Not Sure About the Answer?
Get an answer to your question ✅ “You throw a ball of mass 1.0 kg straight up. You observe that it takes 3.4 s to go up and down, returning to your hand. Assuming we can ...” in 📙 Physics if there is no answer or all answers are wrong, use a search bar and try to find the answer among similar questions.
Search for Other Answers
You Might be Interested in
A car traveling in a straight line at an initial speed of 8.0 meters per second accelerates uniformly to a speed of 14 meters per second over a distance of 44 meters. What is the magnitude of the acceleration of the car?
Answers (1)
A pure musical torte causes a thin wooden panel to vibrate. This is an example of: A. An overtone B. Harmonics C. Resonance D. Interference
Answers (1)
Which of these rocks are formed by volcanic activity? select the two correct answers. a. limestone b. granite c. marble d. basalt e. sandstone
Answers (2)
What happens to the density of a substance as its temperature increases?
Answers (1)
A car starts moving from the position of rest with uniform acceleration of 8m/s^calculate the distance travelled by it during 10th minute of its motion.
Answers (1)
New Questions in Physics
Woman pulls a 6.87 kg suitcase, initially at rest, with a 29.2 N force along the handle at 57.7º. Friction pulls back at 12.7 N, and the suitcase moves 5.93 m. What is its final speed? (Unit = m/s)
Answers (1)
Suppose you know a golf ball's horizontal velocity and the time it has traveled through the air. how could you calculate how far the ball traveled
Answers (1)
What is a radio interferometer? a device for correcting chromatic aberration in radio telescopes a device for absorbing and transmitting radio waves a network of several radio telescopes wired together a radio communication network joining several
Answers (1)
In which galaxy is our solar system located? a. milky way b. ngc 4414 c. andromeda d. small magellanic cloud
Answers (2)
Two astronauts, of masses 60 kg and 80 kg, are initially right next to each other and at rest in outer space. They suddenly push each other apart. How far has the heavier astronaut moved when the lighter astronaut has moved 12 m
Answers (1)
Home » Physics » You throw a ball of mass 1.0 kg straight up. You observe that it takes 3.4 s to go up and down, returning to your hand. Assuming we can neglect air resistance, the time it takes to go up to the top is half the total time, 1.7 s.
Sign Up Forgot Password?