A person drops a cylindrical steel bar (?=1.20×1011 Pa)(Y=1.20×1011 Pa) from a height of 2.202.20 m...

A person drops a cylindrical steel bar (?=1.500×1011 Pa) from a height of 2.50 m (distance...

A person drops a cylindrical steel bar (?=1.500×1011 Pa) from a height of 2.50 m (distance between the floor and the bottom of the vertically oriented bar). The bar, of length ?=0.710 m, radius ?=0.00700 m, and mass ?=1.500 kg , hits the floor and bounces up, maintaining its vertical orientation. Assuming that the collision with the floor is elastic and that no rotation occurs, what is the maximum compression Δ? of the bar? Use the gravitational acceleration ?=9.81 m/s2.

A person drops a cylindrical steel bar (Y = 9.00 × 1010 Pa) from a height...

A person drops a cylindrical steel bar (Y = 9.00 × 1010 Pa) from a height of 4.20 m (distance between the floor and the bottom of the vertically oriented bar). The bar, of length L = 0.880 m, radius R = 0.00600 m, and mass m = 1.100 kg, hits the floor and bounces up, maintaining its vertical orientation. Assuming the collision with the floor is elastic, and that no rotation occurs, what is the maximum compression of the...

A person drops a cylindrical steel bar (Y = 8.00 × 1010 Pa) from a height...

A person drops a cylindrical steel bar (Y = 8.00 × 1010 Pa) from a height of 3.20 m (distance between the floor and the bottom of the vertically oriented bar). The bar, of length L = 0.820 m, radius R = 0.00500 m, and mass m = 1.300 kg, hits the floor and bounces up, maintaining its vertical orientation. Assuming the collision with the floor is elastic, and that no rotation occurs, what is the maximum compression of the...

A person drops a cylindrical steel bar ( Y = 8.0 × 10 10 Pa )...

A person drops a cylindrical steel bar ( Y = 8.0 × 10 10 Pa ) from a height of 1.10 m (distance between the floor and the bottom of the vertically oriented bar). The bar, of length L = 0.67 m, radius R = 0.75 cm, and mass m = 1.80 kg, hits the floor and bounces up, maintaining its vertical orientation. Assuming the collision with the floor is elastic, and that no rotation occurs, what is the maximum...

A person drops a cylindrical steel bar (?=1.100×10^11 Pa) from a height of 4.00 m (distance...

A person drops a cylindrical steel bar (?=1.100×10^11 Pa) from a height of 4.00 m (distance between the floor and the bottom of the vertically oriented bar). The bar, of length ?=0.850 m, radius ?=0.00600 m, and mass ?=0.800 kg, hits the floor and bounces up, maintaining its vertical orientation. Assuming that the collision with the floor is elastic and that no rotation occurs, what is the maximum compression Δ? of the bar? Use the gravitational acceleration ?=9.81 m/s^2.

Question 1 (1 point) Which is not necessary in order to do work on an object...

Question 1 (1 point) Which is not necessary in order to do work on an object (use the scientific definition of work)? Question 1 options: There must be a change in momentum. A net force must be applied to the object. The object must undergo a displacement. A component of the force must be in the direction of motion. Question 2 (1 point) The change in gravitational potential energy for a 1.9 kg box lifted 2.2 m is: Question 2...