What is the direction of the force of an object moving in a circle?

While on the moon, the Apollo astronauts enjoyed the effects of a gravity much smaller than that on Earth. If Neil Armstrong jum

Juliette [100K]

Answer:

The gravitational acceleration experienced was of 1.63m/s².

Explanation:

We know, from the kinematics equations of vertical motion that:

$v^{2} =v_0^2-2gy$

Solving for g, we get:

$g=-\frac{v^2-v_0^2}{2y}$

Since the final speed is zero, because Neil Armstrong came to a stop in his maximum height, we obtain:

$g=\frac{v_0^2}{2y}$

Finally, we plug in the given values of the initial speed and the maximum height:

$g=\frac{(1.51m/s)^2}{2(0.700m)}=1.63m/s^2$

This means that the gravitational acceleration experienced by Neil Armstrong in the moon, was of 1.63m/s².

6 0

2 years ago

How do scientist know that seismic waves can be either compressional or transverse

nasty-shy [4]

Hey there!

Scientists know that seismic waves can be either compressional or transverse because there are horizontal and vertical movements during an earthquake. Horizontal movements are compressional while vertical movements are transverse.

Thank you!

8 0

3 years ago

In getting ready to slam-dunk the ball, a basketball player starts from rest and sprints to a speed of 5.45 m/s in 3.02 s. Assum

vova2212 [387]

Recall that average velocity v is given by

v = ∆x/∆t

where ∆x is displacement and ∆t is time.

Under constant acceleration, average velocity is also equal to the average of the initial and final velocities,

v = (v₂ + v₁)/2

The player starts at rest, so v₁ = 0, and speeds up to v₂ = 5.45 m/s in a matter of ∆t = 3.02 s. So

∆x = (v₂ + v₁) ∆t / 2

∆x = (5.45 m/s) * (3.02 s) / 2