Answer:
a) 10.54 sec
b) 284.58 m
c) 29.406 m/s
d) 39.92 m/s
Explanation:
Given data:
velocity of spacecraft = 27.0 m/s
rate of free fall acceleration is 2.79 m/s^2
distance of moving aircraft from mooon surface is 155 m
a. from kinematic eqaution of motion we have
[tex]y = Vi\times t + (\frac{1}{2}) a\times t^2[/tex]
where y = 155 m
Vi = 0 as this relation is for vertical motion, so the 27.0 m/s is not included
and a = 2.79 m/s^2.
Solving for t we get
t = 10.54 sec
b.
we know that [tex]V = \frac{d}{t}[/tex]
[tex]d = v\times t [/tex]
[tex]= 27 \times 10.54 = 284.58 m[/tex]
c. from the kinematic formula
v = u + at
[tex]v = 0 + 2.79\times 10.57 [/tex]
v = 29.4066 m/a
d. [tex] v = \sqrt { 27^2 + 29.406^2}[/tex]
v = 39.92 m/s
Answer:
Answered
Explanation:
horizontal velocity v= 27.0 m/s
height of space craft = 155 m
rate of free fall acceleration on this airless moon is 2.79 m/s^2.
we know that
a) S= V×t+ 0.5at^2
h= 0×t+ 0.5×2.79t^2 [initial vertical velocity is zero]
155= 0.5×2.79t^2
⇒ t= 10.54 secs
this the the time that the box will take to reach the moon.
b) the horizontal velocity v= 27 m/s and t= 10.54 sec
therefore horizontal displacement d= 10.54×27= 284.58 m
c) for final vertical velocity
we can use the formula
(v_final)^2=( v_initial)^2+ 2×a×h
(v_final)^2=0^2+ 2×2.79×155
v_final= 29.40 m/s [this its vertical velocity when it strikes the surface]
d) speed with which the box strike the moon will be resultant of the final vertical and horizontal velocity vectors that
[tex]\sqrt{27^2+29.40^2}[/tex]
= 39.91 m/s
