Answer:
True
Explanation:
We need to know the net acceleration of Captain Gravity, since it will depend on it to be saved from being swallowed by the black hole:
[tex]a_{net}=a_b+a_c\\a_{net}=20\frac{mi}{h^2}-30\frac{mi}{h^2}\\a_{net}=-10\frac{mi}{h^2}[/tex]
Where [tex]a_b[/tex] is the acceleration with which Captain Gravity is being pulled into the black hole and [tex] a_c[/tex] is the deceleration due to his thrusters.
The captain will be swallowed if the distance necessary for him to decelerate until he reaches a speed equal to 0 is greater than 300 miles, since this is his distance to the black hole. Then using the kinematic equations we can know the value of this distance d:
[tex]v_f^2=v_i^2+2ad[/tex]
Rewriting for d:
[tex]2ad=v_f^2-v_i^2\\d=\frac{v_f^2-v_i^2}{2a}\\d=\frac{0-(100\frac{mi}{h})^2}{2(-10\frac{mi}{h^2})}\\d=\frac{-10000\frac{mi}{h}}{-20\frac{mi}{h^2}}=500mi[/tex]
Since the required distance [tex]d[/tex] is greater than the distance [tex]x[/tex], unfortunately our gravity captain will get sucked into the black hole.
