To escape Earth’s gravitational field, a rocket must be launched with an initial velocity called the escape velocity. A rocket launched from the surface of Earth has velocity v (in miles per second) given by

   

where v_0 is the initial velocity, r is the distance from the rocket to the center of Earth, G is the gravitational constant, M is the mass of Earth, and R is the radius of Earth (approximately 4000 miles).

(a) Find the value of v_o for which you obtain an infinite limit for r as v approaches zero. This value of v_o is the escape velocity for the earth.

(b) A rocket launched from the surface of the moon has velocity v (in miles per second) given by

   

Find the escape velocity for the moon.

(c) A rocket launched from the surface of a planet has velocity v (in miles per second) given by

   

 Find the escape velocity for this planet. Is the mass of this planet larger or smaller than that of Earth? (Assume that the mean density of this planet is the same as that of Earth.)

1. The escape speed V is the minimum speedneeded to project a mass m upward from the surface of another
mass M (such as a planet, asteroid, or star). It is given by
v =√2GM
R

(a)Calculate the escape velocity v from the surface of the Sun.

USE:

M =1.99 × 10³⁰ kg ,

G=gravitational constant 6.67 x10^-11 N*m²/kg²

R =6.96 × 10⁸m.

5) A neutron star is a burnt out star in which gravitational forcestake over. The gravity condenses all the matter to such an extentthat all protons and electrons fuse together, creating neutrons.Thus, the star consists of one giant nucleus containing onlyneutrons. The neutron star at the center of the Crab Nebula has amass of approximately 1.4 times that of our sun, and a diameter ofonly 12.2 miles. It also spins at a rate of 4.81radians/second.
a) How long does it take for this neutron star to complete onerotation?
b) If you were standing on the surface of this star, at itsequator, how fast would you be going? Give your answer in bothmiles/hour, and also as a ratio compared to how fast you’rerotating through space if you stand on the surface of the Earth atthe equator.
c) What is the density of the matter in this star? (Give youranswer in both kilograms per cubic centimeter and pounds per squareinch.)
d) The escape velocity of the Earth is about 25,000 miles/hour. Ifa rocket was launched with this velocity from the surface of thisneutron star, how far would it get from the surface?
e) What is the escape velocity for this star? (Calculate it fromfirst principles. Don’t just use the formula. Give your answer inmiles/hour.)
f) At what height would a satellite around this star have to be, inorder to be in a geosynchronous orbit with it?
g) How fast would a satellite in geosynchronous orbit about thisstar be traveling? (Give your answer in miles/hour.)

The Saturn V, developed at NASA Marshall Space Flight Center (MSFC) under the direction of Wernher Von Braun, was the largest in a family of liquid-propellant rockets that solved the problem of getting to the moon. A total of thirty-two (32) Saturns of all types were launched, not one failed. The three stage Saturn V was taller than a 36 story building and was the largest, most powerful rocket ever launched. Fully loaded with the Apollo spacecraft onboard, it had a mass of 6.8 million pounds. This was still no match; however, for the five powerful rockets that controlled the first stage with 33,560,000 newtons of thrust upwards. Using this information find the net acceleration (m/s2) of the Saturn V rocket. Assume that there is no change in mass,the rocket stays completely perpendicular, and there is no drag on the rocket. This takes place on planet earth with g=9.8 m/s^2.