2. Support the space shuttle is in orbit about the earth at 400 km above its surface. Determine the orbital speed and the orbital period of the space shuttle.
3.calculate the minimum velocity (escape speed) a spacecraft must have to escape the gravitational force of the planet earth. Mearth=5.972 x 10^24kg
4. Calculate the schwarzschild radius of a black hole with the mass of the sun.Mearth=5.972 x 10^24kg
Please post the other question separately. Thanks and good luck:)
2. Support the space shuttle is in orbit about the earth at 400 km above its...
The space shuttle typically travels in a circular orbit at an altitude of 500 km above the Earth's surface. The Earth itself has a radius of about 6400 km. The shuttle can travel in a circular orbit, at constant speed, without any need for the rocket engine to be on, if it travels at just the right speed (a) Given that the value of g is 8.50 m/s2 at an altitude of 500 km, determine the value of the shuttle's...
In a newly discovered exoplanetary system one planet orbits its star in 56 days with an average orbital radius of 107,588,122 kilometers. It is observed that another planet in the same system has orbital period of 373 days. What is its average orbital radius of the second planet? Express your answer in kilometers, use scientific notation and round the coefficient to two decimals. In a newly discovered exoplanetary system one planet orbits its star in 57 days with an average...
Suppose the space shuttle is in orbit 500 km from the Earth's surface, and circles the Earth about once every 90 min . a) Find the centripetal acceleration of the space shuttle in its orbit. b) Express your answer in terms of g, the gravitational acceleration at the Earth's surface.
The International Space Station typically travels in a circular orbit at an altitude of 400 km above the Earth's surface. The Earth itself has a radius of about 6400 km. Assume that the space station travels in a circular orbit at constant speed (this is a perfectly reasonable assumption). A. Given that the value of g is 8.68m/s28.68m/s2at an altitude of 400 km, determine the value of the space station's speed in its circular orbit. _______ m/s B. At this...
1. An international space station in the circular orbit at 5500 km above the Earth surface needs to change its orbit to escape from cosmic debris. Find the new orbital altitude for two possible orbits: a) where its speed is increased v=1.1vo or b) its period: is decreased T-0.9T.
A satellite is in circular orbit at an altitude of 1500 km above the surface of a nonrotating planet with an orbital speed of 3.9 km/s. The minimum speed needed to escape from the surface of the planet is 9.6 km/s, and G = 6.67 × 10-11 N · m2/kg2. The orbital period of the satellite is closest to 54 min.37 min.49 min.43 min.60 min.
The space shuttle releases a satellite into a circular orbit 640 km above the Earth. Part A How fast must the shuttle be moving (relative to Earth) when the release occurs? v = m/s
QUESTION 17 The International Space Station which presently has mass of about 420,000 kilograms, maintains an orbit with an altitude of between 330 and 435 kilometers (205 and 270 miles respectively) above the Earth surface by means of re-boost maneuvers using the engines of the Zvezda module or visiting spacecraft to compensate for 2 km/month orbital decay due to the atmospheric drag. Calculate the following for the low orbit of the ISS (330 kilometers above the Earth surface), assuming that...
4. An astronaut whose height h is 1.70 m floats feet "down" in an orbiting space shuttle at a distance center of Earth. 6.77 x 10° m from the (a) What is the dif her feet and at her head? ference in the gravitational acceleration at (b) If the astronaut is now feet "down" at the same orbital radius r of 6.77 x 10° m about a black hole of mass M1.99 x 10" kg (which is 10 times our...
The space station orbits Earth about 400 km above the surface of Earth (NASA.gov). At this height the force of gravity from Earth is only about 10% less than on the surface of Earth. Using the concepts of circular motion and gravitational forces explain the following: 1. Why does the space station not fall down? 2. Why do the astronauts float inside the space station?