(a) Calculate the rotational kinetic energy (in J) of Jupiter on its axis. (Assume its mass to be 1.90 ✕ 1027 kg, the period about its axis to be 9.84 h, and its diameter to be 1.43 ✕ 105 km.)_________J (b) What is the rotational kinetic energy (in J) of Jupiter in its orbit around the Sun? (Assume its distance from the sun to be 7.78 ✕ 108 km and its period about the sun to be 4340 days.) _________J (a) Calculate the rotational kinetic energy (in J) of Jupiter on its axis. (Assume its mass to be 1.90 x 102 kg, the period about its axis to be 9.84 h, and its diameter to be1.43 x 105 km.)(b) What is the rotational kinetic energy (in J) of Jupiter in its orbit around the Sun? (Assume its distance from the sun to be 7.78 x 10° km and its period about the sun to be4340 days.)

According to question we need to find rotational kinetic energy.

Calculate the rotational kinetic energy (in J) of Jupiter on its axis. (Assume its mass to be 1.90 ✕ 1027 kg, the period about its axis to be 9.84 h, and its diameter to be 1.43 ✕ 105 km.) _________J (b) What is the rotational kinetic energy (in J) of Jupiter in its orbit around the Sun? (Assume its distance from the sun to be 7.78 ✕ 108 km and its period about the sun to be 4340 days.) _________J

Calculate the rotational kinetic energy (in J) of Jupiter on its axis. (Assume its mass to be 1.90 ✕ 1027 kg, the period about its axis to be 9.84 h, and its diameter to be 1.43 ✕ 105 km.) _J (b) What is the rotational kinetic energy (in J) of Jupiter in its orbit around the Sun? (Assume its distance from the sun to be 7.78 ✕ 108 km and its period about the sun to be 4340 days.) _J

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter7: Gravity

Section: Chapter Questions

Problem 38PQ

See similar textbooks

Similar questions

Model the Moons orbit around the Earth as an ellipse with the Earth at one focus. The Moons farthest distance (apogee) from the center of the Earth is rA = 4.05 108 m, and its closest distance (perigee) is rP = 3.63 108 m. a. Calculate the semimajor axis of the Moons orbit. b. How far is the Earth from the center of the Moons elliptical orbit? c. Use a scale such as 1 cm 108 m to sketch the EarthMoon system at apogee and at perigee and the Moons orbit. (The semiminor axis of the Moons orbit is roughly b = 3.84 108 m.)
Suppose the gravitational acceleration at the surface of a certain moon A of Jupiter is 2 m/s2. Moon B has twice the mass and twice the radius of moon A. What is the gravitational acceleration at its surface? Neglect the gravitational acceleration due to Jupiter, (a) 8 m/s2 (b) 4 m/s2 (c) 2 m/s2 (d) 1 m/s2 (e) 0.5 m/s2
Math Review (a) Convert 47.0 to radians, using the appropriate conversion ratio. (b) Convert 2.35 rad to degrees. (c) If a circle has radius 1.70 m, what is the are length subtended by a 47.0 angle? (See Sections 1.5 and 7.1.)
Calculate the angular momentum (in kg · m2/s) of Mars in its orbit around the Sun. (The mass of Mars is 6.420 ✕ 1023 kg, the orbital radius is 2.279 ✕ 108 km and the orbital period is 1.88 y.) Compare this angular momentum with the angular momentum of Mars on its axis. (The radius of Mars is 3.396 ✕ 103 km and the rotation period is 24.62 h.)
(a) Calculate the rotational kinetic energy (in J) of Venus on its axis. (Assume its mass to be 4.90 ✕ 1024 kg, the period about its axis to be 5830 h, and its diameter to be 12100 km.) J (b) What is the rotational kinetic energy (in J) of Venus in its orbit around the Sun? (Assume its distance from the sun to be 1.08 ✕ 108 km and its period about the sun to be 225 days.) J
An asteroid, whose mass is 2.0 × 10-4 times the mass of Earth, revolves in a circular orbit around the Sun at a distance that is 2.7 times the Earth's distance from the Sun. (a) Calculate the period of revolution of the asteroid in years. (b) What is the ratio of the kinetic energy of the asteroid to the kinetic energy of Earth? (a) Number i Units (b) Number i Units
The earth moves about the sun in an elliptical orbit where angular momentum about the sun is conserved. Earth's distance from the sun ranges from 0.983 AU (at perihelion, the closest point) to 1.017 AU (at aphelion, the farthest point). The AU is a unit of distance. If the orbital speed of Earth at aphelion is v, what is the orbital speed of Earth at perihelion?
A satellite of mass m = 3.94e + 3 kg is in circular orbit around the Earth, and the radius of this orbit is ro = 1.04e + 4 km. Take the mass of the Earth to be ME = 6 × 1024 kg. The satellite is subject to a small frictional force of magnitude f = 0.0269 N due to the outer atmosphere of the Earth. Because of this force, the satellite will slowly spiral back towards Earth. What is the change in radius Ar of the satellite after one revolution (assuming the starting radius is ro as given above)? Hint: Assume that the change in radius is slow enough that at any instant of the orbit the satellite can be considered to be undergoing circular motion. Also, since this change in radius will be small, in the sense that A« 1, you may (and should) use a Taylor expansion to find a close (i.e., first-order) approximation to the exact answer. TO Note: You should take Newton's constant to be G = 6.674 × 10-11 Nkg-2m².
Uranus has a mass of 8.68 x 1025 kg and a radius of 2.56 x 10 m. Assume it is a uniform solid sphere. The distance of Uranus from the Sun is 2.87 x 10¹2 m. (Assume Uranus completes a single rotation in 17.3 hours and orbits the Sun once every 3.08 x 104 Earth days.) (a) What is the rotational kinetic energy of Uranus on its axis? J (b) What is the rotational kinetic energy of Uranus in its orbit around the Sun? J
Problem 6 : Estimate the kinetic energy of the Mars with respect to the Sun as the sum of the terms, that due to its daily rotation about its axis, and that due to its yearly revolution about the Sun. [Assume the Mars is a uniform sphere with mass = 6.4×1023 kg , radius = 3.4×106 m , rotation period 24.7 h , orbital period 686 d and is 2.3×108 km from the Sun.] Express your answer to two significant figures and include the appropriate units. (Kdaily+Kyearly=?)
Two satellites travel along the same circular orbit of radius 4.7*10^4 km centred at the Earth. The distance between the satellites, measured along their orbit, is 59, 000 km. Determine the angular separation of the two satellites in radians.
(a) Convert 34.0° to radians, using the appropriate conversion ratio. rad (b) Convert 2.32 rad to degrees. (c) If a circle has radius 1.10 m, what is the arc length subtended by a 34.0° angle? Submit Answer