6) Find the force the sun exerts on a planet, Their masses are 2 x 10³⁰...
6) Find the force the sun exerts on a planet, Their
masses are 2 x 10³⁰ kg and 6 x 10²⁴ kg and the distance
between them is 150 million kilometers [don't forget to state the
direction of the forced]
Homework Answers
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6) Find the force the sun exerts on a planet, Their
masses are 2 x 10³⁰...
Find the force a 2 kg ball exerts on a 6 kg ball, if their centers...
Find the force a 2 kg ball exerts on a 6 kg ball, if their centers are 1.5 m apart [don't forget to state the direction of the force].
A dwarf planet with an average orbital distance of 4.14 x 10° kilometers is kept in...
A dwarf planet with an average orbital distance of 4.14 x 10° kilometers is kept in its orbit by 6.94 x 101 Newton force exerted on it by the Sun. MSun = 1.99 x 1030 kg. MFarth 5.97 x 1024 kg. What is the mass of that planet? kilograms (use scientific notation and round the coefficient to two decimals). A. В. How many Earth masses is that equivalent to? (use scientific notation and round the coefficient to two decimals). An...
Astronomy helper Create an application that displays the following menu: select a planet 1. Mercury 2....
Astronomy helper Create an application that displays the following menu: select a planet 1. Mercury 2. Venus 3. Earth 4. Mars 5. exit the program Enter your selection. When the user selects a planet from the menu, the program should display data about the planet's average distance from the sun, the planet's surface temperature. Use the following data in your program: Mercury Average distance from the sun ---------- 57.9 million kilometers Mass---------------3.31 x 10^23kg surface temperature------------ -173 to 430 degrees...
Find the force of gravity býtween a object (mass = 9.0 kg) and another planet (mass=8.6*10^...
Find the force of gravity býtween a object (mass = 9.0 kg) and another planet (mass=8.6*10^ 23 kg) when the planet at its closest to Earth dis * tan c * e = 9.2x 10^ 10 m) . Express your answer to two significant figures and include the appropriate units. Using the formula for gravity, find the force of gravity on a 6.1 kg mass at Earth's surface. (The mass of Earth of 6*10^ 24 kg , and its radius...
planet X travels in a circular motion orbit around the Sun. The radius of Planet X...
planet X travels in a circular motion orbit around the Sun. The radius of Planet X is twice that of Earth. The year on Planet X is 540 Earth years. The mass of Planet X is half that of Earth. The mass of the sun is 1.99*10^30 kg. The Earth's orbital distance from the Sun is 1.50*10^11 m.
Problem 3.13 A planet of mass 3 x 104 kg is at location <6 x 101,...
Problem 3.13 A planet of mass 3 x 104 kg is at location <6 x 101, s 101, 0 m. A star of mass 9 x 100 kg is at location <3 x 1011 8 x 10, 0> m. wil be useful to draw a diagram of the situation, including the relevant vectors (a) What is the relative position vector 7 pointing from the planet to the star? (b) What is the distance between the planet and the star? 1기...
During a solar eclipse the Moon is positioned directly between Earth and the Sun. Find the...
During a solar eclipse the Moon is positioned directly between Earth and the Sun. Find the magnitude of the net gravitational force acting on the Moon then, due to both Earth and the Sun. The masses of the Sun, Earth, and the Moon are 1.99 x100 kg, 5.98 x1024 kg, and 7.36 x 1022 kg, respectively. The Moon's mean distance from Earth is 3.84 × 108 m, and Earth's mean distance from the Sun is 1.50 x 1011 m. The...
7) Given the mass of the sun (m,-1.99 x 1030 kg ) and the mass of...
7) Given the mass of the sun (m,-1.99 x 1030 kg ) and the mass of the earth (me-5.98 x 1024 kg) and the distance between them (150 billion meters), find the amount of charge required on both the sun and earth to exactly balance the attractive gravitational force.
If the gravitational force is 12663 N between a satelite with a mass of 11 x...
If the gravitational force is 12663 N between a satelite with a mass of 11 x 10^2 kg and a planet with a mass of 2 x 10^20 kg, find the distance between them
Learning Goal: To understand Newton's law of gravitation and the distinction between inertial and gravitational masses....
Learning Goal: To understand Newton's law of gravitation and the distinction between inertial and gravitational masses. In this problem, you will practice using Newton's law of gravitation. According to that law, the magnitude of the gravitational force Fg between two small particles of masses m1 and m2 separated by a distance r, is given by m1m2 T2 where G is the universal gravitational constant, whose numerical value (in SI units) is 6.67 x 10-11 Nm2 kg2 This formula applies not...
A dwarf planet with an average orbital distance of 4.14 x 10° kilometers is kept in its orbit by 6.94 x 101 Newton force exerted on it by the Sun. MSun = 1.99 x 1030 kg. MFarth 5.97 x 1024 kg. What is the mass of that planet? kilograms (use scientific notation and round the coefficient to two decimals). A. В. How many Earth masses is that equivalent to? (use scientific notation and round the coefficient to two decimals). An...
Problem 3.13 A planet of mass 3 x 104 kg is at location <6 x 101, s 101, 0 m. A star of mass 9 x 100 kg is at location <3 x 1011 8 x 10, 0> m. wil be useful to draw a diagram of the situation, including the relevant vectors (a) What is the relative position vector 7 pointing from the planet to the star? (b) What is the distance between the planet and the star? 1기...
During a solar eclipse the Moon is positioned directly between Earth and the Sun. Find the magnitude of the net gravitational force acting on the Moon then, due to both Earth and the Sun. The masses of the Sun, Earth, and the Moon are 1.99 x100 kg, 5.98 x1024 kg, and 7.36 x 1022 kg, respectively. The Moon's mean distance from Earth is 3.84 × 108 m, and Earth's mean distance from the Sun is 1.50 x 1011 m. The...
7) Given the mass of the sun (m,-1.99 x 1030 kg ) and the mass of the earth (me-5.98 x 1024 kg) and the distance between them (150 billion meters), find the amount of charge required on both the sun and earth to exactly balance the attractive gravitational force.
Learning Goal: To understand Newton's law of gravitation and the distinction between inertial and gravitational masses. In this problem, you will practice using Newton's law of gravitation. According to that law, the magnitude of the gravitational force Fg between two small particles of masses m1 and m2 separated by a distance r, is given by m1m2 T2 where G is the universal gravitational constant, whose numerical value (in SI units) is 6.67 x 10-11 Nm2 kg2 This formula applies not...
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