Add: 2.386x109 + 7.472x106 Use the 1x10^6 style format for entering your answer. No spaces between...
Homework help !!! Numbers 1-3 QUESTION 1 What is the gravitational force on a 87 kilogram person standing on the Earth, due to the Earth's gravity? The mass of the Earth is 5.97 1024 kilograms and the radius of the Earth is 6 38 × 106 meters Round your answer to the nearest integer. QUESTION 2 What is the gravitational force on a 74 kilogram person standing on the Earth, due to Moon's gravity? The mass of the Moon is...
What is the gravitational force on a 52 kilogram person standing on the Earth, due to the Earth's gravity? The mass of the Earth is 5.97x 104 kilograms and the radius of the Earth is 6.38 x 10 meters. Round your answer to the nearest integer. A. What is the gravitational force on a 71 kilogram person standing on the Earth, due to Moon's gravity? The mass of the Moon is 7.34 x 102 kilograms and the distance from the...
QUESTION 16 The Moon which has mass of about 7.35 1022 kilograms, and it orbits the Earth with an average orbital distance of 384,400 kilometers. Calculate the following for the Moon the magnitude of the average gravitational force exerted by the Earth on the Moon: A. Newtons (use scientific notation and round the coefficient to two decimals) the magnitude of the acceleration due to Earth's gravity at Moon's orbit B. m/s (use scientific notation and round the coefficient to two...
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...
You send a flash of light toward the Moon. It bounces off a mirror and returns to you. You measure the time between when you sent the flash and when it returns to you and find that the whole process took 2.0 seconds. The distance to the Moon is (state your answer in kilometers and list the answer with at least three significant figures.) You can use 3x108 m/s as the speed of light (feel free to google this quantity...
4 10 points You send a flash of light toward the Moon. It bounces off a mirror and returns to you. You measure the time between when you sent the flash and when it returns to you and find that the whole process took 2.0 seconds. The distance to the Moon is (state your answer in kilometers and list the answer with at least three significant figures.) You can use 3x108 m/s as the speed of light (feel free to...
show calculations please! In Astronomy we often deal with distances, or lengths, that range form the very small to the very large. For instance The size of a nucleus is roughly 0.000, 000,000,000,001 meters and the distance to the nearest star is roughly 700,000,000,000 meters. We will talk about these numbers using scientific notation where each zero is counted as ten raised to an exponent equal to the number of zeros. Le the size of a nucleus is 1 x...
Voyager 1 was 16,238,494,019,000 and voyager 2 was 13,147,855,813,000 from the sun Part 3: Voyager 1 and 2 How far away from the sun, in meters, were the Voyager 1 and 2 spacecraft as of January 2, 20097 Research this information using the Internet or any other sources you can find. Then plot the positions of these two spacecraft on the graph you created in Part 2. How far away are they compared to the nearest star? Specifically, at what...
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...
FERENCES MAILINGS REVIEWVIEWFoxit PDF The force of gravity, F, exerted between two objects is equal to the product of the gravitational constant, G, the mass of the irst object, m, and the mass of the second object, ma, divided by the square of the distance between their centers, d. This is often used to determine the gravitational attraction behween two massive bodies, such as planets, in space. a. Write the formula for F described in the situation above. Type your...