Part 1

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Three identical bodies of mass M are located at the vertices of an equilateral triangle of side L. They revolve under the effect of mutual gravitational force in a circular orbit, circumscribing the triangle while preserving the equilateral triangle. Their orbital velocity is
22
Sep
Three identical bodies of mass M are located at the vertices of an equilateral triangle of side L. They revolve under the effect of mutual gravitational force in a circular orbit, circumscribing the triangle while preserving the equilateral triangle. Their orbital velocity is circumscribing the triangle while preserving the equilateral triangle. Their orbital velocity is [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: circumscribing the triangle while preserving the equilateral triangle. Their orbital velocity is , Three identical bodies of mass M are located at the vertices of an equilateral triangle of side L. They revolve under the effect of mutual gravitational force in a circular orbit ,
Three equal masses of 1 kg each are placed at the vertices of an equilateral ΔPQR and a mass of 2kg is placed at the centroid O of the triangle which is at a distance of root 2 m from each of the vertices of the triangle. Find the force (in newton) acting on the mass of 2 kg.
22
Sep
Three equal masses of 1 kg each are placed at the vertices of an equilateral ΔPQR and a mass of 2kg is placed at the centroid O of the triangle which is at a distance of root 2 m from each of the vertices of the triangle. Find the force (in newton) acting on the [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: Two identical satellites A and B revolve around the earth in circular orbits at distance R and 3R from the surface of the earth. The ratio of the linear momenta of A and B is (R= radius of the earth) ,
Let A be the area swept out by the line joining the earth and the sun during February 1991. The area swept out by the line during a typical week in February 1991 is
22
Sep
Let A be the area swept out by the line joining the earth and the sun during February 1991. The area swept out by the line during a typical week in February 1991 is Let A be the area swept out by the line joining the earth and the sun during February 1991. The area [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: Let A be the area swept out by the line joining the earth and the sun during February 1991. The area swept out by the line during a typical week in February 1991 is ,
The magnitude of the gravitational field at distance r1​ and r2​ from the centre of a uniform sphere of radius R and mass M are I1​ and I2​ respectively. Find the ratio (I1/I2) if r1>R and r2
22
Sep
The magnitude of the gravitational field at distance r1​ and r2​ from the centre of a uniform sphere of radius R and mass M are I1​ and I2​ respectively. Find the ratio (I1/I2) if r1>R and r2 The magnitude of the gravitational field at distance r1​ and r2​ from the centre of a uniform sphere [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: The magnitude of the gravitational field at distance r1​ and r2​ from the centre of a uniform sphere of radius R and mass M are I1​ and I2​ respectively. Find the ratio (I1/I2) if r1>R and r2 ,
A planet of radius R=1/10× (radius of Earth) has the same mass density as Earth. Scientists dig a well of depth R/5 on it and lower a wire of the same length and of linear mass density 10^−3kgm^-1 into it. If the wire is not touching anywhere, the force applied at the top of the wire by a person holding it in place is (take the radius of Earth =6×10^6m and the acceleration due to gravity on Earth is 10ms^−2)
22
Sep
A planet of radius R=1/10× (radius of Earth) has the same mass density as Earth. Scientists dig a well of depth R/5 on it and lower a wire of the same length and of linear mass density 10^−3kgm^-1 into it. If the wire is not touching anywhere, the force applied at the top of the [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: Two identical satellites A and B revolve around the earth in circular orbits at distance R and 3R from the surface of the earth. The ratio of the linear momenta of A and B is (R= radius of the earth) ,
If r denotes the distance between the sun and the earth, then the angular momentum of the earth around the sun is proportional to
22
Sep
If r denotes the distance between the sun and the earth, then the angular momentum of the earth around the sun is proportional to If r denotes the distance between the sun and the earth then the angular momentum of the earth around the sun is proportional to September 22, 2020 Category: Chapter 10 - [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: If r denotes the distance between the sun and the earth , then the angular momentum of the earth around the sun is proportional to ,
Figure shows the variation of energy with the orbit radius r of a satellite in a circular motion. Mark the correct statement.
22
Sep
Figure shows the variation of energy with the orbit radius r of a satellite in a circular motion. Mark the correct statement. Figure shows the variation of energy with the orbit radius r of a satellite in a circular motion. Mark the correct statement. September 22, 2020 Category: Chapter 10 - Gravitation , MTG NEET [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: Figure shows the variation of energy with the orbit radius r of a satellite in a circular motion. Mark the correct statement. ,
A geostationary satellite is orbiting the earth at a height of 6R above the surface of the earth, R being the radius of the earth. The time period of another satellite at a height of 2.5R from the surface of the earth is:
22
Sep
A geostationary satellite is orbiting the earth at a height of 6R above the surface of the earth, R being the radius of the earth. The time period of another satellite at a height of 2.5R from the surface of the earth is: A geostationary satellite is orbiting the earth at a height of 6R [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: A geostationary satellite is orbiting the earth at a height of 6R above the surface of the earth , R being the radius of the earth. The time period of another satellite at a height of 2.5R from the surface of the earth is: ,
How long will a satellite placed in a circular orbit of radius that us (1/4)th the radius of a geostationary satellite take to complete one revolution around the earth ?
22
Sep
How long will a satellite placed in a circular orbit of radius that us (1/4)th the radius of a geostationary satellite take to complete one revolution around the earth ? How long will a satellite placed in a circular orbit of radius that us (1/4)th the radius of a geostationary satellite take to complete one [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: How long will a satellite placed in a circular orbit of radius that us (1/4)th the radius of a geostationary satellite take to complete one revolution around the earth ? ,
An artificial satellite is orbiting at the height of 1800 km from the Earth surface the earth radius is 6300 km and G = 10 m/s^2 on its surface. what is the radial acceleration ?
22
Sep
An artificial satellite is orbiting at the height of 1800 km from the Earth surface the earth radius is 6300 km and G = 10 m/s^2 on its surface. what is the radial acceleration ? An artificial satellite is orbiting at the height of 1800 km from the Earth surface the earth radius is 6300 [...]
Posted in: Chapter 10 - Gravitation , MTG NEET Physics , Part 1 ,
Tags: An artificial satellite is orbiting at the height of 1800 km from the Earth surface the earth radius is 6300 km and G = 10 m/s^2 on its surface. what is the radial acceleration ? ,