359841 A body of mass 60\(g\) experiences a gravitational force of 3.0\(N\), when placed at a particular point. The magnitude of the gravitational field intensity at that point is:

359842 Two masses \(90\;kg\) and \(160\;kg\) are \(5\;m\) apart. The gravitational field intensity at a point \(3\;m\) from \(90\;kg\) and \(4 \mathrm{~m}\) from \(160\;kg\) is

359843 Figure shows a system of point masses placed on \(X\)-axis. Find the net gravitational field intensity at the origin.

359844 The gravitational intensity in a region is \(10(\hat i - \hat j)N{\rm{/}}kg\). The work done by the gravitational force to shift slowly a particle of mass \(1\;kg\) from point \((1\;m,1\;m)\) to a point \((2\;m,{\rm{ }} - 2m)\) is

359845 Two bodies \(A\) and \(B\), having masses \(m\) and \(4 m\), are separated by distance \(r\). Distance from \(A\) at which gravitational field becomes zero is

359841 A body of mass 60\(g\) experiences a gravitational force of 3.0\(N\), when placed at a particular point. The magnitude of the gravitational field intensity at that point is:

359842 Two masses \(90\;kg\) and \(160\;kg\) are \(5\;m\) apart. The gravitational field intensity at a point \(3\;m\) from \(90\;kg\) and \(4 \mathrm{~m}\) from \(160\;kg\) is

359843 Figure shows a system of point masses placed on \(X\)-axis. Find the net gravitational field intensity at the origin.

359844 The gravitational intensity in a region is \(10(\hat i - \hat j)N{\rm{/}}kg\). The work done by the gravitational force to shift slowly a particle of mass \(1\;kg\) from point \((1\;m,1\;m)\) to a point \((2\;m,{\rm{ }} - 2m)\) is

359845 Two bodies \(A\) and \(B\), having masses \(m\) and \(4 m\), are separated by distance \(r\). Distance from \(A\) at which gravitational field becomes zero is

359841 A body of mass 60\(g\) experiences a gravitational force of 3.0\(N\), when placed at a particular point. The magnitude of the gravitational field intensity at that point is:

359842 Two masses \(90\;kg\) and \(160\;kg\) are \(5\;m\) apart. The gravitational field intensity at a point \(3\;m\) from \(90\;kg\) and \(4 \mathrm{~m}\) from \(160\;kg\) is

359843 Figure shows a system of point masses placed on \(X\)-axis. Find the net gravitational field intensity at the origin.

359844 The gravitational intensity in a region is \(10(\hat i - \hat j)N{\rm{/}}kg\). The work done by the gravitational force to shift slowly a particle of mass \(1\;kg\) from point \((1\;m,1\;m)\) to a point \((2\;m,{\rm{ }} - 2m)\) is

359845 Two bodies \(A\) and \(B\), having masses \(m\) and \(4 m\), are separated by distance \(r\). Distance from \(A\) at which gravitational field becomes zero is

359841 A body of mass 60\(g\) experiences a gravitational force of 3.0\(N\), when placed at a particular point. The magnitude of the gravitational field intensity at that point is:

359842 Two masses \(90\;kg\) and \(160\;kg\) are \(5\;m\) apart. The gravitational field intensity at a point \(3\;m\) from \(90\;kg\) and \(4 \mathrm{~m}\) from \(160\;kg\) is

359843 Figure shows a system of point masses placed on \(X\)-axis. Find the net gravitational field intensity at the origin.

359844 The gravitational intensity in a region is \(10(\hat i - \hat j)N{\rm{/}}kg\). The work done by the gravitational force to shift slowly a particle of mass \(1\;kg\) from point \((1\;m,1\;m)\) to a point \((2\;m,{\rm{ }} - 2m)\) is

359845 Two bodies \(A\) and \(B\), having masses \(m\) and \(4 m\), are separated by distance \(r\). Distance from \(A\) at which gravitational field becomes zero is

359841 A body of mass 60\(g\) experiences a gravitational force of 3.0\(N\), when placed at a particular point. The magnitude of the gravitational field intensity at that point is:

359842 Two masses \(90\;kg\) and \(160\;kg\) are \(5\;m\) apart. The gravitational field intensity at a point \(3\;m\) from \(90\;kg\) and \(4 \mathrm{~m}\) from \(160\;kg\) is

359843 Figure shows a system of point masses placed on \(X\)-axis. Find the net gravitational field intensity at the origin.

359844 The gravitational intensity in a region is \(10(\hat i - \hat j)N{\rm{/}}kg\). The work done by the gravitational force to shift slowly a particle of mass \(1\;kg\) from point \((1\;m,1\;m)\) to a point \((2\;m,{\rm{ }} - 2m)\) is

359845 Two bodies \(A\) and \(B\), having masses \(m\) and \(4 m\), are separated by distance \(r\). Distance from \(A\) at which gravitational field becomes zero is