355655 A small ball of mass \(m\) starts at a point \(A\) with speed \(\mathrm{v}_{0}\) and moves along a frictionless track \(AB\) as shown. The track \(BC\) has coefficient of friction \(\mu\). The ball comes to stop at \(C\) after travelling a distance \(L\) which is :-

355656 A \(10\;kg\) mass moves \(3.0\;m\) against a retarding force shown in the figure. If the force is zero at the beginning, then how much kinetic energy is changed?

355657 The graph between the resistive force \(F\) acting on a body and the distance covered by the body is shown in the figure. The mass of the body is 2.5 \(kg\) and initial velocity is 2 \(m/s\). When the distance covered by the body is 4 \(m\) , its kinetic energy would be

355658 A 3.00- \(kg\) object has a velocity \((6.00\hat i + 1.00\hat j)m/s\). What is the net work done on the object if its velocity changes to \((8.00\hat i + 4.00\hat j)m/s\)?

355659 In the given figure, ball \({A}\) is released from rest when the spring is at its natural (unstretched) length. For the block \({B}\) of mass \({M}\) to leave contact with the ground at some stage, the minimum mass of \({A}\) must be

355655 A small ball of mass \(m\) starts at a point \(A\) with speed \(\mathrm{v}_{0}\) and moves along a frictionless track \(AB\) as shown. The track \(BC\) has coefficient of friction \(\mu\). The ball comes to stop at \(C\) after travelling a distance \(L\) which is :-

355656 A \(10\;kg\) mass moves \(3.0\;m\) against a retarding force shown in the figure. If the force is zero at the beginning, then how much kinetic energy is changed?

355657 The graph between the resistive force \(F\) acting on a body and the distance covered by the body is shown in the figure. The mass of the body is 2.5 \(kg\) and initial velocity is 2 \(m/s\). When the distance covered by the body is 4 \(m\) , its kinetic energy would be

355658 A 3.00- \(kg\) object has a velocity \((6.00\hat i + 1.00\hat j)m/s\). What is the net work done on the object if its velocity changes to \((8.00\hat i + 4.00\hat j)m/s\)?

355659 In the given figure, ball \({A}\) is released from rest when the spring is at its natural (unstretched) length. For the block \({B}\) of mass \({M}\) to leave contact with the ground at some stage, the minimum mass of \({A}\) must be

355655 A small ball of mass \(m\) starts at a point \(A\) with speed \(\mathrm{v}_{0}\) and moves along a frictionless track \(AB\) as shown. The track \(BC\) has coefficient of friction \(\mu\). The ball comes to stop at \(C\) after travelling a distance \(L\) which is :-

355656 A \(10\;kg\) mass moves \(3.0\;m\) against a retarding force shown in the figure. If the force is zero at the beginning, then how much kinetic energy is changed?

355657 The graph between the resistive force \(F\) acting on a body and the distance covered by the body is shown in the figure. The mass of the body is 2.5 \(kg\) and initial velocity is 2 \(m/s\). When the distance covered by the body is 4 \(m\) , its kinetic energy would be

355658 A 3.00- \(kg\) object has a velocity \((6.00\hat i + 1.00\hat j)m/s\). What is the net work done on the object if its velocity changes to \((8.00\hat i + 4.00\hat j)m/s\)?

355659 In the given figure, ball \({A}\) is released from rest when the spring is at its natural (unstretched) length. For the block \({B}\) of mass \({M}\) to leave contact with the ground at some stage, the minimum mass of \({A}\) must be

355655 A small ball of mass \(m\) starts at a point \(A\) with speed \(\mathrm{v}_{0}\) and moves along a frictionless track \(AB\) as shown. The track \(BC\) has coefficient of friction \(\mu\). The ball comes to stop at \(C\) after travelling a distance \(L\) which is :-

355656 A \(10\;kg\) mass moves \(3.0\;m\) against a retarding force shown in the figure. If the force is zero at the beginning, then how much kinetic energy is changed?

355657 The graph between the resistive force \(F\) acting on a body and the distance covered by the body is shown in the figure. The mass of the body is 2.5 \(kg\) and initial velocity is 2 \(m/s\). When the distance covered by the body is 4 \(m\) , its kinetic energy would be

355658 A 3.00- \(kg\) object has a velocity \((6.00\hat i + 1.00\hat j)m/s\). What is the net work done on the object if its velocity changes to \((8.00\hat i + 4.00\hat j)m/s\)?

355659 In the given figure, ball \({A}\) is released from rest when the spring is at its natural (unstretched) length. For the block \({B}\) of mass \({M}\) to leave contact with the ground at some stage, the minimum mass of \({A}\) must be

355655 A small ball of mass \(m\) starts at a point \(A\) with speed \(\mathrm{v}_{0}\) and moves along a frictionless track \(AB\) as shown. The track \(BC\) has coefficient of friction \(\mu\). The ball comes to stop at \(C\) after travelling a distance \(L\) which is :-

355656 A \(10\;kg\) mass moves \(3.0\;m\) against a retarding force shown in the figure. If the force is zero at the beginning, then how much kinetic energy is changed?

355657 The graph between the resistive force \(F\) acting on a body and the distance covered by the body is shown in the figure. The mass of the body is 2.5 \(kg\) and initial velocity is 2 \(m/s\). When the distance covered by the body is 4 \(m\) , its kinetic energy would be

355658 A 3.00- \(kg\) object has a velocity \((6.00\hat i + 1.00\hat j)m/s\). What is the net work done on the object if its velocity changes to \((8.00\hat i + 4.00\hat j)m/s\)?

355659 In the given figure, ball \({A}\) is released from rest when the spring is at its natural (unstretched) length. For the block \({B}\) of mass \({M}\) to leave contact with the ground at some stage, the minimum mass of \({A}\) must be