366325
A \(0.5\;kg\) of mass is attached to a massless spring with \(k = 600\;N{\rm{/}}m.\) The system is completely immersed in a vessel containing \(1\;kg\) of water. The spring is made to oscillate with amplitude of \(5\;cm.\) When the oscillations are stopped completely, the change in the temperature of the water will be
(Consider, specific heat of the mass \( = 900\;J{\rm{/}}kg - K,\) specific heat of water \( = 4200\;J{\rm{/}}kg - K,\) the heat received by the vessel and spring can be neglected.)
366327 A steel ball of mass \(0.1\;kg\) falls freely from a height of \(10\;m\) and bounces to a height of \(5.4\;m\) from the ground. If the dissipated energy in this process is absorbed by the ball, the rise in its temperature is (specific heat of steel \( = 460\;J/kg\,^\circ C,g = 10\;m/{s^2})\)
366328 In an experiment a sphere of aluminium of mass \(0.20\;kg\) is heated upto \(150^\circ C\). Immediately, it is put into water of volume \(150\,cc\) at \(25^\circ C\) kept in a calorimeter of water equivalent to \(0.025\;kg\). Final temperature of the system is \(40^\circ C\). The specific heat of aluminium is:
366325
A \(0.5\;kg\) of mass is attached to a massless spring with \(k = 600\;N{\rm{/}}m.\) The system is completely immersed in a vessel containing \(1\;kg\) of water. The spring is made to oscillate with amplitude of \(5\;cm.\) When the oscillations are stopped completely, the change in the temperature of the water will be
(Consider, specific heat of the mass \( = 900\;J{\rm{/}}kg - K,\) specific heat of water \( = 4200\;J{\rm{/}}kg - K,\) the heat received by the vessel and spring can be neglected.)
366327 A steel ball of mass \(0.1\;kg\) falls freely from a height of \(10\;m\) and bounces to a height of \(5.4\;m\) from the ground. If the dissipated energy in this process is absorbed by the ball, the rise in its temperature is (specific heat of steel \( = 460\;J/kg\,^\circ C,g = 10\;m/{s^2})\)
366328 In an experiment a sphere of aluminium of mass \(0.20\;kg\) is heated upto \(150^\circ C\). Immediately, it is put into water of volume \(150\,cc\) at \(25^\circ C\) kept in a calorimeter of water equivalent to \(0.025\;kg\). Final temperature of the system is \(40^\circ C\). The specific heat of aluminium is:
366325
A \(0.5\;kg\) of mass is attached to a massless spring with \(k = 600\;N{\rm{/}}m.\) The system is completely immersed in a vessel containing \(1\;kg\) of water. The spring is made to oscillate with amplitude of \(5\;cm.\) When the oscillations are stopped completely, the change in the temperature of the water will be
(Consider, specific heat of the mass \( = 900\;J{\rm{/}}kg - K,\) specific heat of water \( = 4200\;J{\rm{/}}kg - K,\) the heat received by the vessel and spring can be neglected.)
366327 A steel ball of mass \(0.1\;kg\) falls freely from a height of \(10\;m\) and bounces to a height of \(5.4\;m\) from the ground. If the dissipated energy in this process is absorbed by the ball, the rise in its temperature is (specific heat of steel \( = 460\;J/kg\,^\circ C,g = 10\;m/{s^2})\)
366328 In an experiment a sphere of aluminium of mass \(0.20\;kg\) is heated upto \(150^\circ C\). Immediately, it is put into water of volume \(150\,cc\) at \(25^\circ C\) kept in a calorimeter of water equivalent to \(0.025\;kg\). Final temperature of the system is \(40^\circ C\). The specific heat of aluminium is:
366325
A \(0.5\;kg\) of mass is attached to a massless spring with \(k = 600\;N{\rm{/}}m.\) The system is completely immersed in a vessel containing \(1\;kg\) of water. The spring is made to oscillate with amplitude of \(5\;cm.\) When the oscillations are stopped completely, the change in the temperature of the water will be
(Consider, specific heat of the mass \( = 900\;J{\rm{/}}kg - K,\) specific heat of water \( = 4200\;J{\rm{/}}kg - K,\) the heat received by the vessel and spring can be neglected.)
366327 A steel ball of mass \(0.1\;kg\) falls freely from a height of \(10\;m\) and bounces to a height of \(5.4\;m\) from the ground. If the dissipated energy in this process is absorbed by the ball, the rise in its temperature is (specific heat of steel \( = 460\;J/kg\,^\circ C,g = 10\;m/{s^2})\)
366328 In an experiment a sphere of aluminium of mass \(0.20\;kg\) is heated upto \(150^\circ C\). Immediately, it is put into water of volume \(150\,cc\) at \(25^\circ C\) kept in a calorimeter of water equivalent to \(0.025\;kg\). Final temperature of the system is \(40^\circ C\). The specific heat of aluminium is:
366325
A \(0.5\;kg\) of mass is attached to a massless spring with \(k = 600\;N{\rm{/}}m.\) The system is completely immersed in a vessel containing \(1\;kg\) of water. The spring is made to oscillate with amplitude of \(5\;cm.\) When the oscillations are stopped completely, the change in the temperature of the water will be
(Consider, specific heat of the mass \( = 900\;J{\rm{/}}kg - K,\) specific heat of water \( = 4200\;J{\rm{/}}kg - K,\) the heat received by the vessel and spring can be neglected.)
366327 A steel ball of mass \(0.1\;kg\) falls freely from a height of \(10\;m\) and bounces to a height of \(5.4\;m\) from the ground. If the dissipated energy in this process is absorbed by the ball, the rise in its temperature is (specific heat of steel \( = 460\;J/kg\,^\circ C,g = 10\;m/{s^2})\)
366328 In an experiment a sphere of aluminium of mass \(0.20\;kg\) is heated upto \(150^\circ C\). Immediately, it is put into water of volume \(150\,cc\) at \(25^\circ C\) kept in a calorimeter of water equivalent to \(0.025\;kg\). Final temperature of the system is \(40^\circ C\). The specific heat of aluminium is: