The only force acting on a 2.0 kg body as it moves along the x - axis varies as shown in the figure. The velocity of the body at x = 0 is 4.0 ms What is the maximum K.E attained by the body between x=0 and x=5 m?
The only force acting on a 2.0 kg body as it moves along the x - axis varies as shown in the figure. The velocity of the body at x = 0 is 4.0 ms What is the maximum K.E attained by the body between x=0 and x=5 m?
The correct option is A 12 J
Kinetic energy of the body at x = 0 is K1=12×2.0×(4.0)2=16.0j
Work done by the force on the body is given by area bounded by the curve and x-axis.From x = 0 to x = 1.0m
The force decreases linearly from F = 4N to F = 0, but it is directed along +x-axis, work done by the force is +ve.For 1.0m < x ≤ 5.0m, the force is -ve, so it is directed along -x axis for any interval in this region, the work done by the force will be -ve.
From x = 0 to x = 3.0m, work done by the force on the body = Area of the bounded region
Wnet=12×4×1.0−12×4×1.0=−4.0N.m=−4J
Let the K.E of the body at x = 3.0 m be K3
From work - energy theorem,
-4 = K3−16
K3=12J
12 J
Kinetic energy of the body at x = 0 is K1=12×2.0×(4.0)2=16.0j
Work done by the force on the body is given by area bounded by the curve and x-axis.From x = 0 to x = 1.0m
The force decreases linearly from F = 4N to F = 0, but it is directed along +x-axis, work done by the force is +ve.For 1.0m < x ≤ 5.0m, the force is -ve, so it is directed along -x axis for any interval in this region, the work done by the force will be -ve.
From x = 0 to x = 3.0m, work done by the force on the body = Area of the bounded region
Wnet=12×4×1.0−12×4×1.0=−4.0N.m=−4J
Let the K.E of the body at x = 3.0 m be K3
From work - energy theorem,
-4 = K3−16
K3=12J
