There are (one can say) three coequal theories of motion for a single particle:
ID: 1615788 • Letter: T
Question
There are (one can say) three coequal theories of motion for a single particle: Newton's second law, stating that the total force on an object causes its acceleration; the work–kinetic energy theorem, stating that the total work on an object causes its change in kinetic energy; and the impulse–momentum theorem, stating that the total impulse on an object causes its change in momentum. In this problem, you compare predictions of the three theories in one particular case. A 4.00-kg object has velocity 7.00 m/s. Then, a constant net force 9.0î N acts on the object for 3.50 s.
mvf2 =
/m .Explanation / Answer
part a )
dF = dp/dt
F*dt = pf-pi
pi + F*dt = pf
p = momentum = mv
m*vi + F*dt = m*vf
vf = 7j + 7.875i m/s
part b )
a = (vf-vi)/dt
a = (7j+7.875i - 7j)/3.5
a = 2.25i m/s^2
part c )
a = F/m = 9i/4 = 2.25i m/s^2
part d )
dr = vi*t + 1/2 * a*t^2
dr = 7j * 3.5 + 1/2 * 2.25i * (3.5)^2
dr = 24.5 j + 13.78125i
part e )
W = F.dr
W = 9i * ( 24.5j + 13.78125i)
W = 124.03125J
part f )
KEf = 1/2*m*vf^2
vf = 7j + 7.875i
KEf = 222.03125 J
part g )
KE = mvi^2+W
KE = 222.03125 J
part h )
The accelerations computed in different ways agree. The kinetic energies computed in different ways agree. The three theories are consistent.
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