6 CONSERVATION OF MOMENTUM 6.4 Rocket science
rocketpropellantFigure 50: A rocket.
t t+dtv (^) M+m M+m+dm v+dv
- dm v-u^
Figure 51: Derivation of the rocket equation.Let us attempt to find the equation of motion of a rocket. Let M be the fixedmass of the rocket engine and the payload, and m(t) the total mass of the pro-
pellant contained in the rocket’s fuel tanks at time t. Suppose that the rocket
engine ejects the propellant at some fixed velocity u relative to the rocket. Let
us examine the rocket at two closely spaced instances in time. Suppose that at
time t the rocket and propellant, whose total mass is M + m, are traveling with
instantaneous velocity v. Suppose, further, that between times t and t + dt the
rocket ejects a quantity of propellant of mass −dm (n.b., dm is understood to
be negative, so this represents a positive mass) which travels with velocity v − u
(i.e., velocity −u in the instantaneous rest frame of the rocket). As a result of the
fuel ejection, the velocity of the rocket at time t + dt is boosted to v + dv, and its
total mass becomes M + m + dm. See Fig. 51.
Now, there is zero external force acting on the system, since the rocket is