Linear momentum: Difference between revisions

Definition

For a single body in pure translation

The linear momentum of a body is the vector ${\displaystyle m{\overline {v}}}$, where ${\displaystyle m}$ is the mass of the body and ${\displaystyle {\overline {v}}}$ is the velocity of the body.

For a system of bodies, each in pure translation

The linear momentum of a system is the sum of the linear momenta of all the bodies in that system. If the system comprises ${\displaystyle n}$ bodies with masses ${\displaystyle m_{1},m_{2},\dots ,m_{n}}$ respectively and velocities ${\displaystyle {\overline {v}}_{1},{\overline {v}}_{2},\dots ,{\overline {v}}_{n}}$ respectively, the total linear momentum is given by:

${\displaystyle \!\sum _{i=1}^{n}m_{i}{\overline {v}}_{i}}$

This is a vector summation.

For a single body undergoing motion that is not purely translation

In this case, we integrate the velocity vector over a mass differential:

${\displaystyle \int {\overline {v}}\,dm}$

This is equivalent to integrating the product of velocity and density over a volume differential:

${\displaystyle \int {\overline {v}}\rho \,dV}$

Units and dimensions

|{ class="sortable" border="1" ! Question !! Answer |- | Scalar or vector? || Vector |- | Instantaneous or time-cumulative || Instantaneous |- | MLT dimensions || ${\displaystyle MLT^{-1}}$: MLT;1;1;-1 (same as those of impulse) |- | SI units || ${\displaystyle kgm/s}$ (kilograms meter per second) or ${\displaystyle N-s}$ (Newton-second) |}