PlanetPhysics/Conservation of Angular Momentum

If a \htmladdnormallink{particle {http://planetphysics.us/encyclopedia/Particle.html} is subject to no torque then the [[../MolecularOrbitals/|angular momentum]] is conserved}

The angular momentum, ${\displaystyle 𝐋}$ of a particle with [[../PositionVector/|position vector]], ${\displaystyle 𝐫}$, and total linear [[../Momentum/|momentum]], ${\displaystyle 𝐩}$ is given by ${\displaystyle 𝐋=𝐫\times 𝐩}$. If some [[../Thrust/|force]], ${\displaystyle 𝐅}$, acts on that particles, then the torque is defined similarily as ${\displaystyle 𝐍=𝐫\times 𝐅=𝐫\times d𝐩/dt}$.

Taking the time derivative of the angular momentum equation,

${\displaystyle \begin{array}{ccc}\frac{d𝐋}{dt}& =& \frac{d}{dt}(𝐫\times 𝐩)\\ & =& (\frac{d𝐫}{dt}\times 𝐩)+(𝐫\times \frac{d𝐩}{dt}).\end{array}}$

Consider the term, ${\displaystyle d𝐫/dt\times 𝐩}$. Since ${\displaystyle 𝐩=md𝐫/dt}$, it follows that ${\displaystyle \frac{d𝐫}{dt}\times 𝐩=m(\frac{d𝐫}{dt}\times \frac{d𝐫}{dt}).}$ But, given an arbitrary [[../Vectors/|vector]], ${\displaystyle 𝐀}$, ${\displaystyle 𝐀\times 𝐀=\mathrm{𝟎}}$ (the zero vector), so the expression for the time derivative of the angular momentum becomes, ${\displaystyle \frac{d𝐋}{dt}=(𝐫\times \frac{d𝐩}{dt})=𝐍.}$ Writing the above simplistically as ${\displaystyle d𝐋/dt=𝐍}$ is is clear that when the torque is zero, then the angular momentum is constant in time; it is conserved.

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