===== Example: Firing a deer slug. ===== How much force does a 12 gauge exert on your shoulder when firing a deer slug? === Facts === Mass of gun = 3.5kg Mass of slug = 0.22kg === Lacking === $\vec{F}_{net}$ on shoulder === Approximations & Assumptions === ${\Delta t} \longrightarrow 1/24s$ - Based on when a gun is fired in a movie, it usually occurs at about one movie frame, therefore, the collision time is less than 1/24s. $\vec{V}_{Slug} \longrightarrow 500m/s$ This is a conservative estimate based on an internet search. === Representations === System: Gun + Slug Surroundings: Nothing {{183_notes:examples:momentum_example_2_upload.jpg?600|}} $\vec{F}_{net} = \dfrac{\Delta\vec{p}}{\Delta t}$ $\vec{p}_{sys,f} = \vec{p}_{sys,i}$ $\vec{p}_{1,f} + \vec{p}_{2,f} = \vec{p}_{1,i} + \vec{p}_{2,i}$ $m_1\vec{v}_{1,f} + m_2\vec{v}_{2,f} = m_1\vec{v}_{1,i} + m_2\vec{v}_{2,i}$ === Solution === We know that the momentum of the system (gun + slug) does not change due to their being no external forces acting on the system, therefore, the change in momentum in the x-direction is 0. ${\Delta p_x} = 0$ The total momentum of the system in x direction is also 0. $P_{tot,x} = 0$ This is because the initial momentum of the system is 0 and therefore the final momentum of the system is zero. $P_{tot,i,x} = 0$ We can relate the momentum before to the momentum after then giving us the following equation. $0 = M_G * V_G + m_S * V_S \longrightarrow M_G * V_G$ is negative and $m_S * V_S$ is positive (see diagram). To find the force acting on the shoulder of the shooter me need to know $V_G$ in order to find change in momentum for the gun and relate this to the force using $\vec{F}_{net} = \dfrac{\Delta\vec{p}}{\Delta t}$. Rearrange the previous equation. $V_G = {\dfrac{-m_s}{M_G}} V_S$ Fill in the values for the corresponding variables. $V_G = - {\dfrac{0.22kg}{3.5kg}}{500m/s} = -31.4m/s$ Use the value found for $V_G$ to find the change in momentum and hence find what kind of force that is on your shoulder. $\vec{F}_{net} = \dfrac{\Delta\vec{p}}{\Delta t}$ Fill in values for known variables. $\vec{F}_{net} =\dfrac{(3.5kg)(-31.4m/s + 0m/s)}{(1/24s)}$ $\vec{F}_{net} = 2637.6N$ (at least)