Newton's Second Law and Relativistic Dynamics
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Exercise:
Newton's second law in the form vec F fractextrmdvec ptextrmdt dotvec p is still correct in relativistic physics. abcliste abc Show that when the force acting on a particle is parallel to its velocity it can be written as F gamma^ m dot v gamma^ m a abc Show that the general relation between the force vector and the accelerations parallel and perpicular to the motion of the particle is vec F gamma^ m vec a_parallel + gamma m vec a_perp abcliste
Solution:
abcliste abc The relativistic momentum is p gamma m v The derivative with respect to time is dot p mleftdotgamma v+gammadot vright The derivative of the Lorentz factor with respect to time is fractextrmdgammatextrmdt fractextrmdgammatextrmdv fractextrmdvtextrmdt fractextrmdtextrmdvleft-leftfracvcright^right^-/ dot v -fra vleft-leftfracvcright^right^-/left-fracvc^right fracv dot vc^ gamma^ Putting everything together we find dot p gamma m dot v leftgamma^fracv^c^+right gamma m dot v leftfracfracv^c^-fracv^c^+right gamma m dot v leftfracv^c^-v^+right gamma m dot v left fracv^+c^-v^c^-v^right gamma m dot v left frac-fracv^c^right gamma m dot v gamma^ gamma^ m dot v gamma^ m a abc The derivative of the momentum vector with respect to time is dot vec p mleftfractextrmdgammatextrmdt vec v + gamma fractextrmdvec vtextrmdtright The derivative of the Lorentz factor can be derived in a similar way as before but we have to take o account that v^ v_x^+v_y^+v_z^ so according to the chain rule we have the following expression: dot gamma fractextrmdgammatextrmdv_x dot v_x + fractextrmdgammatextrmdv_y dot v_y + fractextrmdgammatextrmdv_z dot v_z With fractextrmdgammatextrmdv_x fractextrmdtextrmdv_xleft-fracv_x^+v_y^+v_z^c^right^-/ frac-left-fracv_x^+v_y^+v_z^c^right^-/ leftfrac- v_xc^right fracv_xc^ gamma^ and the anologous expressions for the derivative with respect to v_y and v_z we find for dot gamma dot gamma gamma^ fracv_x dot v_x+v_y dot v_y + v_z dot v_zc^ fracgamma^c^ vec v dotvec v It follows for the derivative of the momentum vector dotvec p m leftfracgamma^c^vec v dotvec vvec v + gamma dotvec v right gamma m leftfracgamma^c^ vec v vec a vec v+vec aright We can express the acceleration as the e of the accelerations parallel and perpicular to the motion: vec a vec a_parallel + vec a_perp Since vec v perp vec a_perp we have vec v vec a vec v vec a_parallel + vec a_perp vec v vec a_parallel and since vec v and a_parallel are parallel the vector vec v vec a_parallel vec v has the same direction as a_parallel and magnitude v^ a_parallel so it can be written as vec v vec a_parallel vec v v^ vec a_parallel The force vector is thus vec F dotvec p gamma m leftgamma^fracv^c^ vec a_parallel + a_parallel + a_perpright gamma m leftgamma^ fracv^c^+right vec a_parallel + gamma m vec a_perp gamma^ m vec a_parallel + gamma m vec a_perp The result shows that the ratio between force and mass is not the same for forces acting parallel and perpicular to the motion of the particle. abcliste
Newton's second law in the form vec F fractextrmdvec ptextrmdt dotvec p is still correct in relativistic physics. abcliste abc Show that when the force acting on a particle is parallel to its velocity it can be written as F gamma^ m dot v gamma^ m a abc Show that the general relation between the force vector and the accelerations parallel and perpicular to the motion of the particle is vec F gamma^ m vec a_parallel + gamma m vec a_perp abcliste
Solution:
abcliste abc The relativistic momentum is p gamma m v The derivative with respect to time is dot p mleftdotgamma v+gammadot vright The derivative of the Lorentz factor with respect to time is fractextrmdgammatextrmdt fractextrmdgammatextrmdv fractextrmdvtextrmdt fractextrmdtextrmdvleft-leftfracvcright^right^-/ dot v -fra vleft-leftfracvcright^right^-/left-fracvc^right fracv dot vc^ gamma^ Putting everything together we find dot p gamma m dot v leftgamma^fracv^c^+right gamma m dot v leftfracfracv^c^-fracv^c^+right gamma m dot v leftfracv^c^-v^+right gamma m dot v left fracv^+c^-v^c^-v^right gamma m dot v left frac-fracv^c^right gamma m dot v gamma^ gamma^ m dot v gamma^ m a abc The derivative of the momentum vector with respect to time is dot vec p mleftfractextrmdgammatextrmdt vec v + gamma fractextrmdvec vtextrmdtright The derivative of the Lorentz factor can be derived in a similar way as before but we have to take o account that v^ v_x^+v_y^+v_z^ so according to the chain rule we have the following expression: dot gamma fractextrmdgammatextrmdv_x dot v_x + fractextrmdgammatextrmdv_y dot v_y + fractextrmdgammatextrmdv_z dot v_z With fractextrmdgammatextrmdv_x fractextrmdtextrmdv_xleft-fracv_x^+v_y^+v_z^c^right^-/ frac-left-fracv_x^+v_y^+v_z^c^right^-/ leftfrac- v_xc^right fracv_xc^ gamma^ and the anologous expressions for the derivative with respect to v_y and v_z we find for dot gamma dot gamma gamma^ fracv_x dot v_x+v_y dot v_y + v_z dot v_zc^ fracgamma^c^ vec v dotvec v It follows for the derivative of the momentum vector dotvec p m leftfracgamma^c^vec v dotvec vvec v + gamma dotvec v right gamma m leftfracgamma^c^ vec v vec a vec v+vec aright We can express the acceleration as the e of the accelerations parallel and perpicular to the motion: vec a vec a_parallel + vec a_perp Since vec v perp vec a_perp we have vec v vec a vec v vec a_parallel + vec a_perp vec v vec a_parallel and since vec v and a_parallel are parallel the vector vec v vec a_parallel vec v has the same direction as a_parallel and magnitude v^ a_parallel so it can be written as vec v vec a_parallel vec v v^ vec a_parallel The force vector is thus vec F dotvec p gamma m leftgamma^fracv^c^ vec a_parallel + a_parallel + a_perpright gamma m leftgamma^ fracv^c^+right vec a_parallel + gamma m vec a_perp gamma^ m vec a_parallel + gamma m vec a_perp The result shows that the ratio between force and mass is not the same for forces acting parallel and perpicular to the motion of the particle. abcliste