| <math>\(P = \frac{{T \cdot V}}{{n \cdot R}}\)<\math> || Ideal gas law where \(P\) is pressure, \(T\) is temperature, \(V\) is volume, \(n\) is the number of moles, and \(R\) is the ideal gas constant.

| \(F = q(E + v \times B)\) || Lorentz force equation where \(F\) is the force, \(q\) is the charge, \(E\) is the electric field, \(v\) is the velocity, and \(B\) is the magnetic field.

| \(m = \frac{{m_0}}{{\sqrt{1 - \frac{{v^2}}{{c^2}}}}}\) || Relativistic mass equation where \(m\) is the relativistic mass, \(m_0\) is the rest mass, \(v\) is the velocity, and \(c\) is the speed of light.

| \(E = mc^2\) || Energy-mass equivalence equation from Einstein's theory of relativity where \(E\) is energy, \(m\) is mass, and \(c\) is the speed of light.

| \(v_f = v_i + at\) || Kinematic equation for final velocity where \(v_f\) is the final velocity, \(v_i\) is the initial velocity, \(a\) is acceleration, and \(t\) is time.

| \(I = \frac{V}{R}\) || Ohm's law where \(I\) is current, \(V\) is voltage, and \(R\) is resistance.

| \(F_{\text{buoyant}} = \rho \cdot g \cdot V\) || Buoyant force equation where \(F_{\text{buoyant}}\) is the buoyant force, \(\rho\) is the density of the fluid, \(g\) is the acceleration due to gravity, and \(V\) is the volume of the displaced fluid.

| \(P_{\text{mech}} = P_{\text{hydro}} + P_{\text{static}} + P_{\text{dynamic}}\) || Mechanical power equation where \(P_{\text{mech}}\) is the mechanical power, \(P_{\text{hydro}}\) is the hydrostatic pressure, \(P_{\text{static}}\) is the static pressure, and \(P_{\text{dynamic}}\) is the dynamic pressure.