Hint | Answer | % Correct |
---|---|---|
Completely describes the behaviour of the electromagnetic field | Maxwell's equations | 100%
|
Differential equation that governs the wave function evolution in time | Schrödinger equation | 83%
|
Describes how mass and energy bend space-time | Einstein field equation | 67%
|
Set of partial differential equations which describe the motion of viscous fluid substances | Navier–Stokes equations | 67%
|
States that the current through a conductor is directly proportional to the voltage applied | Ohm's law | 67%
|
Relativistic wave equation that describes spin half massive particles | Dirac Equation | 50%
|
Describes the path taken by a system from one point to another in a way that minimizes its action | Euler–Lagrange equation | 50%
|
States that the energy of a particle in it's rest frame is the product of it's mass with the speed of light squared | Mass–energy equivalence | 50%
|
Gives the energy of a photon | Planck relation | 50%
|
Equations that incorporates both quantum field theory and gauge theory to explain the behavior of the strong, weak, and electromagnetic forces | Standard Model Lagrangian | 50%
|
Set of equations that govern the expansion of space in homogeneous and isotropic models | Friedmann equations | 33%
|
The force a point charge experiences under electric and magnetic fields | Lorentz force equation | 33%
|
Gives the attraction force between two masses | Newton's law of universal gravitation | 33%
|
Relates the force applied on an object with the rate of change of its momentum | Newton's second law | 33%
|
Gives the entropy of a system as a function of the multiplicity of states it can be found in | Boltzmann's entropy formula | 17%
|
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