Conserved current

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In physics a conserved current is a current, <math>j^\mu</math>, that satisfies the continuity equation <math>\partial_\mu j^\mu=0</math>. The continuity equation represents a conservation law, hence the name.

Indeed, integrating the continuity equation over a volume <math>V</math>, large enough to have no net currents through its surface, leads to the conservation law <math display="block"> \frac{\partial}{\partial t}Q = 0\;,</math> where <math display="inline">Q = \int_V j^0 dV</math> is the conserved quantity.

In gauge theories the gauge fields couple to conserved currents. For example, the electromagnetic field couples to the conserved electric current.

Conserved quantities and symmetries

Conserved current is the flow of the canonical conjugate of a quantity possessing a continuous translational symmetry. The continuity equation for the conserved current is a statement of a conservation law. Examples of canonical conjugate quantities are:

Conserved currents play an extremely important role in theoretical physics, because Noether's theorem connects the existence of a conserved current to the existence of a symmetry of some quantity in the system under study. In practical terms, all conserved currents are the Noether currents, as the existence of a conserved current implies the existence of a symmetry. Conserved currents play an important role in the theory of partial differential equations, as the existence of a conserved current points to the existence of constants of motion, which are required to define a foliation and thus an integrable system. The conservation law is expressed as the vanishing of a 4-divergence, where the Noether charge forms the zeroth component of the 4-current.

Examples

Electromagnetism

The conservation of charge, for example, in the notation of Maxwell's equations, <math display="block">\frac{\partial \rho} {\partial t} + \nabla \cdot \mathbf{J} = 0</math>

where

  • ρ is the free electric charge density (in units of C/m3)
  • J is the current density <math display="block"> \mathbf J = \rho \mathbf v </math> with v as the velocity of the charges.

The equation would apply equally to masses (or other conserved quantities), where the word mass is substituted for the words electric charge above.

Complex scalar field

The Lagrangian density <math display="block"> \mathcal{L}=\partial_\mu\phi^*\,\partial^\mu\phi +V(\phi^*\,\phi)</math> of a complex scalar field <math display> \phi:\mathbb{R}^{n+1}\mapsto\mathbb{C} </math> is invariant under the symmetry transformation <math display="block"> \phi\mapsto\phi'=\phi\,e^{i\alpha}\, . </math> Defining <math display> \delta\phi=\phi'-\phi </math> we find the Noether current <math display="block"> j^\mu:=\frac{d\mathcal{L}}{d(\partial_\mu)\phi}\,\frac{d(\delta\phi)}{d\alpha}\bigg|_{\alpha=0}+\frac{d\mathcal{L}}{d(\partial_\mu)\phi^*}\,\frac{d(\delta\phi^*)}{d\alpha}\bigg|_{\alpha=0}= i\,\phi\,(\partial^\mu\phi^*)-i\,\phi^*\,(\partial^\mu\phi)</math> which satisfies the continuity equation.

See also

References

  • Goldstein, Herbert (1980). Classical Mechanics (2nd ed.). Reading, MA: Addison-Wesley. pp. 588–596. ISBN 0-201-02918-9.
  • Peskin, Michael E.; Schroeder, Daniel V. (1995). "Chapter I.2.2. Elements of Classical Field Theory". An Introduction to Quantum Field Theory. CRC Press. ISBN 978-0-201-50397-5.