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Probability current

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In quantum mechanics, the probability current (sometimes called probability flux) is a mathematical quantity describing the flow of probability. Specifically, if one thinks of probability as a heterogeneous fluid, then the probability current is the rate of flow of this fluid. It is a real vector that changes with space and time. Probability currents are analogous to mass currents in hydrodynamics and electric currents in electromagnetism. As in those fields, the probability current (i.e. the probability current density) is related to the probability density function via a continuity equation. The probability current is invariant under gauge transformation.

The concept of probability current is also used outside of quantum mechanics, when dealing with probability density functions that change over time, for instance in Brownian motion and the Fokker–Planck equation.[1]

The relativistic equivalent of the probability current is known as the probability four-current.

Definition (non-relativistic 3-current)

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Free spin-0 particle

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In non-relativistic quantum mechanics, the probability current j of the wave function Ψ of a particle of mass m in one dimension is defined as[2] where

Note that the probability current is proportional to a Wronskian

In three dimensions, this generalizes to where denotes the del or gradient operator. This can be simplified in terms of the kinetic momentum operator, to obtain

These definitions use the position basis (i.e. for a wavefunction in position space), but momentum space is possible.

Spin-0 particle in an electromagnetic field

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The above definition should be modified for a system in an external electromagnetic field. In SI units, a charged particle of mass m and electric charge q includes a term due to the interaction with the electromagnetic field;[3] where A = A(r, t) is the magnetic vector potential. The term qA has dimensions of momentum. Note that used here is the canonical momentum and is not gauge invariant, unlike the kinetic momentum operator .

In Gaussian units: where c is the speed of light.

Spin-s particle in an electromagnetic field

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If the particle has spin, it has a corresponding magnetic moment, so an extra term needs to be added incorporating the spin interaction with the electromagnetic field.

According to Landau-Lifschitz's Course of Theoretical Physics the electric current density is in Gaussian units:[4]

And in SI units:

Hence the probability current (density) is in SI units:

where S is the spin vector of the particle with corresponding spin magnetic moment μS and spin quantum number s.

It is doubtful if this formula is valid for particles with an interior structure.[citation needed] The neutron has zero charge but non-zero magnetic moment, so would be impossible (except would also be zero in this case). For composite particles with a non-zero charge – like the proton which has spin quantum number s=1/2 and μS= 2.7927·μN or the deuteron (H-2 nucleus) which has s=1 and μS=0.8574·μN [5] – it is mathematically possible but doubtful.

Connection with classical mechanics

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The wave function can also be written in the complex exponential (polar) form: where R, S are real functions of r and t.

Written this way, the probability density is and the probability current is:

The exponentials and RR terms cancel:

Finally, combining and cancelling the constants, and replacing R2 with ρ, Hence, the spatial variation of the phase of a wavefunction is said to characterize the probability flux of the wavefunction. If we take the familiar formula for the mass flux in hydrodynamics:

where is the mass density of the fluid and v is its velocity (also the group velocity of the wave). In the classical limit, we can associate the velocity with which is the same as equating S with the classical momentum p = mv however, it does not represent a physical velocity or momentum at a point since simultaneous measurement of position and velocity violates uncertainty principle. This interpretation fits with Hamilton–Jacobi theory, in which in Cartesian coordinates is given by S, where S is Hamilton's principal function.

The de Broglie-Bohm theory equates the velocity with in general (not only in the classical limit) so it is always well defined. It is an interpretation of quantum mechanics.

Motivation

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Continuity equation for quantum mechanics

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The definition of probability current and Schrödinger's equation can be used to derive the continuity equation, which has exactly the same forms as those for hydrodynamics and electromagnetism.[6]

For some wave function Ψ, let:

be the probability density (probability per unit volume, * denotes complex conjugate). Then,

where V is any volume and S is the boundary of V.

This is the conservation law for probability in quantum mechanics. The integral form is stated as:

whereis the probability current or probability flux (flow per unit area).

Here, equating the terms inside the integral gives the continuity equation for probability:and the integral equation can also be restated using the divergence theorem as:


\oiint .


In particular, if Ψ is a wavefunction describing a single particle, the integral in the first term of the preceding equation, sans time derivative, is the probability of obtaining a value within V when the position of the particle is measured. The second term is then the rate at which probability is flowing out of the volume V. Altogether the equation states that the time derivative of the probability of the particle being measured in V is equal to the rate at which probability flows into V.

By taking the limit of volume integral to include all regions of space, a well-behaved wavefunction that goes to zero at infinities in the surface integral term implies that the time derivative of total probability is zero ie. the normalization condition is conserved.[7] This result is in agreement with the unitary nature of time evolution operators which preserve length of the vector by definition.

Transmission and reflection through potentials

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In regions where a step potential or potential barrier occurs, the probability current is related to the transmission and reflection coefficients, respectively T and R; they measure the extent the particles reflect from the potential barrier or are transmitted through it. Both satisfy: where T and R can be defined by: where jinc, jref, jtrans are the incident, reflected and transmitted probability currents respectively, and the vertical bars indicate the magnitudes of the current vectors. The relation between T and R can be obtained from probability conservation:

In terms of a unit vector n normal to the barrier, these are equivalently: where the absolute values are required to prevent T and R being negative.

Examples

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Plane wave

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For a plane wave propagating in space: the probability density is constant everywhere; (that is, plane waves are stationary states) but the probability current is nonzero – the square of the absolute amplitude of the wave times the particle's speed;

illustrating that the particle may be in motion even if its spatial probability density has no explicit time dependence.

Particle in a box

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For a particle in a box, in one spatial dimension and of length L, confined to the region , the energy eigenstates are and zero elsewhere. The associated probability currents are since

Discrete definition

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For a particle in one dimension on we have the Hamiltonian where is the discrete Laplacian, with S being the right shift operator on Then the probability current is defined as with v the velocity operator, equal to and X is the position operator on Since V is usually a multiplication operator on we get to safely write

As a result, we find:

References

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  1. ^ Paul, Wolfgang; Baschnagel, Jörg (1999). Stochastic Processes : From Physics to Finance. Berlin: Springer. p. 84. ISBN 3-540-66560-9.
  2. ^ McMahon, D. (2008). Quantum Field Theory. McGraw Hill. ISBN 978-0-07-154382-8.
  3. ^ Ballentine, Leslie E. (1990). Quantum Mechanics. Prentice Hall Advanced Reference Series. Vol. 280. Englewood Cliffs: Prentice Hall. ISBN 0-13-747932-8.
  4. ^ see page 473, equation 115.4, L.D. Landau, E.M. Lifschitz. "COURSE OF THEORETICAL PHYSICS Vol. 3 – Quantum Mechanics" (PDF). ia803206.us.archive.org (3rd ed.). Retrieved 29 April 2023.
  5. ^ "Spin Properties of Nuclei". www2.chemistry.msu.edu. Retrieved 29 April 2023.
  6. ^ Quantum Mechanics, E. Abers, Pearson Ed., Addison Wesley, Prentice Hall Inc, 2004, ISBN 978-0-13-146100-0
  7. ^ Sakurai, Jun John; Napolitano, Jim (2021). Modern quantum mechanics (3rd ed.). Cambridge: Cambridge University Press. ISBN 978-1-108-47322-4.

Further reading

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  • Resnick, R.; Eisberg, R. (1985). Quantum Physics of Atoms, Molecules, Solids, Nuclei and Particles (2nd ed.). John Wiley & Sons. ISBN 0-471-87373-X.