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EspañolKLEIN-GORDON EQUATION
The 'Klein-Gordon equation' ('Klein-Fock-Gordon equation' or sometimes ''Klein-Gordon-Fock equation'') is the relativistic version of the Schrödinger equation, which is used to describe spinless particles. It was named after Oskar Klein and Walter Gordon.
__TOC__
The Schrödinger equation for a free particle is
:
where
: is the momentum operator ( being the del operator).
The Schrödinger equation suffers from not being relativistically covariant, meaning it does not take into account Einstein's special relativity.
It is natural to try to use the identity from special relativity
:
for the energy; then, just inserting the quantum mechanical momentum operator, yields the equation
:
This, however, is a cumbersome expression to work with because of the square root. In addition, this equation, as it stands, is nonlocal.
Klein and Gordon instead worked with the more general ''square'' of this equation (the Klein-Gordon equation for a free particle), which in covariant notation reads
:
where
:
and
:
This operator is called the d'Alembert operator. Today this form is interpreted as the relativistic field equation for a scalar (i.e. spin-0) particle.
The Klein-Gordon equation was first considered as a quantum wave equation by Schrödinger in his search for an equation describing de Broglie waves. The equation is found in his notebooks from late 1925, and he appears to have prepared a manuscript applying it to the hydrogen atom. Yet, without taking into account the electron's spin, the Klein-Gordon equation predicts the hydrogen atom's fine structure incorrectly, including overestimating the overall magnitude of the splitting pattern by a factor of 4n/(2n-1) for the n-th energy level. In January 1926, Schrödinger submitted for publication instead ''his'' equation, a non-relativistic approximation that predicts the Bohr energy levels of hydrogen without fine structure.
In 1926, soon after the Schrödinger equation was introduced, Fock wrote an article about its generalization for the case of magnetic fields, where forces were dependent on velocity, and independently derived this equation. Both Klein and Fock used Kaluza and Klein's method. Fock also determined the gauge theory for the wave equation. The Klein-Gordon equation for a free particle has a simple plane wave solution.
The Klein-Gordon equation for a free particle can be written as
:
with the same solution as in the non-relativistic case:
:
except with the constraint
:
Just as with the non-relativistic particle, we have for energy and momentum:
:
:
Except that now when we solve for k and ω and substitute into the constraint equation, we recover the relationship between energy and momentum for relativistic massive particles:
:
For massless particles, we may set ''m'' = 0 in the above equations. We then recover the relationship between energy and momentum for massless particles:
:
The Klein-Gordon equation can be derived from the following action
:
where is the Klein-Gordon field and is its mass.
★ Dirac equation
★ Quantum field theory
★ Scalar field
★ Mathematical aspects of the Klein-Gordon equation are discussed on the Dispersive PDE Wiki.
★ Advanced Quantum Mechanics, Sakurai, J. J., , , Addison Wesley, 1967, ISBN 0-201-06710-2
★ Quantum Mechanics, 2nd Edition, Davydov, A.S., , , Pergamon, 1976, ISBN 0-08-020437-6
★ Linear Klein-Gordon Equation at EqWorld: The World of Mathematical Equations.
★ Nonlinear Klein-Gordon Equation at EqWorld: The World of Mathematical Equations.
★ generalizing the Klein-Gordon equation to include a generalized space
__TOC__
| Contents |
| Details |
| Relativistic free particle solution |
| Action |
| See also |
| References |
| External links |
Details
The Schrödinger equation for a free particle is
:
where
: is the momentum operator ( being the del operator).
The Schrödinger equation suffers from not being relativistically covariant, meaning it does not take into account Einstein's special relativity.
It is natural to try to use the identity from special relativity
:
for the energy; then, just inserting the quantum mechanical momentum operator, yields the equation
:
This, however, is a cumbersome expression to work with because of the square root. In addition, this equation, as it stands, is nonlocal.
Klein and Gordon instead worked with the more general ''square'' of this equation (the Klein-Gordon equation for a free particle), which in covariant notation reads
:
where
:
and
:
This operator is called the d'Alembert operator. Today this form is interpreted as the relativistic field equation for a scalar (i.e. spin-0) particle.
The Klein-Gordon equation was first considered as a quantum wave equation by Schrödinger in his search for an equation describing de Broglie waves. The equation is found in his notebooks from late 1925, and he appears to have prepared a manuscript applying it to the hydrogen atom. Yet, without taking into account the electron's spin, the Klein-Gordon equation predicts the hydrogen atom's fine structure incorrectly, including overestimating the overall magnitude of the splitting pattern by a factor of 4n/(2n-1) for the n-th energy level. In January 1926, Schrödinger submitted for publication instead ''his'' equation, a non-relativistic approximation that predicts the Bohr energy levels of hydrogen without fine structure.
In 1926, soon after the Schrödinger equation was introduced, Fock wrote an article about its generalization for the case of magnetic fields, where forces were dependent on velocity, and independently derived this equation. Both Klein and Fock used Kaluza and Klein's method. Fock also determined the gauge theory for the wave equation. The Klein-Gordon equation for a free particle has a simple plane wave solution.
Relativistic free particle solution
The Klein-Gordon equation for a free particle can be written as
:
with the same solution as in the non-relativistic case:
:
except with the constraint
:
Just as with the non-relativistic particle, we have for energy and momentum:
:
:
Except that now when we solve for k and ω and substitute into the constraint equation, we recover the relationship between energy and momentum for relativistic massive particles:
:
For massless particles, we may set ''m'' = 0 in the above equations. We then recover the relationship between energy and momentum for massless particles:
:
Action
The Klein-Gordon equation can be derived from the following action
:
where is the Klein-Gordon field and is its mass.
See also
★ Dirac equation
★ Quantum field theory
★ Scalar field
★ Mathematical aspects of the Klein-Gordon equation are discussed on the Dispersive PDE Wiki.
References
★ Advanced Quantum Mechanics, Sakurai, J. J., , , Addison Wesley, 1967, ISBN 0-201-06710-2
★ Quantum Mechanics, 2nd Edition, Davydov, A.S., , , Pergamon, 1976, ISBN 0-08-020437-6
External links
★ Linear Klein-Gordon Equation at EqWorld: The World of Mathematical Equations.
★ Nonlinear Klein-Gordon Equation at EqWorld: The World of Mathematical Equations.
★ generalizing the Klein-Gordon equation to include a generalized space
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