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equations:klein-gordon_equation [2018/03/29 13:55] leot221 [Concrete] |
equations:klein-gordon_equation [2019/07/30 08:46] 60.52.77.62 [Klein-Gordon Equation] |
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<tabbox Intuitive> | <tabbox Intuitive> | ||
- | <note tip> | + | The Klein-Gordon equation describes how the state of a relativistic (= fast moving) quantum system without spin changes in time. |
- | Explanations in this section should contain no formulas, but instead colloquial things like you would hear them during a coffee break or at a cocktail party. | + | |
- | </note> | + | The analogous equation for systems with half-integer spin is the [[equations:dirac_equation|]]. |
+ | |||
+ | If the system only moves slowly, the Klein-Gordon equation becomes the [[equations:schroedinger_equation]]. | ||
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<tabbox Concrete> | <tabbox Concrete> | ||
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using the [[equations:euler_lagrange_equations|Euler-Lagrange equations]]. | using the [[equations:euler_lagrange_equations|Euler-Lagrange equations]]. | ||
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+ | ---- | ||
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+ | **Solutions** | ||
+ | |||
+ | The most general solution of the Klein-Gordon equation is\begin{equation}\label{KGsol} \Phi(x)= \int \mathrm{d }k^3 \frac{1}{(2\pi)^3 2\omega_k} \left( a(k){\mathrm{e }}^{ -i(k x)} + a^\dagger(k) {\mathrm{e }}^{ i(kx)}\right) .\end{equation} | ||
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<tabbox Why is it interesting?> | <tabbox Why is it interesting?> | ||
- | The Klein-Gordon equation is the correct equation of motion that describes free [[basic_notions:spin|spin]] $1$ particles. | + | The Klein-Gordon equation is the correct equation of motion that describes free [[basic_notions:spin|spin]] $0$ particles. |
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* $\partial _{\mu} $ denotes the partial derivative and $\partial _{\mu} \partial ^{\mu}$ stands for a sum using the Einstein sum convention, i.e. $\partial _{\mu} \partial ^{\mu} = \partial _0 \partial^0 - \partial _1 \partial^1 -\partial _2 \partial^2 -\partial _3 \partial^3$, | * $\partial _{\mu} $ denotes the partial derivative and $\partial _{\mu} \partial ^{\mu}$ stands for a sum using the Einstein sum convention, i.e. $\partial _{\mu} \partial ^{\mu} = \partial _0 \partial^0 - \partial _1 \partial^1 -\partial _2 \partial^2 -\partial _3 \partial^3$, | ||
* $m$ denotes the mass of the particle, | * $m$ denotes the mass of the particle, | ||
- | * $\Phi$ is either the wave function of the spin $0$ particle if we use the Klein-Gordon equation in a particle theory, or describes the spin $0$ field if we work in a field theory. | + | * $\Phi$ describes the spin $0$ field if we work in a field theory. |
+ | * Note: $\Phi$ cannot be interpreted as a wavefunction because it is a real valued field; it is its own anti-particle like the Majorana fermion. Only in the case that it is the U(1)-charged (requires 2 independent real Klein Gordon fields that are symmetry transform into each other) is a naive wavefunction interpretation possible. Basically, you get a relativistic scalar superfluid field. Nevertheless, there are single particle wavefunctions lurking in the single real Klein-Gordon theory. But you need to use the coherent state representation to see the 1st quantized operators from the complex annihilation and creation operators. Essentially undoing the second quantization. | ||