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--- equations:klein-gordon_equation [2018/03/13 11:18]
jakobadmin
+++ equations:klein-gordon_equation [2019/07/30 08:32]
60.52.77.62 [Klein-Gordon Equation]
@@ Line 1: / Line 1: @@
-====== Klein-Gordon Equation ======
+<WRAP lag>$  ( \partial _{\mu} \partial ^{\mu}+m^2)\Phi = 0 $</WRAP>
+====== Klein-Gordon Equation   ======
-<note tip> $$( \partial _{\mu} \partial ^{\mu}+m^2)\Phi = 0 $$
+<tabbox Intuitive>
--->Definitions#
-  * $\partial _{\mu} $ denotes the partial derivative and $\partial _{\mu} \partial ^{\mu}$ stands for a sum using the Einstein sum convention, i.e. $\partial _{\mu} \partial ^{\mu} =  \partial _0 \partial^0 - \partial _1 \partial^1 -\partial _2 \partial^2 -\partial _3 \partial^3$.
+The Klein-Gordon equation describes how the state of a relativistic (= fast moving) quantum system without spin changes in time.
-  * $m$ 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.
+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]].
-</note>
-<tabbox Why is it interesting?>
+<tabbox Concrete>
+The Klein-Gordon equation can be derived from the Lagrangian
-The Klein-Gordon equation is the correct equation of motion that describes free [[basic_notions:spin|spin]] $1$ particles.
+\begin{equation} \mathscr{L}= \frac{1}{2}( \partial _{\mu} \Phi \partial ^{\mu} \Phi -m^2 \Phi^2) \end{equation}
+using the [[equations:euler_lagrange_equations|Euler-Lagrange equations]].
-<tabbox Layman>
+----
-<note tip>
+**Solutions**
-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 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}
-<tabbox Student>
+----
   * A nice discussion can be found in [[http://www.quantumfieldtheory.info/website_Chap03.pdf |chapter 3 of Klauber's Student Friendly QFT book]]
   * For an elementary derivation of the Klein-Gordon equation see Physics from Symmetry by Schwichtenberg
-<tabbox Researcher>
+<tabbox Abstract>
 <note tip>
@@ Line 35: / Line 36: @@
 </note>
---> Common Question 1#
+<tabbox Why is it interesting?>
+The Klein-Gordon equation is the correct equation of motion that describes free [[basic_notions:spin|spin]] $0$ particles.
-<--
---> Common Question 2#
-<--
-<tabbox Examples>
+<tabbox Definitions>
---> Example1#
+  * $\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,
+  * $\Phi$ 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.
---> Example2:#
-<--
-<tabbox History>
 </tabbox>

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