Savart: Difference between revisions

Revision as of 19:58, 1 June 2013

The Stewart–Walker lemma provides necessary and sufficient conditions for the linear perturbation of a tensor field to be gauge-invariant. $\Delta \delta T=0$ if and only if one of the following holds

1. $T_{0}=0$

2. $T_{0}$ is a constant scalar field

3. $T_{0}$ is a linear combination of products of delta functions $\delta _{a}^{b}$

Derivation

A 1-parameter family of manifolds denoted by ${\mathcal {M}}_{\epsilon }$ with ${\mathcal {M}}_{0}={\mathcal {M}}^{4}$ has metric $g_{ik}=\eta _{ik}+\epsilon h_{ik}$ . These manifolds can be put together to form a 5-manifold ${\mathcal {N}}$ . A smooth curve $\gamma$ can be constructed through ${\mathcal {N}}$ with tangent 5-vector $X$ , transverse to ${\mathcal {M}}_{\epsilon }$ . If $X$ is defined so that if $h_{t}$ is the family of 1-parameter maps which map ${\mathcal {N}}\to {\mathcal {N}}$ and $p_{0}\in {\mathcal {M}}_{0}$ then a point $p_{\epsilon }\in {\mathcal {M}}_{\epsilon }$ can be written as $h_{\epsilon }(p_{0})$ . This also defines a pull back $h_{\epsilon }^{*}$ that maps a tensor field $T_{\epsilon }\in {\mathcal {M}}_{\epsilon }$ back onto ${\mathcal {M}}_{0}$ . Given sufficient smoothness a Taylor expansion can be defined

h_{\epsilon }^{*}(T_{\epsilon })=T_{0}+\epsilon \,h_{\epsilon }^{*}({\mathcal {L}}_{X}T_{\epsilon })+O(\epsilon ^{2})

$\delta T=\epsilon h_{\epsilon }^{*}({\mathcal {L}}_{X}T_{\epsilon })\equiv \epsilon ({\mathcal {L}}_{X}T_{\epsilon })_{0}$ is the linear perturbation of $T$ . However, since the choice of $X$ is dependent on the choice of gauge another gauge can be taken. Therefore the differences in gauge become $\Delta \delta T=\epsilon ({\mathcal {L}}_{X}T_{\epsilon })_{0}-\epsilon ({\mathcal {L}}_{Y}T_{\epsilon })_{0}=\epsilon ({\mathcal {L}}_{X-Y}T_{\epsilon })_{0}$ . Picking a chart where $X^{a}=(\xi ^{\mu },1)$ and $Y^{a}=(0,1)$ then $X^{a}-Y^{a}=(\xi ^{\mu },0)$ which is a well defined vector in any ${\mathcal {M}}_{\epsilon }$ and gives the result

\Delta \delta T=\epsilon {\mathcal {L}}_{\xi }T_{0}.\,

The only three possible ways this can be satisfied are those of the lemma.

Sources

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20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

My blog: http://www.primaboinca.com/view_profile.php?userid=5889534 Describes derivation of result in section on Lie derivatives

Template:Refend

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-year-old Power Era Seed Operator Houston Nordahl from Fort Saskatchewan, has lots of interests that include physical exercise (aerobics weights), [http://www.comoganhardinheiro101.com/perguntas-frequentes/ como ganhar dinheiro] na internet and traveling. Preceding year just made a trip Old Walled City of Shibam.
+The '''Stewart–Walker lemma''' provides necessary and sufficient conditions for the [[linear]] [[wiktionary:perturbation|perturbation]] of a [[tensor]] field to be [[gauge theory|gauge]]-invariant. <math>\Delta \delta T = 0</math> [[if and only if]] one of the following holds
+. <math>T_{0} = 0</math>
+. <math>T_{0}</math> is a constant scalar field
+. <math>T_{0}</math> is a linear combination of products of delta functions <math>\delta_{a}^{b}</math>
+== Derivation ==
+A 1-parameter family of manifolds denoted by <math>\mathcal{M}_{\epsilon}</math> with <math>\mathcal{M}_{0} = \mathcal{M}^{4}</math> has [[Metric (mathematics)|metric]] <math>g_{ik} = \eta_{ik} + \epsilon h_{ik}</math>. These manifolds can be put together to form a 5-manifold <math>\mathcal{N}</math>. A smooth curve <math>\gamma</math> can be constructed through <math>\mathcal{N}</math> with tangent 5-vector <math>X</math>, transverse to <math>\mathcal{M}_{\epsilon}</math>. If <math>X</math> is defined so that  if <math>h_{t}</math> is the family of 1-parameter maps which map <math>\mathcal{N} \to \mathcal{N}</math> and <math>p_{0} \in \mathcal{M}_{0}</math> then a point <math>p_{\epsilon} \in \mathcal{M}_{\epsilon}</math> can be written as <math>h_{\epsilon}(p_{0})</math>. This also defines a [[pullback (differential geometry)|pull back]] <math>h_{\epsilon}^{*}</math> that maps a tensor field <math>T_{\epsilon} \in \mathcal{M}_{\epsilon} </math> back onto <math>\mathcal{M}_{0}</math>. Given sufficient smoothness a Taylor expansion can be defined
+:<math>h_{\epsilon}^{*}(T_{\epsilon}) = T_{0} + \epsilon \, h_{\epsilon}^{*}(\mathcal{L}_{X}T_{\epsilon}) + O(\epsilon^{2})</math>
+<math>\delta T = \epsilon h_{\epsilon}^{*}(\mathcal{L}_{X}T_{\epsilon}) \equiv \epsilon (\mathcal{L}_{X}T_{\epsilon})_{0}</math> is the linear perturbation of <math>T</math>. However, since the choice of <math>X</math> is dependent on the choice of [[Gauge theory|gauge]] another gauge can be taken. Therefore the differences in gauge become <math>\Delta \delta T = \epsilon(\mathcal{L}_{X}T_{\epsilon})_0 - \epsilon(\mathcal{L}_{Y}T_{\epsilon})_0 = \epsilon(\mathcal{L}_{X-Y}T_\epsilon)_0</math>. Picking a [[Chart (topology)|chart]] where <math>X^{a} = (\xi^\mu,1)</math> and <math>Y^a = (0,1)</math> then <math>X^{a}-Y^{a} = (\xi^{\mu},0)</math> which is a well defined vector in any <math>\mathcal{M}_\epsilon</math> and gives the result
+:<math>\Delta \delta T = \epsilon \mathcal{L}_{\xi}T_0.\,</math>
+The only three possible ways this can be satisfied are those of the lemma.
+== Sources ==
+{{refbegin}}
+* {{cite book | author=Stewart J. | title=Advanced General Relativity | location=Cambridge | publisher=Cambridge University Press | year=1991 | isbn=0-521-44946-4}}  Describes derivation of result in section on Lie derivatives
+{{refend}}
+{{DEFAULTSORT:Stewart-Walker lemma}}
+[[Category:Tensors]]
+[[Category:Lemmas]]

Savart: Difference between revisions

Revision as of 19:58, 1 June 2013

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