Fermi coordinates

In the mathematical theory of Riemannian geometry, there are two uses of the term Fermi coordinates. In one use they are local coordinates that are adapted to a geodesic.^[1] In a second, more general one, they are local coordinates that are adapted to any world line, even not geodesical.^[2]

Take a future-directed timelike curve ${\displaystyle \gamma =\gamma (\tau )}$, ${\displaystyle \tau }$ being the proper time along ${\displaystyle \gamma }$ in the spacetime ${\displaystyle M}$. Assume that ${\displaystyle p=\gamma (0)}$ is the initial point of ${\displaystyle \gamma }$.

Fermi coordinates adapted to ${\displaystyle \gamma }$ are constructed this way.

Consider an orthonormal basis of ${\displaystyle TM}$ with ${\displaystyle e_0}$ parallel to ${\displaystyle \dot{\gamma }}$.

Transport the basis ${\displaystyle \{e_a{\}}_{a=0,1,2,3}}$along ${\displaystyle \gamma (\tau )}$ making use of Fermi-Walker's transport. The basis ${\displaystyle \{e_a(\tau ){\}}_{a=0,1,2,3}}$ at each point ${\displaystyle \gamma (\tau )}$ is still orthonormal with ${\displaystyle e_0(\tau )}$ parallel to ${\displaystyle \dot{\gamma }}$ and is non-rotated (in a precise sense related to the decomposition of Lorentz transformations into pure transformations and rotations) with respect to the initial basis, this is the physical meaning of Fermi-Walker's transport.

Finally construct a coordinate system in an open tube ${\displaystyle T}$, a neighbourhood of ${\displaystyle \gamma }$, emitting all spacelike geodesics through ${\displaystyle \gamma (\tau )}$ with initial tangent vector ${\displaystyle {\displaystyle \sum _{i=1}^3}{v}^i{e}_i(\tau )}$, for every ${\displaystyle \tau }$.

A point ${\displaystyle q\in T}$ has coordinates ${\displaystyle \tau (q),v^1(q),v^2(q),v^3(q)}$ where ${\displaystyle {\displaystyle \sum _{i=1}^3}{v}^i{e}_i(\tau (q))}$ is the only vector whose associated geodesic reaches ${\displaystyle q}$ for the value of its parameter ${\displaystyle s=1}$ and ${\displaystyle \tau (q)}$ is the only time along ${\displaystyle \gamma }$ for that this geodesic reaching ${\displaystyle q}$ exists.

If ${\displaystyle \gamma }$ itself is a geodesic, then Fermi-Walker's transport becomes the standard parallel transport and Fermi's coordinates become standard Riemannian coordinates adapted to ${\displaystyle \gamma }$. In this case, using these coordinates in a neighbourhood ${\displaystyle T}$ of ${\displaystyle \gamma }$, we have ${\displaystyle {\mathrm{\Gamma }}_{bc}^a=0}$, all Christoffel symbols vanish exactly on ${\displaystyle \gamma }$. This property is not valid for Fermi's coordinates however when ${\displaystyle \gamma }$ is not a geodesic. Such coordinates are called Fermi coordinates and are named after the Italian physicist Enrico Fermi. The above properties are only valid on the geodesic. The Fermi-Coordinates adapted to a null geodesic is provided by Mattias Blau, Denis Frank, and Sebastian Weiss.^[3] Notice that, if all Christoffel symbols vanish near ${\displaystyle p}$, then the manifold is flat near ${\displaystyle p}$.

• Proper reference frame (flat spacetime)
• Geodesic normal coordinates
• Fermi-Walker transport
• Christoffel symbols
• Isothermal coordinates

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