I have been reading an article, and I am not clear on what he does in this one part.
He starts with a Riemmannian manifold $\Sigma$ that is $\mathbb{H}^2/\Gamma$, a quotient of the hyperbolic space by some group of isometries. He then takes an isometry $\tau:\Sigma\rightarrow\Sigma$ and defines $M=\Sigma\times[0,1]/[(x,0)\sim(\tau(x),1)]$ the mapping torus.
It is claimed in the article that if you take a geodesic $\gamma$ in $M$ then the tube around it has a flat metric on it's boundary. This (unless in am missing something) is not true for the product metric. you can take $(t,\rho,z)$ to be your coordinates when $(t,\rho)$ are the Fermi coordinates in $\mathbb{H}^2$ then $ds^2=d\rho^2+cosh^2(\rho)dt^2+dz^2$ will not be flat at the boundary.
The boundary of a tube around a geodesic is flat, if you you think of a quotient of $\mathbb{H}^3$ (and that is what I originally thought he did) but $(x,r)\rightarrow(\tau(x),r+1)$ is not an isometry of $\mathbb{H}^3$, so you cant get $M=\mathbb{H}^3/G$.
Any thought on how this can be done? I thank you all in advance