A generalized Hartle-Hawking wave function

The Hartle-Hawking wave function is known to be the Fourier dual of the Chern-Simons or Kodama state reduced to mini-superspace, using an integration contour covering the whole real line. But since the Chern-Simons state is a solution of the Hamiltonian constraint (with a given ordering), its Fourier dual should provide a solution (i.e. beyond mini-superspace) of the Wheeler DeWitt equation representing the Hamiltonian constraint in the metric representation. We write down a formal expression for such a wave function, to be seen as the generalization beyond mini-superspace of the Hartle-Hawking wave function. Its explicit evaluation (or simplification) depends only on the symmetries of the problem, and we illustrate the procedure with anisotropic Bianchi models and with the Kantowski-Sachs model. A significant difference of this approach is that we may leave the torsion inside the wave functions when we set up the ansatz for the connection, rather than setting it to zero before quantization. This allows for quantum fluctuations in the torsion, with far reaching consequences.

Automated summary

This article discusses the Fourier dual of the Hartle-Hawking wave function and its generalization beyond mini-superspace. The evaluation of this wave function depends on the symmetries of the problem and is illustrated using anisotropic Bianchi models and the Kantowski-Sachs model. An important aspect of this approach is the inclusion of quantum fluctuations in the torsion, which has significant consequences.