The Consistent Result of Cosmological Constant From Quantum Cosmology and Inflation with Born-Infeld Scalar Field
Abstract
The Quantum cosmology with Born-Infeld(B-I) type scalar field is considered. In the extreme limits of small cosmological scale factor the wave function of the universe can also be obtained by applying the methods developed by Hartle-Hawking(H-H) and Vilenkin. H-H wave function predicts that most Probable cosmological constant equals to 1η(12η equals to the maximum of the kinetic energy of scalar field). It is different from the original results(=0) in cosmological constant obtained by Hartle-Hawking. The Vilenkin wave function predicts a nucleating unverse with largest possible cosmological constant and it is larger than 1/η. The conclusions have been nicely to reconcile with cosmic inflation. We investigate the inflation model with B-I type scalar field, and find that η depends on the amplitude of tensor perturbation δh, with the form 1η m212π[(9δ2N δh2)2-1]. The vacuum energy in inflation epoch depends on the tensor-to-scalar ratio δhδ. The amplitude of the tensor perturbation δh can, in principle, be large enough to be discovered. However, it is only on the border of detectability in future experiments. If it has been observed in future, this is very interesting to determine the vacuum energy in inflation epoch.
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