Cosmological model with macroscopic spin fluid

We consider a Friedmann-Roberston-Walker cosmological model with some exotic perfect fluid with spin known as the Weyssenhoff fluid. The possibility that the dark energy may be described in part by the Weyssenhoff fluid is discussed. The observational constraint coming from supernovae type Ia observations is established. This result indicates that, whereas the cosmological constant is still needed to explain current observations, the model with a spin fluid is admissible. For high redshifts z>1 the differences between the model with spin fluid and the cold dark matter model with a cosmological constant become detectable observationally for the flat case with Ω_m,0=0.3. From the maximum likelihood method we obtain the value of Ω_s,0=0.004±0.016. This gives us the limit Ω_s,0>-0.012 at the 1σ level. While the model with “brane effects” is preferred by the supernovae Ia data, the model with a spin fluid is statistically admissible. For comparison, the limit on the spin fluid coming from cosmic microwave background anisotropies is also obtained. The uncertainties in the location of a first peak give the interval -1.4×10^-10<Ω_s,0<-10^-10. From big bang nucleosynthesis we obtain the strongest limit, Ω_s,0≳-10^-20. The interconnection between the model considered and brane models is also pointed out.