The Cosmological Constant 237Explaining simultaneously all these and still other data, all consistent with an infla-
tionary cold dark matter model with a cosmological constant, requires an accelerat-
ing universe. Recent supernova data plotted in Figure 11.1 as퐻(푧)∕( 1 +푧)versus푧[5]
show that an early deceleration followed by a recent acceleration is favored, determin-
ing the time of transition from deceleration to acceleration to푧= 0. 74 ± 0 .05. Observa-
tions of baryonic acoustic oscillations [6] plotted in Figure 11.2 as퐻(푧)∕( 1 +푧)versus
푧determine this moment to have occurred at푧≈ 0 .8.
Dynamical Models. The cosmological constant corresponds to static gravity with
the equation of state푤=−1 as in Equation (5.28). If푤were a function of the scale푎
the expansion history would be different, but unfortunately all functions aread hoc.
Some simple one-parameter formulas are
푤(푧)=푤 0 +푤 1 푧, (11.1)and
푤(푎)=푤 0 +푤 1 ( 1 −푎). (11.2)
One relatively successful two-parameter formula is
푤(푎)=푤 0 [ 1 +푏ln( 1 +푧)]−^2. (11.3)The advantage of this formula is that it covers the whole observed range of푧.
90807060504030
0.0 0.5 1.0Simon9
Stern2
Moresco8
Buscal
Zhang4
Blake3
Chuang1zH
(z
)/(1+
z)1.5 2.0Figure 11.1Evidence for transition from deceleration in the past to acceleration today. From
reference [6]. From Farook, O. and Ratra, B., Hubble parameter measurement constraints
on the cosmological deceleration-acceleration transition redshift,Astrophys. J. Lett., 766 ,L7,
published 4 March 2013. © AAS. Reproduced with permission. (See plate section for color
version.)