In the context of dynamical breaking of local supersymmetry (supergravity), including the DeserZumino super-Higgs effect, for the simple but quite representative cases of N = 1, D = 4 supergravity, we discuss the emergence of Starobinsky-type inflation, due to quantum corrections in the effective action arising from integrating out gravitino fields in their massive phase. This type of inflation may occur after a first-stage small-field inflation that characterises models near the origin of the one-loop effective potential, and it may occur at the non-trivial minima of the latter. Phenomenologically realistic scenarios, compatible with the Planck data, may be expected for the conformal supergravity variants of the basic model. This short article serves as an addendum to our previous publication [1], where we discussed dynamical breaking of supergravity (SUGRA) theories via gravitino condensation. In particular, we shall demonstrate the compatibility of this scenario with Starobinsky-like [2] inflationary scenarios, which in our case can characterise the massive gravitino phase. As we shall argue, this is a second inflationary phase, that may succeed a first inflation which occurs in the flat region of the one-loop effective potential for the gravitino condensate field [3].Starobinsky inflation is a model for obtaining a de Sitter (inflationary) cosmological solution to gravitational equations arising from a (four space-time-dimensional) action that includes higher curvature terms, specifically of the type in which the quadratic curvature corrections consist only of scalar curvature terms [2]where κ 2 = 8πG, and G = 1/m 2 P is Newton's (gravitational) constant in four space-time dimensions, with m P the Planck mass, and M is a constant of mass dimension one, characteristic of the model.The important feature of this model is that inflationary dynamics are driven by the purely gravitational sector, through the R 2 terms, and the scale of inflation is linked to M. From a microscopic point of view, the scalar curvature-squared terms in (1) are viewed as the result of quantum fluctuations (at one-loop level) of conformal (massless or high energy) matter fields of various spins, which have been integrated out in the relevant path integral in a curved background space-time [4]. The quantum mechanics of this model, by means of tunneling of the Universe from a state of "nothing" to the inflationary phase of ref. [2] has been discussed in detail in [5]. The above considerations necessitate truncation to one-loop quantum order and to curvature-square (four-derivative) terms, which implies that there must be a region of validity for curvature invariants such that O R 2 /m 4 p 1, which is a condition satisfied in phenomenologically realistic scenarios of inflation [6,7], for which the inflationary Hubble scale H I ≤ 0.74 × 10 −5 m P = O(10 15 ) GeV (the reader should recall that R ∝ H 2 I in the inflationary phase).Although the inflation in this model is not driven by fundamental rolling scalar fields, nevertheless the model (...
