2019
DOI: 10.1103/physrevlett.122.251301
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Rapid-Turn Inflationary Attractors

Abstract: We prove the existence of a general class of rapidly turning two-field inflationary attractors. By only requiring a large, slowly varying turn rate, we solve the system completely without specifying any metric or potential, and prove the linear stability of the solution. Several recently studied turning inflation models, including hyperinflation, side-tracked inflation, and a flat field-space model, turn out to be examples of this general class of attractor solutions. Very rapidly turning models are of particu… Show more

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Cited by 55 publications
(93 citation statements)
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“…In this ultralight limit, the value of β becomes suppressed by the amount of efolds elapsed from the moment in which the mode crossed the horizon and the end of inflation (similarly, in ref. [24] an analytical expression for the power spectrum was obtained for large values of λ in which a superhorizon growth is reported, in agreement with a suppressed value of β for large values of λ). The numerical result shown in Figure 1 allows us to see how β behaves for intermediate regimes that have not been solved analytically.…”
Section: Perturbationssupporting
confidence: 76%
“…In this ultralight limit, the value of β becomes suppressed by the amount of efolds elapsed from the moment in which the mode crossed the horizon and the end of inflation (similarly, in ref. [24] an analytical expression for the power spectrum was obtained for large values of λ in which a superhorizon growth is reported, in agreement with a suppressed value of β for large values of λ). The numerical result shown in Figure 1 allows us to see how β behaves for intermediate regimes that have not been solved analytically.…”
Section: Perturbationssupporting
confidence: 76%
“…Let us also point out that when more than two fields are present, one can define a turning rate associated to every normal direction and they will contribute to the total turning rate 10 Recent multifield inflation investigations have pointed out that small turning rates are not necessary for a successful period of slow-roll inflation [23][24][25][26][27][28], as we showed explicitly above. Most of these studies focus on the case of non-zero negative curvature of the scalar manifold.…”
Section: Slow-roll Fat Inflation and Large Turnsmentioning
confidence: 90%
“…The adiabatic mass squared m 2 T is given by 26) and the entropy mass M is given by 27) where V N N = N i N j ∇ i ∇ j V and R is the scalar manifold's Ricci scalar. At superhorizon scales, (2.24) becomesQ 28) and one can define an effective entropy mass as M 2 ef f = M 2 + 4Ω 2 .…”
Section: Dynamics Of the Linear Perturbationsmentioning
confidence: 99%
“…Over the last few years there has been much interest in two-field inflation models with strongly non-geodesic motion . These models have been studied under various names (such as spinflation, hyperinflation, side-tracked inflation, angular inflation, and effective single-field theories with a reduced speed of sound from heavy fields), but have recently been shown to belong to a general class of solutions known as 'rapid-turn attractors' [4]. Intriguingly, inflation models with rapidly turning fields can be realised in potentials that are much too steep for standard slow-roll inflation [22,30], and may thereby ameliorate the so-called inflationary 'η-problem' [31,32].…”
Section: Introductionmentioning
confidence: 99%