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Can Renormalization Change the Observable Predictions of Inflation? Gonzalo J. Olmo Instituto de Estructura de la Materia - CSIC (Spain) In collaboration with I.Agullo, J.Navarro-Salas, and L.Parker Gonzalo J. Olmo Motivation and Summary ■ ● Motivation and Summary Inflation provides a natural solution to the horizon and flatness problems of the hot Big Bang cosmology. ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 2/13 Motivation and Summary ■ Inflation provides a natural solution to the horizon and flatness problems of the hot Big Bang cosmology. ■ Inflation also provides a Quantum Mechanical mechanism to account for the origin of small inhomogeneities in the early Universe, which represent the seeds for structure formation. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 2/13 Motivation and Summary ■ Inflation provides a natural solution to the horizon and flatness problems of the hot Big Bang cosmology. ■ Inflation also provides a Quantum Mechanical mechanism to account for the origin of small inhomogeneities in the early Universe, which represent the seeds for structure formation. ■ A relic background of gravitational waves is also unavoidable if inflation happened in the early Universe. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 2/13 Motivation and Summary ■ Inflation provides a natural solution to the horizon and flatness problems of the hot Big Bang cosmology. ■ Inflation also provides a Quantum Mechanical mechanism to account for the origin of small inhomogeneities in the early Universe, which represent the seeds for structure formation. ■ A relic background of gravitational waves is also unavoidable if inflation happened in the early Universe. ■ Typically, an inflationary model predicts the value of 3 parameters: ns −1 ◆ Scalar spectral index ns ⇒ Ps (k) = Ps (k0 ) k k0 ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo ◆ Tensor spectral index nt ⇒ Pt (k) = Pt (k0 ) ◆ Tensor-to-scalar ratio r ⇒ r ≡ nt k k0 Pt Ps Porto, 29-31 March, IberiCos 2010 - p. 2/13 Motivation and Summary ■ Inflation provides a natural solution to the horizon and flatness problems of the hot Big Bang cosmology. ■ Inflation also provides a Quantum Mechanical mechanism to account for the origin of small inhomogeneities in the early Universe, which represent the seeds for structure formation. ■ A relic background of gravitational waves is also unavoidable if inflation happened in the early Universe. ■ Typically, an inflationary model predicts the value of 3 parameters: ns −1 ◆ Scalar spectral index ns ⇒ Ps (k) = Ps (k0 ) k k0 ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End ■ Gonzalo J. Olmo ◆ Tensor spectral index nt ⇒ Pt (k) = Pt (k0 ) ◆ Tensor-to-scalar ratio r ⇒ r ≡ nt k k0 Pt Ps These parameters are not independent. Porto, 29-31 March, IberiCos 2010 - p. 2/13 Motivation and Summary ■ Inflation provides a natural solution to the horizon and flatness problems of the hot Big Bang cosmology. ■ Inflation also provides a Quantum Mechanical mechanism to account for the origin of small inhomogeneities in the early Universe, which represent the seeds for structure formation. ■ A relic background of gravitational waves is also unavoidable if inflation happened in the early Universe. ■ Typically, an inflationary model predicts the value of 3 parameters: ns −1 ◆ Scalar spectral index ns ⇒ Ps (k) = Ps (k0 ) k k0 ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo ◆ Tensor spectral index nt ⇒ Pt (k) = Pt (k0 ) ◆ Tensor-to-scalar ratio r ⇒ r ≡ nt k k0 Pt Ps ■ These parameters are not independent. ■ Consistency condition for (single-field) slow roll inflation: r ≡ −8nt Porto, 29-31 March, IberiCos 2010 - p. 2/13 Motivation and Summary ■ So far, observations just provide upper limits on tensor fluctuations. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 3/13 Motivation and Summary ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ■ So far, observations just provide upper limits on tensor fluctuations. ■ Forthcoming high-precision measurements may detect effects of relic gravitational waves and offer a test of the consistency condition r ≡ −8nt ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 3/13 Motivation and Summary ● Motivation and Summary ■ So far, observations just provide upper limits on tensor fluctuations. ■ Forthcoming high-precision measurements may detect effects of relic gravitational waves and offer a test of the consistency condition r ≡ −8nt ■ If observations determine that r 6= −8nt then single-field slow roll inflation would be ruled out !!! ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 3/13 Motivation and Summary ● Motivation and Summary ■ So far, observations just provide upper limits on tensor fluctuations. ■ Forthcoming high-precision measurements may detect effects of relic gravitational waves and offer a test of the consistency condition r ≡ −8nt ■ If observations determine that r 6= −8nt then single-field slow roll inflation would be ruled out !!! ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End We shall argue that Quantum Field Renormalization significantly influences the predictions of primordial perturbations and hence the expected measurable imprint of inflation on the CMB. In particular, we will find a new consistency condition: q ′ 4nt r = 4(1−ns −nt )+ n2 −2n 1 − ns − 2nt′ + (1 − ns )2 − nt′ 2 ′ t Gonzalo J. Olmo t Porto, 29-31 March, IberiCos 2010 - p. 3/13 Motivation and Summary ● Motivation and Summary ■ So far, observations just provide upper limits on tensor fluctuations. ■ Forthcoming high-precision measurements may detect effects of relic gravitational waves and offer a test of the consistency condition r ≡ −8nt ■ If observations determine that r 6= −8nt then single-field slow roll inflation would be ruled out !!! ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End We shall argue that Quantum Field Renormalization significantly influences the predictions of primordial perturbations and hence the expected measurable imprint of inflation on the CMB. In particular, we will find a new consistency condition: q ′ 4nt r = 4(1−ns −nt )+ n2 −2n 1 − ns − 2nt′ + (1 − ns )2 − nt′ 2 ′ t ■ Gonzalo J. Olmo t I will try to justify why renormalization is needed and how it affects the predictions of single field slow roll inflation. Porto, 29-31 March, IberiCos 2010 - p. 3/13 Tensorial Perturbations. Standard Approach. ■ ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method Consider the fluctuating tensorial modes hi j (~x,t) , where gi j = a2 (t)(δi j + hi j ) and a(t) is the expansion factor in the background metric ds2 = −dt 2 + a2 (t)d~x2 . ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 4/13 Tensorial Perturbations. Standard Approach. ■ Consider the fluctuating tensorial modes hi j (~x,t) , where gi j = a2 (t)(δi j + hi j ) ● Motivation and Summary ● Tensor Modes and a(t) is the expansion factor in the background metric ds2 = −dt 2 + a2 (t)d~x2 . ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo ■ The perturbation field hi j can be decomposed into two polarization states both obeying the wave equation ḧ + 3H ḣ − a−2 ∇2 h = 0 Porto, 29-31 March, IberiCos 2010 - p. 4/13 Tensorial Perturbations. Standard Approach. ■ Consider the fluctuating tensorial modes hi j (~x,t) , where gi j = a2 (t)(δi j + hi j ) ● Motivation and Summary ● Tensor Modes and a(t) is the expansion factor in the background metric ds2 = −dt 2 + a2 (t)d~x2 . ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ■ ● Time Dependence ● Testable Effects ● Conclusions The End ■ Gonzalo J. Olmo The perturbation field hi j can be decomposed into two polarization states both obeying the wave equation ḧ + 3H ḣ − a−2 ∇2 h = 0 In slow roll inflation (ε ≡ −Ḣ/H 2 ≪ 1) the form of the modes is q 16πGτπ i~k~x (1) H3/2+ε (−kτ) h~k (~x,t) = − 4(2π) 3 a2 e Porto, 29-31 March, IberiCos 2010 - p. 4/13 Tensorial Perturbations. Standard Approach. ■ Consider the fluctuating tensorial modes hi j (~x,t) , where gi j = a2 (t)(δi j + hi j ) ● Motivation and Summary ● Tensor Modes and a(t) is the expansion factor in the background metric ds2 = −dt 2 + a2 (t)d~x2 . ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ■ ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo The perturbation field hi j can be decomposed into two polarization states both obeying the wave equation ḧ + 3H ḣ − a−2 ∇2 h = 0 ■ In slow roll inflation (ε ≡ −Ḣ/H 2 ≪ 1) the form of the modes is q 16πGτπ i~k~x (1) H3/2+ε (−kτ) h~k (~x,t) = − 4(2π) 3 a2 e ■ In pure de Sitter (ε = 0) the modes take the simple form q −1 −Ht ~ h~k (~x,t) = π2Gk3 (H − ike−Ht )eik~x eikH e Porto, 29-31 March, IberiCos 2010 - p. 4/13 Amplitude of Tensorial Perturbations ■ At early times, the amplitude of oscillations depends on k/a(t) in a way similar to that of a massless field in Minkowski space. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 5/13 Amplitude of Tensorial Perturbations ■ At early times, the amplitude of oscillations depends on k/a(t) in a way similar to that of a massless field in Minkowski space. ■ As time evolves, the physical wavelength reaches the Hubble radius when t = tk ⇒ k/a(tk ) = H(tk ) ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 5/13 Amplitude of Tensorial Perturbations ■ At early times, the amplitude of oscillations depends on k/a(t) in a way similar to that of a massless field in Minkowski space. ■ As time evolves, the physical wavelength reaches the Hubble radius when t = tk ⇒ k/a(tk ) = H(tk ) ■ A few Hubble times after horizon exit (−kτ ≈ 1) the amplitude freezes to ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo the constant value |hk |2 = GH(tk )2 π2 k3 Porto, 29-31 March, IberiCos 2010 - p. 5/13 Amplitude of Tensorial Perturbations ■ At early times, the amplitude of oscillations depends on k/a(t) in a way similar to that of a massless field in Minkowski space. ■ As time evolves, the physical wavelength reaches the Hubble radius when t = tk ⇒ k/a(tk ) = H(tk ) ■ A few Hubble times after horizon exit (−kτ ≈ 1) the amplitude freezes to ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects the constant value |hk ● Conclusions The End ■ |2 = GH(tk )2 π2 k3 The freezing amplitude is usually codified through the quantity ∆2h (k,t) , defined in general by ∆2h = 4πk3 |h~k |2 and evaluated at the horizon crossing time tk (or a few Hubble times after it). Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 5/13 Amplitude of Tensorial Perturbations ■ At early times, the amplitude of oscillations depends on k/a(t) in a way similar to that of a massless field in Minkowski space. ■ As time evolves, the physical wavelength reaches the Hubble radius when t = tk ⇒ k/a(tk ) = H(tk ) ■ A few Hubble times after horizon exit (−kτ ≈ 1) the amplitude freezes to ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects the constant value |hk ● Conclusions The End ■ |2 = GH(tk )2 π2 k3 The freezing amplitude is usually codified through the quantity ∆2h (k,t) , defined in general by ∆2h = 4πk3 |h~k |2 and evaluated at the horizon crossing time tk (or a few Hubble times after it). ■ One finally obtains a nearly “scale free” tensorial power spectrum 2 H(t ) k Pt (k) ≡ 4∆2h = M82 2π P √ where MP = 1/ 8πG is the reduced Planck mass. Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 5/13 Need for renormalization: variance of h(~x,t). ■ ● Motivation and Summary ● Tensor Modes In position space, the variance of the tensorial perturbations is defined as R 3 R ∞ dk 2 2 2 ~ hh i = d k|h~ (~x,t)| = ∆ (k) k 0 k h ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 6/13 Need for renormalization: variance of h(~x,t). ■ k ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions In position space, the variance of the tensorial perturbations is defined as R 3 R ∞ dk 2 2 2 ~ hh i = d k|h~ (~x,t)| = ∆ (k) ■ 0 k h Due to the large k behavior of the modes the above integral is divergent: i R ∞ dk 16πGk3 h a (2+3ε) 2 hh (~x,t)i = 0 k 4π2 a3 k [1 + 2k2 τ2 ] + ... ◆ ◆ First term: quadratic divergence (typical in Minkowski). Second term: logarithmic divergence (typical in expanding universe). The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 6/13 Need for renormalization: variance of h(~x,t). ■ k ● Motivation and Summary ● Tensor Modes ● Amplitude of TM In position space, the variance of the tensorial perturbations is defined as R 3 R ∞ dk 2 2 2 ~ hh i = d k|h~ (~x,t)| = ∆ (k) ■ ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Conclusions k h Due to the large k behavior of the modes the above integral is divergent: i R ∞ dk 16πGk3 h a (2+3ε) 2 hh (~x,t)i = 0 k 4π2 a3 k [1 + 2k2 τ2 ] + ... ◆ ● Testable Effects 0 ◆ First term: quadratic divergence (typical in Minkowski). Second term: logarithmic divergence (typical in expanding universe). The End ■ Gonzalo J. Olmo Little attention has been paid to these divergences: ◆ Sometimes this is bypassed by regarding h(~x,t) as a classical random field and introducing a window function to remove the Fourier modes with large k. But QFT is much more than Quantum Mechanics. Porto, 29-31 March, IberiCos 2010 - p. 6/13 Need for renormalization: variance of h(~x,t). ■ k ● Motivation and Summary ● Tensor Modes ● Amplitude of TM In position space, the variance of the tensorial perturbations is defined as R 3 R ∞ dk 2 2 2 ~ hh i = d k|h~ (~x,t)| = ∆ (k) ■ ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Conclusions k h Due to the large k behavior of the modes the above integral is divergent: i R ∞ dk 16πGk3 h a (2+3ε) 2 hh (~x,t)i = 0 k 4π2 a3 k [1 + 2k2 τ2 ] + ... ◆ ● Testable Effects 0 ◆ First term: quadratic divergence (typical in Minkowski). Second term: logarithmic divergence (typical in expanding universe). The End ■ Little attention has been paid to these divergences: ◆ Sometimes this is bypassed by regarding h(~x,t) as a classical random field and introducing a window function to remove the Fourier modes with large k. But QFT is much more than Quantum Mechanics. ◆ It is also common to consider hh(x1 )h(x2 )i as the basic object. R ∞ dk 2 sin k|~x−~x′ | However, in FRW hh(x1 )h(x2 )i = 0 k ∆h (k) k|~x−~x′ | , so all the nontrivial information is contained in hh2 i , which is ill defined. Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 6/13 Renormalization in momentum space ■ ● Motivation and Summary We regard the variance hh2 i as the basic physical object, which defines the amplitude of fluctuations in position space. ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 7/13 Renormalization in momentum space ■ We regard the variance hh2 i as the basic physical object, which defines the amplitude of fluctuations in position space. ■ We treat h(~x,t) as a quantum entity ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ⇒ RENORMALIZATION IN AN EXPANDING UNIVERSE ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 7/13 Renormalization in momentum space ■ We regard the variance hh2 i as the basic physical object, which defines the amplitude of fluctuations in position space. ■ We treat h(~x,t) as a quantum entity ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ⇒ ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence RENORMALIZATION IN AN EXPANDING UNIVERSE ● Testable Effects ● Conclusions The End Gonzalo J. Olmo ■ Since the physically relevant quantity (power spectrum) is expressed in momentum space, the natural renormalization scheme to apply is the so-called ADIABATIC SUBTRACTION (Parker-Fulling, ’74). The DeWitt-Schwinger method gives the same results. Porto, 29-31 March, IberiCos 2010 - p. 7/13 Renormalization in momentum space ■ We regard the variance hh2 i as the basic physical object, which defines the amplitude of fluctuations in position space. ■ We treat h(~x,t) as a quantum entity ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ⇒ ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence RENORMALIZATION IN AN EXPANDING UNIVERSE ● Testable Effects ● Conclusions ■ Since the physically relevant quantity (power spectrum) is expressed in momentum space, the natural renormalization scheme to apply is the so-called ADIABATIC SUBTRACTION (Parker-Fulling, ’74). The DeWitt-Schwinger method gives the same results. ■ Adiabatic renormalization removes the divergences by subtracting (second order) counterterms mode by mode in the integral The End n 2 h oi R 3 ä 1 1 ȧ 2 (k) − 16πGk + + hh2 iren = 0∞ dk ∆ h k wk a 4π2 a3 2w3k a2 Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 7/13 Renormalization of Tensorial Perturbations ■ ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization Calculations give hh2 iren R ∞ dk 16πGk3 (−τπ) h (1) |H (−kτ)|2 − = 0 k 4π2 2a2 ν i (2+3ε) 2 1 + 2k2 τ2 π(−kτ) ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 8/13 Renormalization of Tensorial Perturbations ■ hh2 iren ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations Calculations give ■ R ∞ dk 16πGk3 (−τπ) h (1) |H (−kτ)|2 − = 0 k 4π2 2a2 ν i (2+3ε) 2 1 + 2k2 τ2 π(−kτ) Therefore, the renormalized expression for ∆2h (k) is ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo ∆˜ 2h (k) = 16πGk3 (−τπ) 4π2 2a2 h i (1) (2+3ε) 2 1 + 2k2 τ2 |Hν (−kτ)|2 − π(−kτ) Porto, 29-31 March, IberiCos 2010 - p. 8/13 Renormalization of Tensorial Perturbations ■ hh2 iren ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations Calculations give ■ ● Scalar Perturbations R ∞ dk 16πGk3 (−τπ) h (1) |H (−kτ)|2 − = 0 k ν 4π2 2a2 i (2+3ε) 2 1 + 2k2 τ2 π(−kτ) Therefore, the renormalized expression for ∆2h (k) is ● Time Dependence ● Testable Effects ∆˜ 2h (k) = ● Conclusions The End ■ 16πGk3 (−τπ) 4π2 2a2 h i (1) (2+3ε) 2 1 + 2k2 τ2 |Hν (−kτ)|2 − π(−kτ) Evaluated at the Hubble radius crossing time we get Pt (k)ren = 8α MP2 where α ≈ 0.904 and ε ≡ −Ḣ/H 2 ≪ 1. Gonzalo J. Olmo H(tk ) 2 ε(tk ) 2π Porto, 29-31 March, IberiCos 2010 - p. 8/13 Renormalization of Tensorial Perturbations ■ hh2 iren ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations Calculations give ■ ● Scalar Perturbations R ∞ dk 16πGk3 (−τπ) h (1) |H (−kτ)|2 − = 0 k ν 4π2 2a2 i (2+3ε) 2 1 + 2k2 τ2 π(−kτ) Therefore, the renormalized expression for ∆2h (k) is ● Time Dependence ● Testable Effects ∆˜ 2h (k) = ● Conclusions The End ■ 16πGk3 (−τπ) 4π2 2a2 h i (1) (2+3ε) 2 1 + 2k2 τ2 |Hν (−kτ)|2 − π(−kτ) Evaluated at the Hubble radius crossing time we get Pt (k)ren = 8α MP2 where α ≈ 0.904 and ε ≡ −Ḣ/H 2 ≪ 1. ■ H(tk ) 2 ε(tk ) 2π Recall that the unrenormalized value is Pt (k) = Gonzalo J. Olmo 8 MP2 H(tk ) 2 2π Porto, 29-31 March, IberiCos 2010 - p. 8/13 Renormalization of Scalar Perturbations ■ Scalar perturbations are commonly studied through the gauge-invariant quantity R (the comoving curvature perturbation) obeying ● Motivation and Summary d2 R k dτ2 ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects dz d R k 2 + 2z dτ dτ + k R k = 0 where z ≡ aφ̇0 /H, and with R k related to the inflaton field fluctuations via R k = −Ψk − φ̇H δφk .. 0 ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 9/13 Renormalization of Scalar Perturbations ■ Scalar perturbations are commonly studied through the gauge-invariant quantity R (the comoving curvature perturbation) obeying ● Motivation and Summary d2 R k dτ2 ● Tensor Modes ● Amplitude of TM ● Need for renormalization where z ≡ aφ̇0 /H, and with R k related to the inflaton field fluctuations via ● Renormalization Method ● Tensor Perturbations R k = −Ψk − φ̇H δφk .. ● Scalar Perturbations ● Time Dependence 0 ● Testable Effects ● Conclusions The End dz d R k 2 + 2z dτ dτ + k R k = 0 ■ Proceeding as before (with care to treat the adiabatic counterterms for the R k field) we get hR h i R (1) (2+3(3ε−η)) ∞ dk 2 2i 2 3 −πτ ren = 0 k 4πk 4(2π)3 z2 |Hµ (−τk)| − π(−kτ) 1 + 2(−kτ)2 where µ = 3/2 + 3ε − η and η = MP2 (V ′′ /V ). Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 9/13 Renormalization of Scalar Perturbations ■ Scalar perturbations are commonly studied through the gauge-invariant quantity R (the comoving curvature perturbation) obeying ● Motivation and Summary d2 R k dτ2 ● Tensor Modes ● Amplitude of TM ● Need for renormalization where z ≡ aφ̇0 /H, and with R k related to the inflaton field fluctuations via ● Renormalization Method ● Tensor Perturbations R k = −Ψk − φ̇H δφk .. ● Scalar Perturbations ● Time Dependence 0 ● Testable Effects ● Conclusions dz d R k 2 + 2z dτ dτ + k R k = 0 ■ The End Proceeding as before (with care to treat the adiabatic counterterms for the R k field) we get hR h i R (1) (2+3(3ε−η)) ∞ dk 2 2i 2 3 −πτ ren = 0 k 4πk 4(2π)3 z2 |Hµ (−τk)| − π(−kτ) 1 + 2(−kτ)2 where µ = 3/2 + 3ε − η and η = MP2 (V ′′ /V ). ■ The renormalized expression for ∆2R (k) is ∆˜ 2 R (k) = Gonzalo J. Olmo 4πk3 (−πτ) 4(2π)3 z2 h i (1) (2+3(3ε−η)) 2 2 |Hµ (−τk)| − π(−kτ) 1 + 2(−kτ)2 Porto, 29-31 March, IberiCos 2010 - p. 9/13 Time Dependence ■ The renormalized amplitudes of the power spectra ∆˜ 2h (k) and ∆˜ 2R (k) inherit the time-dependence of the counterterms. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 10/13 Time Dependence ■ The renormalized amplitudes of the power spectra ∆˜ 2h (k) and ∆˜ 2R (k) inherit the time-dependence of the counterterms. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ■ Since primordial fluctuations acquire classical properties soon after crossing the Hubble radius, we find it natural to evaluate the renormalized spectra at tk , or a few e-folds afterwards. ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 10/13 Time Dependence ■ The renormalized amplitudes of the power spectra ∆˜ 2h (k) and ∆˜ 2R (k) inherit the time-dependence of the counterterms. ● Motivation and Summary ● Tensor Modes ■ Since primordial fluctuations acquire classical properties soon after crossing the Hubble radius, we find it natural to evaluate the renormalized spectra at tk , or a few e-folds afterwards. ■ Assuming n > 1 but nε ≪ 1, we find that (n = number of e−folds) 2 H(t ) 2 k ˜ 2 (k, n) ≈ 2 ◆ ∆ ε(tk )(2n − 3/2) h 2π MP 2 H(t ) 1 k 2 ˜ (k, n) ≈ 2 ◆ ∆ (3ε(tk ) − η(tk ))(2n − 3/2) 2π R 2M ε(t ) ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End P k The result is: r = 16ε(tk ) 3ε(t Gonzalo J. Olmo ε(tk ) k )−η(tk ) Porto, 29-31 March, IberiCos 2010 - p. 10/13 Time Dependence ■ The renormalized amplitudes of the power spectra ∆˜ 2h (k) and ∆˜ 2R (k) inherit the time-dependence of the counterterms. ● Motivation and Summary ● Tensor Modes ■ Since primordial fluctuations acquire classical properties soon after crossing the Hubble radius, we find it natural to evaluate the renormalized spectra at tk , or a few e-folds afterwards. ■ Assuming n > 1 but nε ≪ 1, we find that (n = number of e−folds) 2 H(t ) 2 k ˜ 2 (k, n) ≈ 2 ◆ ∆ ε(tk )(2n − 3/2) h 2π MP 2 H(t ) 1 k 2 ˜ (k, n) ≈ 2 ◆ ∆ (3ε(tk ) − η(tk ))(2n − 3/2) 2π R 2M ε(t ) ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End P k The result is: r = 16ε(tk ) 3ε(t ■ Gonzalo J. Olmo ε(tk ) k )−η(tk ) The standard result r = 16ε(tk ) is recovered only if the counterterms are evaluated at times well after the end of inflation (n > 100). Porto, 29-31 March, IberiCos 2010 - p. 10/13 Time Dependence ■ The renormalized amplitudes of the power spectra ∆˜ 2h (k) and ∆˜ 2R (k) inherit the time-dependence of the counterterms. ● Motivation and Summary ● Tensor Modes ■ Since primordial fluctuations acquire classical properties soon after crossing the Hubble radius, we find it natural to evaluate the renormalized spectra at tk , or a few e-folds afterwards. ■ Assuming n > 1 but nε ≪ 1, we find that (n = number of e−folds) 2 H(t ) 2 k ˜ 2 (k, n) ≈ 2 ◆ ∆ ε(tk )(2n − 3/2) h 2π MP 2 H(t ) 1 k 2 ˜ (k, n) ≈ 2 ◆ ∆ (3ε(tk ) − η(tk ))(2n − 3/2) 2π R 2M ε(t ) ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End P k The result is: r = 16ε(tk ) 3ε(t Gonzalo J. Olmo ε(tk ) k )−η(tk ) ■ The standard result r = 16ε(tk ) is recovered only if the counterterms are evaluated at times well after the end of inflation (n > 100). ■ Though a better understanding of the decoherence processes is necessary to fully determine the time scale at which the quantum-to-classical transition really occurs, our predictions are accurate up to n ∼ 10 − 20). Porto, 29-31 March, IberiCos 2010 - p. 10/13 Testable Effects ■ ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method Renormalization also affects the spectral indices: Standard Values ◆ nt = −2ε ◆ ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions ◆ ns − 1 = 2(η − 3ε) nt′ = −nt (1 − ns + nt ) Renormalized Values ◆ nt = 2(ε − η) (12ε2 −8εη+ξ) 3ε−η ◆ ns − 1 = 2(η − 3ε) + ◆ nt′ = 8ε(ε − η) + 2ξ , where ξ ≡ MP4 (V ′V ′′′ /V 2 ). The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 11/13 Testable Effects ■ Renormalization also affects the spectral indices: ● Tensor Modes ● Amplitude of TM ● Need for renormalization ◆ ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ◆ ● Time Dependence ● Testable Effects ● Conclusions Renormalized Values ◆ nt = 2(ε − η) Standard Values ◆ nt = −2ε ● Motivation and Summary ■ ns − 1 = 2(η − 3ε) nt′ = −nt (1 − ns + nt ) (12ε2 −8εη+ξ) 3ε−η ◆ ns − 1 = 2(η − 3ε) + ◆ nt′ = 8ε(ε − η) + 2ξ , where ξ ≡ MP4 (V ′V ′′′ /V 2 ). We find a new consistency relation for single field inflation The End r = 4(1 − ns − nt ) + Gonzalo J. Olmo 4nt′ nt2 −2nt′ 1 − ns − q 2nt′ + (1 − ns )2 − nt2 Porto, 29-31 March, IberiCos 2010 - p. 11/13 Testable Effects ■ Renormalization also affects the spectral indices: ● Tensor Modes ● Amplitude of TM ● Need for renormalization ◆ ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ◆ ● Time Dependence ● Testable Effects ● Conclusions Renormalized Values ◆ nt = 2(ε − η) Standard Values ◆ nt = −2ε ● Motivation and Summary ■ ns − 1 = 2(η − 3ε) nt′ = −nt (1 − ns + nt ) (12ε2 −8εη+ξ) 3ε−η ◆ ns − 1 = 2(η − 3ε) + ◆ nt′ = 8ε(ε − η) + 2ξ , where ξ ≡ MP4 (V ′V ′′′ /V 2 ). We find a new consistency relation for single field inflation The End r = 4(1 − ns − nt ) + ■ 4nt′ nt2 −2nt′ 1 − ns − q 2nt′ + (1 − ns )2 − nt2 The standard prediction r = −8nt requires nt < 0 . Our prediction also allows for nt ≥ 0 . Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 11/13 Testable Effects ■ Renormalization also affects the spectral indices: ● Tensor Modes ● Amplitude of TM ● Need for renormalization ◆ ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ◆ ● Time Dependence ● Testable Effects ● Conclusions Renormalized Values ◆ nt = 2(ε − η) Standard Values ◆ nt = −2ε ● Motivation and Summary ■ ns − 1 = 2(η − 3ε) nt′ = −nt (1 − ns + nt ) (12ε2 −8εη+ξ) 3ε−η ◆ ns − 1 = 2(η − 3ε) + ◆ nt′ = 8ε(ε − η) + 2ξ , where ξ ≡ MP4 (V ′V ′′′ /V 2 ). We find a new consistency relation for single field inflation The End r = 4(1 − ns − nt ) + ■ 4nt′ nt2 −2nt′ 1 − ns − q 2nt′ + (1 − ns )2 − nt2 The standard prediction r = −8nt requires nt < 0 . Our prediction also allows for nt ≥ 0 . ■ The standard prediction constrains nt′ = −nt (1 − ns + nt ) . In our case nt′ is a new observable !!! Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 11/13 Testable Effects ■ Renormalization also affects the spectral indices: ● Tensor Modes ● Amplitude of TM ● Need for renormalization ◆ ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ◆ ● Time Dependence ● Testable Effects ● Conclusions Renormalized Values ◆ nt = 2(ε − η) Standard Values ◆ nt = −2ε ● Motivation and Summary ■ ns − 1 = 2(η − 3ε) nt′ = −nt (1 − ns + nt ) (12ε2 −8εη+ξ) 3ε−η ◆ ns − 1 = 2(η − 3ε) + ◆ nt′ = 8ε(ε − η) + 2ξ , where ξ ≡ MP4 (V ′V ′′′ /V 2 ). We find a new consistency relation for single field inflation The End r = 4(1 − ns − nt ) + ■ 4nt′ nt2 −2nt′ 1 − ns − q 2nt′ + (1 − ns )2 − nt2 The standard prediction r = −8nt requires nt < 0 . Our prediction also allows for nt ≥ 0 . ■ The standard prediction constrains nt′ = −nt (1 − ns + nt ) . In our case nt′ is a new observable !!! ■ Gonzalo J. Olmo For more details and references see Phys.Rev. D81,043514(2010). Porto, 29-31 March, IberiCos 2010 - p. 11/13 Conclusions ■ ● Motivation and Summary ● Tensor Modes The predictions of (single-field) slow-roll inflation change significantly if renormalization in curved spacetimes is taken into account and the counterterms are evaluated around the time of Hubble horizon exit. ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 12/13 Conclusions ■ The predictions of (single-field) slow-roll inflation change significantly if renormalization in curved spacetimes is taken into account and the counterterms are evaluated around the time of Hubble horizon exit. ■ Renormalization provides a new consistency condition that relates the tensor-to-scalar amplitude ratio with the spectral indices. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions The End ε r = 16ε 3ε−η nt = 2(ε − η) ns − 1 = 2(η − 3ε) + (12ε2 −8εη+ξ) 3ε−η nt′ = 8ε(ε − η) + 2ξ Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 12/13 Conclusions ■ The predictions of (single-field) slow-roll inflation change significantly if renormalization in curved spacetimes is taken into account and the counterterms are evaluated around the time of Hubble horizon exit. ■ Renormalization provides a new consistency condition that relates the tensor-to-scalar amplitude ratio with the spectral indices. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions ε r = 16ε 3ε−η The End nt = 2(ε − η) ns − 1 = 2(η − 3ε) + (12ε2 −8εη+ξ) 3ε−η nt′ = 8ε(ε − η) + 2ξ ■ Gonzalo J. Olmo Only when the counterterms are evaluated at times well beyond the end of inflation does one recover the standard predictions. A deeper understanding of the quantum-to-classical transition is necessary. Porto, 29-31 March, IberiCos 2010 - p. 12/13 Conclusions ■ The predictions of (single-field) slow-roll inflation change significantly if renormalization in curved spacetimes is taken into account and the counterterms are evaluated around the time of Hubble horizon exit. ■ Renormalization provides a new consistency condition that relates the tensor-to-scalar amplitude ratio with the spectral indices. ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions ε r = 16ε 3ε−η The End nt = 2(ε − η) ns − 1 = 2(η − 3ε) + (12ε2 −8εη+ξ) 3ε−η nt′ = 8ε(ε − η) + 2ξ Gonzalo J. Olmo ■ Only when the counterterms are evaluated at times well beyond the end of inflation does one recover the standard predictions. A deeper understanding of the quantum-to-classical transition is necessary. ■ The new generation of high precision detectors may soon turn QFT in curved spacetimes into an experimental science. Our results indicate that renormalization may play an important role in the interpretation of the observational data. Porto, 29-31 March, IberiCos 2010 - p. 12/13 ● Motivation and Summary ● Tensor Modes ● Amplitude of TM ● Need for renormalization ● Renormalization Method ● Tensor Perturbations ● Scalar Perturbations ● Time Dependence ● Testable Effects ● Conclusions Thanks !!! The End Gonzalo J. Olmo Porto, 29-31 March, IberiCos 2010 - p. 13/13
