The wave equation in the Einstein and de Sitter spacetime

Abstract: We consider the wave propagating in the Einstein & de Sitter spacetime. The covariant d'Alembert's operator in the Einstein & de Sitter spacetime belongs to the family of the non-Fuchsian partial differential operators. We introduce the initial value problem for this equation and give the explicit representation formulas for the solutions. We also show the L p − L q estimates for solutions.

“…This was used in [1] to show that, in the flat case, solutions with initial data of compact support decay as t −1 , that is, as a(t) − 3 2 (but without decay estimates for the time derivative). The same problem was studied further in [11,12], including L p -L q decay estimates and paramatrices. The wave equation in the de Sitter spacetime with flat 3-dimensional spatial sections was analyzed by Rendall [16]; he proved that the time derivative decays at least as e −Ht (with H = Λ/3 being the Hubble constant, where Λ > 0 is the cosmological constant), that is, as a(t) −1 , and conjectured a decay of order e −2Ht , that is, a(t) −2 .…”

Decay of solutions of the wave equation in expanding cosmological spacetimes

“…This was used in [1] to show that, in the flat case, solutions with initial data of compact support decay as t −1 , that is, as a(t) − 3 2 (but without decay estimates for the time derivative). The same problem was studied further in [11,12], including L p -L q decay estimates and paramatrices. The wave equation in the de Sitter spacetime with flat 3-dimensional spatial sections was analyzed by Rendall [16]; he proved that the time derivative decays at least as e −Ht (with H = Λ/3 being the Hubble constant, where Λ > 0 is the cosmological constant), that is, as a(t) −1 , and conjectured a decay of order e −2Ht , that is, a(t) −2 .…”

Decay of solutions of the wave equation in expanding cosmological spacetimes

“…Since φ τ0 − φ τ1 is a solution of the wave equation for τ ≥ τ 1 , the energy inequality (7) and the a priori bound (9) imply…”

“…To prove uniqueness, we note that by using initial data in C ∞ (Σ) approaching φ(τ 0 , · ) in H 1 (Σ) and ∂ τ φ(τ 0 , · ) in L 2 (Σ), it is easy to extend the energy inequality (7) to weak solutions in…”

“…A first example was provided by Klainerman and Sarnak [9], who gave the explicit solution for the wave equation for two particular FLRW models (the so-called Einstein-de Sitter universe and its hyperbolic analogue): their work was used in [1] to prove the existence of solutions bounded at the Big Bang in these two models. The problem of prescribing asymptotic data at the Big Bang for the Einstein-de Sitter universe was further analyzed in [7,8]. More recently, Ringström [11] studied linear systems of wave equations on general cosmological backgrounds with convergent asymptotics, including the problem of imposing asymptotic data.…”

Solutions of the wave equation bounded at the Big Bang

“…Equations with time-dependent coefficients arise in a natural way when studying the physics of an expanding universe. This has attracted considerable interest over the recent years, just to mention a few references we refer to the work of K. Yagdjian, A. Galstian and T. Kinoshita [8,30,9] and sketch the relation to our approach. Especially for the family of Friedmann-Lemaître-Robertson-Walker spacetimes on R 1+n with metrics of the form ds 2 = − dt 2 + 1 a 2 (t) n j=1 dx 2 j , a(t) > 0, (5.39) in an expanding / shrinking universe the covariant Klein-Gordon equation for scalar fields takes the form u tt − a 2 (t)∆u − nȧ with variable mass and dissipation.…”

On t-dependent hyperbolic systems. Part 2