On a critical acceleration scale of dark matter in Lambda-CDM and dynamical dark energy

Abstract

Universal acceleration a0 emerges in various empirical laws, yet its fundamental nature remains unclear. Using Illustris and Virgo N-body simulations, we propose a0 is the scale of acceleration fluctuations in collisionless dark matter involving long-range gravity. In contrast, in the kinetic theory of gases, molecules undergo random elastic collisions involving short-range interactions, where only velocity fluctuations are relevant. We identify the redshift evolution a0 (1+z)3/4 that is in good agreement with Magneticum and EAGLE simulations and in reasonable agreement with limited observations. This suggests a larger a0 at a higher redshift such that galaxies of fixed baryonic mass rotate faster at a higher redshift. The velocity fluctuations involve a critical velocity uc (1+z)-3/4. The acceleration fluctuations involve a critical acceleration ac (1+z)3/4. Two critical quantities are related by the rate of energy cascade u≈ -ac uc/[2(3π)2], where factor 3π is from the angle of incidence and u≈ -10-7m2/s3. With critical velocity uc on the order of 300 km/s at z=0, the critical acceleration is determined to be ac0 ac(z=0) ≈ 10-10m/s2, suggesting ac might explain the universal acceleration a0≈ 10-10m/s2 in the empirical Tully-Fisher relation or modified Newtonian dynamics (MOND). Note that dark energy (DE) density DE0≈ ac02/G=10-10J/m3, we postulate an entropic origin of the dark energy from acceleration fluctuations of dark matter, in analogy to the gas pressure from velocity fluctuations. This leads to a dynamical dark energy coupled to the structure evolution involving a relatively constant DE density followed by a slow weakening phase, suggesting possible deviations from the standard .