A Higher-Derivative Hubble Parameter Dark Energy Model: Cosmological Analysis and Scalar Field Correspondence
Abstract
In this work, we study a Dark Energy (DE) energy density model which depends on the Hubble parameter squared H2 and on its first, second and third time derivatives H, H and H. Considering a scale factor a with a power-law dependence on the time (with n indicating the power-law index), we obtain some important cosmological quantities as function of the , like the energy densities of Matter m and of DE D, the fractional energy densities of DM m and of DE D, the Hubble parameter squared H2, the deceleration parameter q, the evolutionary form of the fractional energy density of DE 'D, the pressure of DE pD and the Equation of State (EoS) parameter of DE ωD, for both non interacting and interacting cases. For the interacting case, we consider 9 different interacting term Q, all functions of the Hubble parameter H and/or of m and D. Finally, we establish a correspondence between the DE model we study and some scalar field theories, including tachyon, k-essence, quintessence, Yang-Mills (YM) and Nonlinear Electrodynamics (NLED) fields.
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