THE PARAMETERIZED POST-FRIEDMANNIAN FRAMEWORK FOR THE INTERACTING DARK ENERGY IN COSMOLOGICAL MODEL WITH NONMINIMAL DERIVATIVE COUPLING
In almost the last two decades, cosmological observations from measurements of the cosmic microwave background (CMB), Supernovae Ia (SN Ia), and baryon acoustic oscillations (BAO) indicate that the universe is currently in an accelerated expansion phase. The development of this observational evid...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/75140 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | In almost the last two decades, cosmological observations from measurements of
the cosmic microwave background (CMB), Supernovae Ia (SN Ia), and baryon
acoustic oscillations (BAO) indicate that the universe is currently in an accelerated
expansion phase. The development of this observational evidence shows that the
components that fill the universe in the form of cold dark matter (CDM) about 25%
and dark energy (DE) about 70%. These two dark sectors are the main components
of the universe today which are considered to have an influence on the acceleration
of the universe's expansion. The existence of the two dark sectors is only detected
indirectly through gravitational effects so that they have the possibility of
interacting non-gravitationally. The interacting dark energy (IDE) scenario in
which dark energy interacts directly with dark matter (having non-zero coupling
with each other) is one way to reduce or solve the problems that arise in the ?CDM
model, namely namely the fine-tunning and coincidence problems. The ?CDM
model is a cosmological standard model that can describe the universe in
accordance with cosmological observations where dark energy in the form of the
cosmological constant (?) as the dominant filling component of the universe
interacts with dark matter in the form of cold dark matter (CDM).
The true nature of the two dark sectors is not yet known, so one of the main goals
of modern cosmology is to discover the nature of dark energy, which is the dominant
component of the universe in its accelerated expansion phase. To gain a better
understanding of the dark energy nature and its role in the evolution of the universe,
the equation of state and the speed of sound parameters are needed. These two
parameters are important to study in the IDE model because they provide important
information about the behavior and properties of dark energy. The equation of state
explains the correlation between the pressure and the energy density of dark energy
to understand how it affects the evolution of the background universe. At the
perturbation level, the speed of sound is a parameter like the equation of state and
relates pressure disturbances and energy density so that they affect the growth of
structure in the universe. Physicists are still developing the theory of gravity by modifying the cosmological
parameters of Einstein's field equations or called the theory of modified gravity
(MG). The theory of modified gravity must pass the test on the solar system scale.
There are two approaches to performing cosmological tests the theory of modified
gravity. The first approach, a theory of gravity is determined through its
Lagrangian which produces the equations of motion for homogeneous expansion
and cosmological perturbation. The second approach is inspired by the
Parameterized Post-Newtonian (PPN) framework for testing the solar system.
However, at the gigaparsec (Gpc) scale where dark energy appears to be driving
accelerated expansion, there are no more bound test particle orbits to measure. So
based on the cosmological perturbation theory, a different approach is needed to
examine the cosmology of the very common modified gravity. Therefore, a new
formalism is introduced which parameterizes the cosmological perturbation theory
of various modified gravity models. This formalism is known as a Parameterized
Post-Friedmannian (PPF) framework. The formalism of PPF is similar to PPN in
that the cosmological parameters have assumed that some of Einstein's field
equations remain valid under the theory of modified gravity. This PPF formalism
tests the modified gravity model independently to pave the way for independent
models to classify and test IDE theory.
In this dissertation research, a dark energy model with non-minimum coupling
between the curvature and the scalar field derivative or called the non-minimal
derivative coupling (NMDC) of the scalar field has been studied. Modeling dark
energy with NMDC will provide an accelerated expansion of the universe. Here,
the dark energy model with NMDC is modified into a dark energy model that
interacts with dark matter (Interacting Dark Energy, IDE) and is examined whether
its interaction affects the evolution of the equation of state and the speed of sound.
The impact of this interaction implies that the interaction effect on the dark energy
equation of state is much stronger than the effect of varying the speed of sound.
The PPF framework has been applied to various the theory of modified gravity
including the IDE model. In previous research, the IDE model within the PPF
framework has been carried out using a quintessence scenario in which the scalar
field is non-minimum coupling with gravity. Here, the scenario is developed
considering the actions of NMDC. This research begins by studying the
cosmological perturbation of the general perturbation metric with the NMDC
action of the scalar field. Then, the PPF formalism is applied in the Type 1 IDE
model where this model is classified through the field independent function. Thus,
classification of the model can be revealed by looking at the PPF coefficient
resulting from the scalar mode linear perturbation in metric and fluid variables.
Based on the classification of the PPF coefficient results obtained, the
parameterization of the Type 1 IDE model with NMDC corresponds to the type 1
IDE model class without NMDC. Therefore, the IDE model with NMDC is a
subcase of the type 1 IDE model without NMDC.
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