As dense and hot bodies with a well-understood equation of state, white dwarfs offer a unique opportunity to investigate new physics. In this paper, we examine the role of dark sectors, which are extensions of the Standard Model of particle physics that are not directly observable, in the cooling process of white dwarfs. Specifically, we examine the role of a dark photon, within the framework of a three-portal Model, in enhancing the neutrino emission during the cooling process of white dwarfs. We compare this scenario to the energy release predicted by the Standard Model. By analyzing the parameter space of dark sectors, our study aims to identify regions that could lead to significant deviations from the expected energy release of white d...
In many models of dark matter (DM), several production mechanisms contribute to its final abundance,...
We investigate electromagnetic and gravitational radiation generated during a process of the tidal s...
Hot new early dark energy describes a supercooled, first-order phase transition that takes place at ...
The evolution of white dwarfs (WDs) depends crucially on thermal processes. The plasma in their core...
The white dwarf luminosity function, which provides information about their cooling, has been measur...
We study the effects of light QCD axions on the stellar configuration of white dwarfs. At finite bar...
The evolution of white dwarfs is essentially a gravothermal process of cooling in which the basic in...
A recent analysis of the 100 pc white dwarf sample in the SDSS footprint demonstrated for the first ...
White dwarfs cool through several processes, including the emission of weakly interacting particles ...
A simple cooling model of white dwarf stars is re-analyzed in Palatini $f(R)$ gravity. Modified grav...
We report on the spectroscopic confirmation of 68 new bright ($G=13.5-17.2$ mag) and blue (pre-)whit...
Dark matter can be part of a dark sector with non-minimal couplings to the Standard Model. Compared ...
White dwarfs (WDs) are the final evolutionary product of the vast majority of stars in the Universe....
We show that rotating white dwarfs admixed with dark matter have interesting properties that may be ...
This thesis is about deriving a few equations of state for white dwarfs below the regime of neutron...
In many models of dark matter (DM), several production mechanisms contribute to its final abundance,...
We investigate electromagnetic and gravitational radiation generated during a process of the tidal s...
Hot new early dark energy describes a supercooled, first-order phase transition that takes place at ...
The evolution of white dwarfs (WDs) depends crucially on thermal processes. The plasma in their core...
The white dwarf luminosity function, which provides information about their cooling, has been measur...
We study the effects of light QCD axions on the stellar configuration of white dwarfs. At finite bar...
The evolution of white dwarfs is essentially a gravothermal process of cooling in which the basic in...
A recent analysis of the 100 pc white dwarf sample in the SDSS footprint demonstrated for the first ...
White dwarfs cool through several processes, including the emission of weakly interacting particles ...
A simple cooling model of white dwarf stars is re-analyzed in Palatini $f(R)$ gravity. Modified grav...
We report on the spectroscopic confirmation of 68 new bright ($G=13.5-17.2$ mag) and blue (pre-)whit...
Dark matter can be part of a dark sector with non-minimal couplings to the Standard Model. Compared ...
White dwarfs (WDs) are the final evolutionary product of the vast majority of stars in the Universe....
We show that rotating white dwarfs admixed with dark matter have interesting properties that may be ...
This thesis is about deriving a few equations of state for white dwarfs below the regime of neutron...
In many models of dark matter (DM), several production mechanisms contribute to its final abundance,...
We investigate electromagnetic and gravitational radiation generated during a process of the tidal s...
Hot new early dark energy describes a supercooled, first-order phase transition that takes place at ...