Pulsar Timing Residuals and Angular Correlations from Ultralight Scalar Dark Matter and Non-Adiabatic Perfect Fluid Dark Matter

Beyond ultralight scalar dark matter and non-adiabatic perfect fluid dark matter, several other dark matter models could leave distinctive signatures in pulsar timing array (PTA) observations. These include: Ultralight Vector Dark Matter: Similar to scalar dark matter, ultralight vector dark matter can produce oscillatory signals in pulsar timing due to its coherent oscillations. The vector nature may lead to different angular correlations and timing residuals compared to scalar models, potentially allowing for differentiation based on the observed patterns. Fuzzy Dark Matter: This model posits that dark matter consists of ultralight bosons with a mass on the order of (10^{-22}) eV. The wave-like nature of fuzzy dark matter could create interference patterns in pulsar timing, leading to unique signatures that differ from those of scalar or perfect fluid dark matter. Self-Interacting Dark Matter (SIDM): Models that incorporate self-interaction among dark matter particles could lead to different density profiles and clustering effects. These interactions might produce additional gravitational wave signals or perturbations that could be detected through PTA observations. Modified Gravity Theories: Models that modify general relativity, such as those incorporating extra dimensions or alternative gravity theories, could also affect the propagation of signals from pulsars. The resulting metric perturbations could yield distinctive timing residuals that differ from those predicted by standard dark matter models. Primordial Black Holes: If a significant fraction of dark matter consists of primordial black holes, their gravitational effects could lead to unique signatures in pulsar timing, particularly if they cluster in specific regions of the galaxy. Each of these models presents unique characteristics that could be identified through careful analysis of pulsar timing data, potentially enhancing our understanding of dark matter's nature and distribution.

Observational data from current and future pulsar timing array (PTA) experiments can be utilized to constrain or differentiate between various dark matter models through several key methodologies: Timing Residual Analysis: By measuring the timing residuals of pulsars with high precision, researchers can identify patterns that correspond to specific dark matter models. For instance, the directional dependence of timing residuals from scalar dark matter, as discussed in the paper, can be compared against predictions from other models, such as vector or fuzzy dark matter. Angular Correlation Studies: PTA observations can be used to analyze angular correlations between pulsars, which can reveal the underlying structure of dark matter. Different dark matter models may produce distinct angular correlation functions, such as the Hellings-Downs curve, allowing for model differentiation based on the observed correlations. Frequency Domain Analysis: The frequency characteristics of pulsar timing signals can be examined to identify oscillatory features associated with specific dark matter models. For example, the frequency of oscillations in scalar dark matter is related to its mass, providing a direct link between observed frequencies and dark matter properties. Statistical Methods: By employing statistical techniques to analyze the distribution of timing residuals and correlations, researchers can quantify the likelihood of various dark matter models. Bayesian inference and likelihood analysis can help constrain model parameters based on the fit to observed data. Long-Term Monitoring: Future PTA experiments, such as the Square Kilometre Array (SKA), will provide more extensive and precise data over longer time periods. This will enhance the ability to detect subtle signatures of dark matter and improve the statistical significance of the results, allowing for more robust comparisons between models. Through these methods, PTA observations can serve as a powerful tool for testing dark matter theories, potentially leading to significant advancements in our understanding of the universe's composition.

The conclusions drawn in this paper are heavily dependent on several key assumptions regarding the properties and distribution of dark matter within our galaxy: Homogeneity and Isotropy: The analysis assumes that dark matter is distributed homogeneously and isotropically within the galactic halo. Deviations from this assumption, such as clumping or anisotropic distributions, could alter the predicted timing residuals and angular correlations, potentially leading to different observational signatures. Nature of Dark Matter: The paper focuses on specific models of dark matter, namely ultralight scalar and non-adiabatic perfect fluid dark matter. The conclusions regarding timing residuals and angular correlations are contingent upon the validity of these models. If dark matter behaves differently than assumed (e.g., if it has significant self-interactions or is composed of different particle types), the results may not hold. Velocity Distribution: The analysis relies on the assumption of a specific velocity distribution for dark matter particles, which influences the de Broglie wavelength and the resulting oscillatory behavior. Variations in the velocity distribution could lead to different timing signatures, affecting the conclusions drawn about the nature of dark matter. Effective Sound Speed: For perfect fluid dark matter, the effective sound speed is assumed to be a constant value. If the sound speed varies significantly due to local conditions or interactions, this could impact the acoustic oscillations and the resulting metric perturbations, leading to different predictions for pulsar timing. Cosmological Parameters: The conclusions are also influenced by the underlying cosmological parameters, such as the density of dark matter and its equation of state. Changes in these parameters could affect the evolution of metric perturbations and the resulting timing signals. Overall, the robustness of the conclusions is tied to the accuracy of these assumptions. Future observations and theoretical developments may refine our understanding of dark matter, potentially leading to revisions of the predictions made in this paper.