Model-independent calibration of Gamma-Ray Bursts with neural networks

TL;DR

This paper presents a neural network-based, model-independent calibration method for gamma-ray bursts, enhancing their reliability as high-redshift cosmological distance indicators.

Contribution

It introduces an ANN-driven calibration of GRB luminosity relations that reduces scatter and systematic uncertainties, improving high-redshift cosmological measurements.

Findings

ANN calibration minimizes scatter in GRB luminosity relations

Method avoids kernel dependence and overfitting issues of Gaussian processes

Results support GRBs as reliable high-redshift distance indicators

Abstract

The $\Lambda$ Cold Dark Matter ($\Lambda$CDM) cosmological model has been highly successful in predicting cosmic structure and evolution, yet recent precision measurements have highlighted discrepancies, especially in the Hubble constant inferred from local and early-Universe data. Gamma-ray bursts (GRBs) present a promising alternative for cosmological measurements, capable of reaching higher redshifts than traditional distance indicators. This work leverages GRBs to refine cosmological parameters independently of the $\Lambda$CDM framework. Using the Platinum compilation of long GRBs, we calibrate the Dainotti relations-empirical correlations among GRB luminosity properties-as standard candles through artificial neural networks (ANNs). We analyze both the 2D and 3D Dainotti calibration relations, leveraging an ANN-driven Markov Chain Monte Carlo approach to minimize scatter in the calibration parameters, thereby achieving a stable Hubble diagram. This ANN-based calibration approach offers advantages over Gaussian processes, avoiding issues such as kernel function dependence and overfitting. Our results emphasize the need for model-independent calibration approaches to address systematic challenges in GRB luminosity variability, ultimately extending the cosmic distance ladder in a robust way. By addressing redshift evolution and reducing systematic uncertainties, GRBs can serve as reliable high-redshift distance indicators, offering critical insights into current cosmological tensions.