Gamma-Ray Bursts Calibrated by Using Artificial Neural Networks from the Pantheon+ Sample

Abstract

In this paper, we calibrate the luminosity relation of gamma-ray bursts (GRBs) by Artificial Neural Networks (ANN) which is employed to analyze the Pantheon+ sample of type Ia supernovae (SNe Ia) in a manner independent of cosmological assumptions. The A219 GRB dataset are used to calibrate the Amati relation (\(E p\)-\(E iso\)) at low redshift with the ANN framework, facilitating the construction of the Hubble diagram at higher redshifts. Cosmological models are constrained with GRBs at high-redshift and the latest observational Hubble data (OHD) via a Markov Chain Monte Carlo numerical approach. For the Chevallier-Polarski-Linder (CPL) model within a flat universe, we obtain \( m = 0.321+0.078-0.069\), \(h = 0.654+0.053-0.071\), \(w0 = -1.02+0.67-0.50\), and \(wa = -0.98+0.58-0.58\) at the 1-\(σ\) confidence level, which indicating a preference for dark energy with potential redshift evolution (\(wa ≠ 0\)). These findings by using ANN align closely with those derived from GRBs calibrated by using Gaussian Processes.