Measuring energy production in the Universe over all wavelengths and all time

TL;DR

This paper discusses recent advances in measuring the extragalactic background light across all wavelengths and cosmic time, aiming to understand the Universe's energy production history with high precision.

Contribution

It highlights progress in modeling and measuring the EBL, including redshift subdivision and improved dust and AGN models, paving the way for near 1% accuracy in future observations.

Findings

Breakthroughs in optical and IR measurements resolve previous discrepancies.

Enhanced models now incorporate detailed dust and AGN contributions.

Future facilities will enable near-perfect EBL measurement accuracy.

Abstract

The study of the extragalactic background light (EBL) is undergoing a renaissance. New results from very high energy experiments and deep space missions have broken the deadlock between the contradictory measurements in the optical and near-IR arising from direct versus discrete source estimates. We are also seeing advances in our ability to model the EBL from gamma-ray to radio wavelengths with improved dust models and AGN handling. With the advent of deep and wide spectroscopic and photometric redshift surveys, we can now subdivide the EBL into redshift intervals. This allows for the recovery of the Cosmic Spectral Energy Distribution (CSED), or emissivity of a representative portion of the Universe, at any time. With new facilities coming online, and more unified studies underway from gamma-ray to radio wavelengths, it will soon be possible to measure the EBL to within 1 per cent accuracy. At this level correct modelling of reionisation, awareness of missing populations or light, radiation from the intra-cluster and halo gas, and any signal from decaying dark-matter all become important. In due course, the goal is to measure and explain the origin of all photons incident on the Earth's surface from the extragalactic domain, and within which is encoded the entire history of energy production in our Universe.