X-Ray Clues to Cosmic Rays: The Discovery of a Galactic PeVatron Candidate

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Multi-messenger astrophysics

Astro-COLIBRI

63 episodes

2 days ago

Discussions around tools and discoveries in the novel domain of multi-messenger and time domain astrophysics. We'll highlight recent publications, discuss tools to faciliate observations and generally talk about the cool science behind the most violent explosions in the universe.

Astronomy

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Astronomy

Science

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X-Ray Clues to Cosmic Rays: The Discovery of a Galactic PeVatron Candidate

Multi-messenger astrophysics

23 minutes 46 seconds

4 months ago

X-Ray Clues to Cosmic Rays: The Discovery of a Galactic PeVatron Candidate

Join us as we dive into the latest astronomical discovery! Scientists have identified a **new candidate pulsar wind nebula (PWN)**, named XMMU 034124.2+525720, which may be directly linked to **1LHAASO J0343+5254u**, a powerful "PeVatron" in our galaxy.

**What are PeVatrons?** They are the most energetic astrophysical objects in our galaxy, producing cosmic rays (CRs) with energies exceeding 1 PeV (10^15 eV), far surpassing what terrestrial accelerators can achieve. Understanding them is key to solving the mystery of the most energetic galactic cosmic rays and gamma rays.

This potential PWN, discovered through extensive **XMM-Newton observations**, exhibits key characteristics typical of other very high-energy PWNs like the "Eel" and "Boomerang" nebulae. Its X-ray emission shows an **extended, asymmetric morphology** and a **power-law spectrum (ΓX = 1.9)** that becomes notably softer farther from its center.

Using **multiwavelength modeling**, researchers demonstrated that a **fully leptonic model**—involving electron synchrotron radiation and inverse-Compton (IC) scattering of ambient photons—can explain the observed X-ray and gamma-ray emission, especially if there are **elevated infrared (IR) photon fields** in the region. While this model largely accounts for the LHAASO gamma-ray flux, future observations will help explore if hadronic processes in nearby molecular clouds also contribute to the gamma-ray emission and potential neutrino flux.

Though XMM-Newton observations didn't definitively resolve a central pulsar or detect X-ray pulsations, this discovery marks a crucial step in understanding galactic PeVatrons. Future, higher-resolution X-ray observations with missions like Chandra and NuSTAR, along with dedicated radio searches for a pulsar, are planned to solidify this PWN classification and provide deeper insights into these extreme cosmic accelerators.

**Article Reference:**

DiKerby, S., Zhang, S., Ergin, T., et al. 2025, *Discovery of a Pulsar Wind Nebula Candidate Associated with the Galactic PeVatron 1LHAASOJ0343+5254u*, The Astrophysical Journal, 983:21.

Acknowledements: Podcast prepared with Google/NotebookLM. Illustration credits: Stephen DiKerby et al., 2025 ApJ 983 21