Assessing uncertainties in parton showers at double logarithmic accuracy for jet quenching studies

Author(s)

Andres, Carlota; Apolinário, Liliana; Armesto, Néstor; Cordeiro, André; Dominguez, Fabio; Milhano, José G.; ... Show more Show less

Abstract

We present a systematic study of how different choices of ordering and phase-space constraints in parton showers affect the space-time structure of vacuum parton cascades and their interface with jet quenching models. Using a simplified Monte Carlo shower implemented at double logarithmic accuracy, we analyse variations in emission patterns and resulting phase-space arising from three ordering variables: inverse formation time, invariant mass, and opening angle. These are coupled with two kinematic reconstruction schemes defined by different phase-space constraints. We show that, while global features are relatively stable, differences emerge in the temporal evolution of the cascade. To probe the impact of these differences, we introduce a simplified model for in-medium energy loss based on formation time and colour decoherence, enabling us to evaluate the sensitivity of quenching observables to the underlying space-time structure of the vacuum shower. We further quantify the role of time-ordering violations and propose strategies to preserve a consistent space-time interpretation. Lastly, we explore a range of alternative quenching models confirming the robustness of our conclusions. Our findings highlight the importance of maintaining a coherent space-time structure in parton shower algorithms when modelling jet propagation in an extended QCD medium, as this structure becomes a physically meaningful and testable component of the jet itself.

Date issued

2025-08-20

URI

https://hdl.handle.net/1721.1/163375

Department

Massachusetts Institute of Technology. Center for Theoretical Physics

Journal

Journal of High Energy Physics

Publisher

Springer Berlin Heidelberg

Citation

Andres, C., Apolinário, L., Armesto, N. et al. Assessing uncertainties in parton showers at double logarithmic accuracy for jet quenching studies. J. High Energ. Phys. 2025, 160 (2025).

Version: Final published version