| 26 Mar 2026
CoRSEER: The Calculator of Rock Surface Exposure Age and Erosion Rates for Rock Surface Luminescence dating
Abstract. Rock-surface luminescence dating estimates the duration of rock surface exposure and the rate of erosion by analysing changes in luminescence with depth below the surface. The wider use of this method has been slowed by three practical issues: the subjective selection of the deep plateau for profile normalisation, inconsistent modelling choices across studies, and the lack of a unified inverse-modelling workflow that delivers both parameter estimates and uncertainty bounds. We introduce CoRSEER, an open-source MATLAB application that standardises the full workflow from luminescence depth profiles to exposure and erosion history. CoRSEER first normalises profiles objectively using weighted three-parameter logistic sigmoidal fitting to identify the saturation level and profile shape. It then simulates profile evolution with a finite-difference forward model that includes ambient radiation induced signal growth, depth-dependent bleaching described by a surface bleaching rate, attenuation coefficient, and advection caused by erosion. Finally, CoRSEER performs Monte Carlo inversion to estimate calibration parameters from known-age calibration samples, apparent exposure ages for unknown samples, and steady or stepwise erosion histories while reporting the best-fit and uncertainty ranges from likelihood-based filtering. We tested all three modules by reanalysing published datasets from multiple regions, including 23 calibration samples from the original dataset. For a representative calibration profile, CoRSEER improved the fit (coefficient of determination of 0.928 compared with 0.868 for the literature dataset) and substantially tightened the uncertainty bounds after objective re-normalisation. Across the compiled studies, the CoRSEER-derived apparent ages cluster close to the one-to-one line relative to the published values and span approximately 1–8.5 thousand years, while erosion estimates for a benchmark case remain comparable to the literature results (0.1 mm/a versus 0.066 mm/a). These results show that objective normalisation plus a transparent, standardised inversion framework can materially improve the reproducibility of rock surface luminescence dating and support consistent inter-study comparisons of exposure and erosion history.
Title: CoRSEER: The Calculator of Rock Surface Exposure Age and Erosion Rates for Rock Surface Luminescence dating
Author(s): Arbaz N. Pathan et al.
MS No.: egusphere-2026-1303
General comments
CoRSEER is exactly what the luminescence community needs right now. It provides much-needed standardisation of the method, but also increases the accessibility of this technique. This is a major step-forward in the technique. The CoRSEER calculator is accompanied by this well explained paper, which shows how much testing has gone into it, which gives confidence to the user. It also acts as somewhat of a reference ‘manual’ for those less expert in the technique, which is a very useful addition to the literature. With this in mind, I have a few comments below where this paper could provide a little more instruction/guidance on the technique more generally (beyond just CoRSEER) given that it will be such a key reference paper for the technique. The paper identifies and tackles the issues with defining the saturated plateau at depth, providing a solution shown to reduce uncertainties quite dramatically, and presumably improve the accuracy – an important advancement as anyone who has tried to model luminescence depth profiles will know. This is an excellent addition to the literature and luminescence toolkit, and the authors should be commended for all their hard work on developing it. I include a few very minor comments below for the authors to consider.
Specific comments
Technical corrections