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Main Authors: Perriyil, S. M., Sadangaya, S. S., de Castro, C. G. Giménez, Simões, P. J. A.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.19836
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author Perriyil, S. M.
Sadangaya, S. S.
de Castro, C. G. Giménez
Simões, P. J. A.
author_facet Perriyil, S. M.
Sadangaya, S. S.
de Castro, C. G. Giménez
Simões, P. J. A.
contents We investigate how the magnetic loop length of solar flares relates to the timing between their thermal and nonthermal emission signatures. Our study analyzes a sample of 96 C-, M-, and X-class flares observed between 2013 and 2015 with soft X-rays, hard X-rays, and extreme UV. For each event, we determine the time delay Δt between the hard X-ray and soft X-ray peak, and estimate the flare loop length L from UV footpoints assuming a semicircular geometry. In every case, longer flare loops are consistently associated with larger timing delays. Across the full sample, we find a strong correlation, R = 0.88 between L and Δt. We also quantify how closely each flare follows the Neupert effect using a coefficient RN, defined as the Pearson correlation between the time derivative of the soft X-ray flux and the hard X-ray light curve. Applying correlation thresholds of RN > 0.5 and RN > 0.8 yields subsets of 87 and 46 events, respectively. In both cases, the linear relationship between loop length and peak delay remains clearly expressed. For the RN > 0.5 subset, the correlation is R = 0.87, while the more selective subset with RN > 0.8 displays an even stronger correlation of R = 0.91. These results show that the overall trend persists across increasingly stringent correlation thresholds. The results provide direct observational confirmation that magnetic loop geometry plays a key role in governing the temporal evolution of energy transport in solar flares.
format Preprint
id arxiv_https___arxiv_org_abs_2602_19836
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Observational Evidence Linking Loop Length and Thermal-Nonthermal Peak Timing in Solar Flares
Perriyil, S. M.
Sadangaya, S. S.
de Castro, C. G. Giménez
Simões, P. J. A.
Solar and Stellar Astrophysics
We investigate how the magnetic loop length of solar flares relates to the timing between their thermal and nonthermal emission signatures. Our study analyzes a sample of 96 C-, M-, and X-class flares observed between 2013 and 2015 with soft X-rays, hard X-rays, and extreme UV. For each event, we determine the time delay Δt between the hard X-ray and soft X-ray peak, and estimate the flare loop length L from UV footpoints assuming a semicircular geometry. In every case, longer flare loops are consistently associated with larger timing delays. Across the full sample, we find a strong correlation, R = 0.88 between L and Δt. We also quantify how closely each flare follows the Neupert effect using a coefficient RN, defined as the Pearson correlation between the time derivative of the soft X-ray flux and the hard X-ray light curve. Applying correlation thresholds of RN > 0.5 and RN > 0.8 yields subsets of 87 and 46 events, respectively. In both cases, the linear relationship between loop length and peak delay remains clearly expressed. For the RN > 0.5 subset, the correlation is R = 0.87, while the more selective subset with RN > 0.8 displays an even stronger correlation of R = 0.91. These results show that the overall trend persists across increasingly stringent correlation thresholds. The results provide direct observational confirmation that magnetic loop geometry plays a key role in governing the temporal evolution of energy transport in solar flares.
title Observational Evidence Linking Loop Length and Thermal-Nonthermal Peak Timing in Solar Flares
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2602.19836