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Auteurs principaux: Rasco, B. C., Gray, T., Ruland, T.
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2505.11510
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author Rasco, B. C.
Gray, T.
Ruland, T.
author_facet Rasco, B. C.
Gray, T.
Ruland, T.
contents Experimental extraction of $β$-shape functions, C(W), is challenging. Comparing different experimental $β$-shapes to each other and to those predicted by theory in a consistent manner is difficult. This difficulty is compounded when different parameterizations of the $β$-shape function are used. Usually some form of a power polynomial of the total electron energy is chosen for this parametrization. This choice results in extracted coefficients that are highly correlated, with their physical meaning and numerical value dependent on the order of polynomial chosen. This is true for both theoretical and experimental coefficients, and leads to challenges when comparing coefficients from polynomials of different orders. Accurately representing the highly correlated uncertainties is difficult and subtle. These issues impact the underlying physical interpretation of shape function parameters. We suggest an alternative approach based on orthogonal polynomials. Orthogonal polynomials offer more stable coefficient extraction which is less dependent on the order of the polynomial, allow for easier comparison between theory and experimental coefficients from polynomials of different orders, and offer some observations on simple physical meaning and on the statistical limits of the extracted coefficients.
format Preprint
id arxiv_https___arxiv_org_abs_2505_11510
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle On Robust $β$-Spectra Shape Parameter Extraction
Rasco, B. C.
Gray, T.
Ruland, T.
Computational Physics
Nuclear Experiment
Nuclear Theory
Chemical Physics
Experimental extraction of $β$-shape functions, C(W), is challenging. Comparing different experimental $β$-shapes to each other and to those predicted by theory in a consistent manner is difficult. This difficulty is compounded when different parameterizations of the $β$-shape function are used. Usually some form of a power polynomial of the total electron energy is chosen for this parametrization. This choice results in extracted coefficients that are highly correlated, with their physical meaning and numerical value dependent on the order of polynomial chosen. This is true for both theoretical and experimental coefficients, and leads to challenges when comparing coefficients from polynomials of different orders. Accurately representing the highly correlated uncertainties is difficult and subtle. These issues impact the underlying physical interpretation of shape function parameters. We suggest an alternative approach based on orthogonal polynomials. Orthogonal polynomials offer more stable coefficient extraction which is less dependent on the order of the polynomial, allow for easier comparison between theory and experimental coefficients from polynomials of different orders, and offer some observations on simple physical meaning and on the statistical limits of the extracted coefficients.
title On Robust $β$-Spectra Shape Parameter Extraction
topic Computational Physics
Nuclear Experiment
Nuclear Theory
Chemical Physics
url https://arxiv.org/abs/2505.11510