Energy-differential measurement of the $^{\mathrm{nat}}$C(n,p) and $^{\mathrm{nat}}$C(n,d) reactions at the n_TOF facility at CERN

P. \v{Z}ugec; N. Colonna; D. Rochman; M. Barbagallo; J. Andrzejewski; J. Perkowski; A. Ventura; D. Bosnar; A. Gawlik-Ramiega; M. Sabat\'e-Gilarte; M. Bacak; F. Mingrone; E. Chiaveri; O. Aberle; V. Alcayne; S. Amaducci; L. Audouin; V. Babiano-Suarez; S. Bennett; E. Berthoumieux; J. Billowes; A. Brown; M. Busso; M. Caama\~no; L. Caballero-Ontanaya; F. Calvi\~no; M. Calviani; D. Cano-Ott; A. Casanovas; F. Cerutti; G. Cort\'es; M. A. Cort\'es-Giraldo; L. Cosentino; S. Cristallo; L. A. Damone; P. J. Davies; M. Diakaki; M. Dietz; C. Domingo-Pardo; R. Dressler; Q. Ducasse; E. Dupont; I. Dur\'an; Z. Eleme; B. Fern\'andez-Dom\'inguez; A. Ferrari; P. Finocchiaro; V. Furman; K. G\"obel; R. Garg; S. Gilardoni; I. F. Gon\c{c}alves; E. Gonz\'alez-Romero; C. Guerrero; F. Gunsing; H. Harada; S. Heinitz; J. Heyse; D. G. Jenkins; A. Junghans; F. K\"appeler; Y. Kadi; A. Kimura; I. Knapov\'a; M. Kokkoris; Y. Kopatch; M. Krti\v{c}ka; D. Kurtulgil; I. Ladarescu; C. Lederer-Woods; H. Leeb; J. Lerendegui-Marco; S. J. Lonsdale; D. Macina; A. Manna; T. Mart\'inez; M. Mart\'inez-Ca\~nada; A. Masi; C. Massimi; P. Mastinu; M. Mastromarco; E. A. Maugeri; A. Mazzone; E. Mendoza; A. Mengoni; V. Michalopoulou; P. M. Milazzo; J. Moreno-Soto; A. Musumarra; A. Negret; R. Nolte; F. Og\'allar; A. Oprea; N. Patronis; A. Pavlik; C. Petrone; L. Piersanti; E. Pirovano; I. Porras; J. Praena; J. M. Quesada; D. Ramos; T. Rauscher; R. Reifarth; C. Rubbia; A. Saxena; P. Schillebeeckx; D. Schumann; A. Sekhar; A. G. Smith; N. V. Sosnin; P. Sprung; A. Stamatopoulos; G. Tagliente; J. L. Tain; A. Tarife\~no-Saldivia; L. Tassan-Got; Th. Thomas; P. Torres-S\'anchez; A. Tsinganis; J. Ulrich; S. Urlass; S. Valenta; G. Vannini; V. Variale; P. Vaz; D. Vescovi; V. Vlachoudis; R. Vlastou; A. Wallner; P. J. Woods; T. Wright

arXiv:2604.25437·nucl-ex·April 29, 2026

Energy-differential measurement of the $^{\mathrm{nat}}$C(n,p) and $^{\mathrm{nat}}$C(n,d) reactions at the n_TOF facility at CERN

P. \v{Z}ugec, N. Colonna, D. Rochman, M. Barbagallo, J. Andrzejewski, J. Perkowski, A. Ventura, D. Bosnar, A. Gawlik-Ramiega, M. Sabat\'e-Gilarte, M. Bacak, F. Mingrone, E. Chiaveri, O. Aberle, V. Alcayne, S. Amaducci, L. Audouin, V. Babiano-Suarez, S. Bennett, E. Berthoumieux

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TL;DR

This study measured the energy-differential cross sections of $^{ ext{nat}}$C(n,p) and (n,d) reactions at CERN's n_TOF facility, revealing discrepancies with existing evaluation libraries and aligning with TALYS-2.0 predictions.

Contribution

It provides new experimental cross section data for carbon reactions up to 25 MeV, highlighting inconsistencies with major libraries and supporting TALYS-2.0 calculations.

Findings

01

Cross sections are higher than existing evaluations.

02

Results agree with TALYS-2.0 calculations.

03

Supports earlier integral measurement findings.

Abstract

Energy-differential cross section of the $^{nat}$ C(n,p) and $^{nat}$ C(n,d) reactions was measured at the neutron time of flight facility n_TOF at CERN. The measurement was performed in the first experimental area (EAR1; flight path of 182.5 m). Two position-sensitive $Δ E$ - $E$ silicon telescopes were used. Two naturally occurring carbon isotopes, $^{12}$ C and $^{13}$ C, contribute to the reactions on natural carbon, with the (n,p) reaction threshold at 13.7 MeV and the (n,d) threshold at 14.9 MeV (determined by the $^{12}$ C isotope for both reactions). This paper provides the details of the analysis leading to the final results published previously as a Letter. The cross section results are reported up to 25 MeV. During the data analysis the population of the excited states in the daughter nuclei $^{11}$ B, $^{12}$ B, $^{13}$ B had to be considered, requiring the…

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