Automated workflow for accurate scattering function calculation of light water using quantum corrections

Abstract

Accurate calculation of the neutron scattering function for light water from theoretical model is often limited due to the challenges associated with the incoherent and inelastic correction of hydrogen. Traditional correction methods rely on empirical formulas, which lack generality and accuracy. Although quantum correction methods for light water have been studied for a while, they have not yet been translated into practical, openly available tools for calculating the scattering function $S (Q, ω)$ . In this paper, we present an open-source computational tool that provides a stable numerical implementation of the Gaussian approximation-assisted quantum correction (GAAQC) framework for light water. The tool applies quantum corrections to classical neutron scattering data derived from molecular dynamics (MD) simulations. It takes two inputs-both obtainable from standard MD trajectories: (a) the vibrational density of states (VDOS) and (b) the classical scattering function $S_{cl} (Q, ω)$ -and outputs the quantum-corrected scattering function $S (Q, ω)$ . Our implementation overcomes the instabilities that previously limited the GAAQC method, enabling reliable calculation over a wide dynamic range of momentum and energy transfer.

Keywords

neutron scattering numerical calculation light water quantum correction

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References

Glauber

. Time-dependent displacement correlations and inelastic scattering by crystals. Phys Rev 1955; 98: 1692–1698.

Lavelle

Liu

Stone

. Toward a new polyethylene scattering law determined using inelastic neutron scattering. Nucl Instrum Methods Phys Res A 2013; 711: 166–179.

Cai

Klinkby

. Neutron total cross section calculation within the framework of quasi-harmonic approximation. New J Phys 2017; 19: 103027.

Cai

Kittelmann

. Ncrystal: a library for thermal neutron transport. Comput Phys Commun 2020; 246: 106851.

Edura

Morishima

. Cold and thermal neutron scattering in liquid water: cross-section model and dynamics of water molecules. Nucl Instrum Methods Phys Res A 2004; 534: 531–543.

Viñales

Dawidowski

Márquez Damián

. Neutron total cross-section model for liquids and its application to light water. Ann Nucl Energy 2011; 38: 1687–1692.

Qvist

Schober

Halle

. Structural dynamics of supercooled water from quasielastic neutron scattering and molecular simulations. J Chem Phys 2011; 134: 144508.

Van Hove

. Correlations in space and time and born approximation scattering in systems of interacting particles. Phys Rev 1954; 95: 249–262.

Soper

. Inelasticity corrections for time-of-flight and fixed wavelength neutron diffraction experiments. Mol Phys 2009; 107: 1667–1684.

10.

Rahman

Stillinger

. Molecular dynamics study of liquid water. J Chem Phys 1971; 55: 3336–3359.

11.

Martí

Padro

Guàrdia

. Molecular dynamics simulation of liquid water along the coexistence curve: hydrogen bonds and vibrational spectra. J Chem Phys 1996; 105: 639–649.

12.

González

Abascal

JLF

. A flexible model for water based on TIP4P/2005. J Chem Phys 2011; 135: 224516.

13.

Abe

Tsuboi

Tasaki

. Evaluation of the neutron scattering cross-section for light water by molecular dynamics. Nucl Instrum Methods Phys Res A 2014; 735: 568–573.

14.

Noguere

Scotta

, et al. Temperature-dependent dynamic structure factors for liquid water inferred from inelastic neutron scattering measurements. J Chem Phys 2021; 155: 024502.

15.

Márquez Damián

Granada

Malaspina

. CAB models for water: a new evaluation of the thermal neutron scattering laws for light and heavy water in ENDF-6 format. Ann Nucl Energy 2014; 65: 280–289.

16.

Schofield

. Space-time correlation function formalism for slow neutron scattering. Phys Rev Lett 1960; 4: 239–240.

17.

Egelstaff

. Neutron scattering studies of liquid diffusion. Adv Phys 1962; 11: 203–232.

18.

Sears

. Neutron scattering in almost-classical liquids. Phys Rev A 1985; 31: 2525–2533.

19.

Abe

Tasaki

. Molecular dynamics analysis of incoherent neutron scattering from light water via the van hove space–time self-correlation function with a new quantum correction. Ann Nucl Energy 2015; 83: 302–308.

20.

Márquez Damián

Granada

Cantargi

, et al. Generation of thermal scattering libraries for liquids beyond the Gaussian approximation using molecular dynamics and NJOY/LEAPR. Ann Nucl Energy 2016; 92: 107–112.

21.

Rahman

Singwi

Sjölander

. Theory of slow neutron scattering by liquids. I. Phys Rev 1962; 126: 986–996.

22.

Thompson

Aktulga

Berger

, et al. LAMMPS—a flexible simulation tool for particle-based materials modeling at the atomic, meso, and continuum scales. Comput Phys Commun 2022; 271: 108171.

23.

Fosdick

. A special case of the Filon quadrature formula. Math Comput 1968; 22: 77–81.

24.

Cai

. Convolutional discrete fourier transform method for calculating thermal neutron cross section in liquids. J Comput Phys 2022; 466: 111382.

25.

Soper

. The radial distribution functions of water and ice from 220 to 673 K and at pressures up to 400 MPa. Chem Phys 2000; 258: 121–137.

26.

Singwi

Sjölander

. Diffusive motions in water and cold neutron scattering. Phys Rev 1960; 119: 863–871.

27.

Esch

Yeater

Moore

, et al. The temperature dependence of neutron inelastic scattering from water. Nucl Sci Eng 1971; 46: 223–235.