Electron-volt neutron spectroscopy: beyond fundamental systems

Andreani, C.; Krzystyniak, M.; Romanelli, Giovanni; Senesi, R.; Fernandez-Alonso, Félix

doi:10.1080/00018732.2017.1317963

Cited by 85 publications

(154 citation statements)

References 217 publications

(301 reference statements)

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“…where σ 2 is the second moment of the NMD and y is the so-called West-scaling variable, defined as the projection of an associated radial nuclear momentum p onto the direction of the momentum transferQ [69]. For a given nucleus, σ 2 can be, within the harmonic approximation, further associated with the atom-projected density of vibrational states (AVDOS), g(ω), according to the following relation:…”

Section: Neutron Compton Scatteringmentioning

confidence: 99%

Section: Neutron Compton Scatteringmentioning

confidence: 99%

“…In brief, NCS operates within the limits of the so-called impulse approximation (IA) [69], with hundreds of electronVolt energy transferhω from incident neutrons and up to tens ofÅ −1 of momentum transfer, Q. The consequence of the IA is that a time-of-flight (TOF) spectrum measured on VESUVIO consists of separate recoil peaks, each stemming from the longitudinal nuclear momentum distribution (NMD) of each respective nucleus present in the target system, J IA y,Q [69]. Moreover, the intensity of each NCS recoil peak is proportional to the product of the total bound scattering cross-section and the number of atoms under the beam, thus rendering NCS, unlike INS, completely free from the neutron weighting problem, which greatly facilitates the theoretical interpretation of the spectra.…”

Section: Neutron Compton Scatteringmentioning

confidence: 99%

See 2 more Smart Citations

Hydrogen dynamics in solid formic acid: insights from simulations with quantum colored-noise thermostats

Drużbicki

Krzystyniak

Hollas

et al. 2018

J. Phys.: Conf. Ser.

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Abstract. With an increase of computational capabilities, ab initio molecular dynamics becomes the natural choice for exploring the nuclear dynamics of solids. As based on classical mechanics, the validity of this approach is, in-principle, limited to the high-T regime, whilst low-temperature simulations require inclusion of quantum effects. The methods commonly used to account for nuclear quantum effects are based on the path-integral formalism, which become, however, particularly time consuming when high accuracy methods are used for calculating forces. Recently, new efficient alternative approaches to account for quantum nature of nuclei have been proposed, using so-called quantum thermostats. In this work, we examine the simulations performed with the quantum colored-noise thermostat introduced by Ceriotti [Phys. Rev. Lett., 103:030603, 2009]. We present the tests of portable implementation of the quantum thermostat in the ABIN program, which has been extended to periodic systems through the interface to CASTEP, a leading spectroscopy-oriented plane-wave density functional theory code. The range of applicability of quantum-thermostatted molecular dynamics simulations for the interpretation of neutron scattering data was examined and compared to classical molecular dynamics and lattice-dynamics simulations, using solid formic acid case as a test bed. We find that the approach is particularly useful for the modeling of low-temperature inelastic neutron scattering spectra as well as provides some theoretical estimate for the low-limit of the mean kinetic energy. While finding the quantum-thermostat to seriously affect the dynamic properties of the title system, we illustrate to which extent the unperturbed response can be successfully recovered. IntroductionMolecular dynamics (MD) has evolved into a powerful numerical method to investigate structural and dynamical properties of condensed matter [1]. For an atom, these calculations are, however, only valid in the classical limit, i.e. for temperatures safely above the Debye temperature that signals the onset of quantum effects. The Debye temperature is often of the order of few hundred Kelvins and nuclear quantum effects (NQEs) are thus indeed important over a wide range of temperatures [2,3].Quantum fluctuations stemming from the Heisenberg uncertainty principle make the energy of a particle at 0 K higher than a the potential energy minimum, leading to a concept of zero point energy (ZPE) (see Fig. 1). While ZPE reflects the quantum nature of atomic motion, it can be approximately accounted for by lattice-dynamics calculations, which, by definition, are based on the quantum harmonic oscillator model.

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Section: Neutron Compton Scatteringmentioning

confidence: 99%

Section: Neutron Compton Scatteringmentioning

confidence: 99%

Section: Neutron Compton Scatteringmentioning

confidence: 99%

See 1 more Smart Citation

Hydrogen dynamics in solid formic acid: insights from simulations with quantum colored-noise thermostats

Drużbicki

Krzystyniak

Hollas

et al. 2018

J. Phys.: Conf. Ser.

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“…Looking at these proceedings and at a recent review [4], the scientific community using eV neutron spectroscopy on the VESUVIO spectrometer has broadened the area of investigated subjects towards, for example, energy materials [35] and real-life systems [36]. Such an evolution in the scientific programme has been catalysed, amongst other reasons, by an increased attention to the several techniques simultaneously available during a DINS experiment.…”

Section: Outlook and Ways Forwardmentioning

confidence: 99%

“…Looking at the proceedings of the VI (2014) [1] and VII (2017) international workshops on eV neutron spectroscopy [2], one can notice how the use of Deep Inelastic Neutron Scattering (DINS) to characterise Nuclear Quantum Effects (NQEs) mostly on hydrogen dynamics [3] has lead to MAss-selective Neutron SpEctroscopy (MANSE), whereby the Nuclear Momentum Distributions (NMDs) of several elements in a given sample are accessed at the same time [4,5,6]. Furthermore, a number of recent investigations carried out on the VESUVIO spectrometer [7], the flagship instrument for eV neutron spectroscopy at the ISIS Facility [8], successfully combined DINS with concurrent Neutron Diffraction (ND) measurements [9,10], or employed broad-range Neutron Transmission (NT) [11,12].…”

Section: Introductionmentioning

confidence: 99%

The road to a station for epithermal and thermal neutron analysis

Romanelli

Krzystyniak

Festa

et al. 2018

J. Phys.: Conf. Ser.

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Abstract.Despite the large variety of research interests and themes motivating the current neutron research included in this collection, we have found common denominators characterising the manner in which the chosen research methodology tries to tackle the envisaged scientific questions. This article attempts to characterise those trends in current research with the aim of identifying the main mid-to-long term opportunities faced by electron-Volt neutron spectroscopy. The main realisation from this exercise is that the scientific community seems eager to combine neutron-based techniques over a broad energy range. To this end, the most natural choice seems to be to resort to neutron instruments where such capabilities are already present from the outset, with the most prominent example being the VESUVIO spectrometer at the ISIS pulsed neutron and muon source in the UK. However broad the operational basis of the existing neutron beamline infrastructure may be, progress, achievable only through further instrument upgrades, is the only way forward. The need to move forward is clearly seen within the community and is well documented by the research presented in this collection. This need for a substantial upgrade has crystallised in the form of a proposition to build a station rather than a conventional beamline, for Epithermal and Thermal Neutron Analysis station, hereafter ETNA.

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The onset of the tetrabonded structure in liquid water

Corsaro

Mallamace

Romanelli

et al. 2019

Sci. China Phys. Mech. Astron.

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Water properties are dominated by the hydrogen bond interaction that gives rise in the stable liquid phase to the formation of a dynamical network. The latter drives the water thermodynamics and is at the origin of its well known anomalies. The HB structural geometry and its changes remain uncertain and still are challenging research subjects. A key question is the role and effects of the HB tetrahedral structure on the local arrangement of neighboring molecules in water. Here the hydrogen dynamics in bulk water is studied through the combined use of Neutron Compton Scattering and NMR techniques. Results are discussed in the framework of previous studies performed in a wide temperature range, in the liquid, solid, and amorphous states. For the first time this combined studies provide an experimental evidence of the onset of the water tetrahedral network at T∼315 K, originally proposed in previous studies of transport coefficients and thermodynamical data; below this temperature the local order in water changes and the lifetime of local hydrogen bond network becomes long enough to gradually develop the characteristic tetrahedral network of water. water, neutron compton scattering, NMR

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Electron-volt neutron spectroscopy: beyond fundamental systems

Cited by 85 publications

References 217 publications

Hydrogen dynamics in solid formic acid: insights from simulations with quantum colored-noise thermostats

Hydrogen dynamics in solid formic acid: insights from simulations with quantum colored-noise thermostats

The road to a station for epithermal and thermal neutron analysis

The onset of the tetrabonded structure in liquid water

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