Imaging of cultural heritage objects using neutron resonances

Cippo, E. Perelli; Borella, A.; Gorini, G.; Kockelmann, W.; Moxon, M.C.; Postma, H.; Rhodes, N.J.; Schillebeeckx, P.; Schoonenveld, Eric M.; Tardocchi, M.; Dusz, Krisztina; Hajnal, Zsuzsa; Biró, Katalin T.; Porcinai, Simone; Andreani, C.; Festa, G.

doi:10.1039/c0ja00256a

Cited by 31 publications

(18 citation statements)

References 17 publications

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“…The MCP detector used in our experiments is capable of neutron counting with simultaneous <100 /lm spatial and sub-/ls temporal resolution, enabling an order of magnitude improvement compared to previous measurements performed with a 1 Ox 1 0 pixel detector with 2x2 mm 2 pixels [6], [9].…”

Section: Introductionmentioning

confidence: 91%

“…Capture of the fine detail in these images is enabled by the high spatial resolution of our detection system. Previous measurements performed with a lOxlO detector only allowed a crude map of the silver distribution across the same belt mount [6]. The improved spatial resolution should enable high resolution non destructive elemental/isotopic mapping within objects containing elements and isotopes with relatively low resonance energies in the range 1-100 eV.…”

Section: B Nrai Imaging Of a Belt Mount Replicamentioning

confidence: 99%

“…In this method the energy of the transmitted neutrons is measured by the neutron time of flight (TOF) providing the detector can both spatially and temporally resolve registered neutrons. The potential of neutron resonance absorption imaging (NRAI) was demonstrated by the previous measurements, where a number of museum artifacts were studied in terms of their constituent materials [4], [6], [9]. The depths of neutron absorption resonances can be translated into the quantitative amounts of specific elements in the sample, with the spatial resolution defined by the detector pixellation used in the experiments.…”

Section: Introductionmentioning

confidence: 98%

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High resolution neutron resonance absorption imaging at a pulsed neutron beamline

Tremsin¹,

McPhate²,

Vallerga³

et al. 2011

2011 IEEE Nuclear Science Symposium Conference Record

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The existence of resonance peaks in neutron absorption spectra in the epithermal range of energies enables unique non-destructive testing techniques. The deep penetration of epithermal neutrons provides the opportunity to perform a compositional analysis of a sample which is opaque to X-rays and thermal neutrons. The neutron resonances in the transmission spectra constitute a characteristic pattern for many isotopes, which can be used to identify the isotope and to map the distribution of the isotope in a sample. The neutron transmission spectra can be measured with the time of flight (TOF) technique using a pulsed neutron source. Combining this method with a high resolution neutron counting detector enables substantial improvements of spatial resolution of neutron resonance transmission imaging. Such a detector has been developed to register neutrons with 55 J.UIl spatial and 10-1000 ns temporal resolution Our proof-of-principle experiments at the ISIS pulsed neutron spallation source demonstrate that compositional analysis of multi-element samples can now be performed with -150 J.UIl spatial resolution. Images of a test mask consisting of <200 J.UIl thick foils of Au, Ag, In and Gd were collected in the 1-100 eV energy range. The experimental results demonstrate the potential for compositional analysis via resonance absorption transmission with high spatial resolution. In-bulk temperature measurement through Doppler broadening analysis will also benefit from this technique.

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Section: Introductionmentioning

confidence: 91%

Section: B Nrai Imaging Of a Belt Mount Replicamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

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High resolution neutron resonance absorption imaging at a pulsed neutron beamline

Tremsin¹,

McPhate²,

Vallerga³

et al. 2011

2011 IEEE Nuclear Science Symposium Conference Record

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“…Moreover, many elements have overlapping peaks and some emitted X-rays may not escape the sample and be detected, reducing the accuracy in inhomogeneous samples 29) . Neutron Resonance Capture Analysis (NRCA) is a technique for the determination of elemental composition, making use of a pulsed beam of epithermal neutrons and a TOF system to recognize resonances of isotopes in the energy range of ~1 eV to ~10 keV 30,31) . For many metallic materials, the impinging epithermal neutrons are resonantly captured by the material's nuclei, showing intense peaks in the absorption cross section (probability of a neutron being absorbed by a nucleus).…”

Section: Introductionmentioning

confidence: 99%

Orthodontic archwire composition and phase analyses by neutron spectroscopy

Tian

Festa

Basoli

et al. 2017

Dental Materials Journal

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Quantitative metallurgical and phase analyses employing neutron diffraction technique were conducted on two as-received commercial rectangular austenitic stainless steel orthodontic archwires, G&H and Azdent, 0.43×0.64 mm (0.017×0.025 inch). Results showed a bi-phase structure containing martensitic phase (45.67% for G&H and 6.62% for Azdent) in addition to the expected metastable austenite. The former may be a strain-induced phase-transformation arising during the cold working process of wire fabrication. Further neutron resonance capture analysis determinations provided atomic and isotopic compositions, including alloying elements in each sample, complementary to the results of traditional energy dispersive X-ray spectroscopy. Together, these results assist in relating commercial alloying recipes and processing histories with mechanical performance, strength and ductility in particular.

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“…Although fast neutrons are useful for many applications, such as imaging [6] and material testing for fusion reactor vessels [7], the arena of neutron science and applications mainly requires slow neutrons (with energies ranging from sub-meV to keV) which are provided at reactor [8] and accelerator [9] based facilities by moderating fast neutrons. In particular, sources of epithermal neutrons (eV-100keV) are of high interest for a wide range of applications, from material science [10][11][12] to nuclear waster transmutations [13] and healthcare [14,15]. However, the scale and operational costs involved in accelerator-based facilities not only limit their availability to the scientific community, but also hinder their wide promotion in the industrial, security and healthcare sectors.…”

mentioning

confidence: 99%

Experimental demonstration of a compact epithermal neutron source based on a high power laser

Mirfayzi

Alejo

Ahmed

et al. 2017

Applied Physics Letters

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Epithermal neutrons from pulsed-spallation sources have revolutionised neutron science allowing scientists to acquire new insight into the structure and properties of matter. Here, we demonstrate that laser driven fast (∼MeV) neutrons can be efficiently moderated to epithermal energies with intrinsically short burst durations. In a proof-of-principle experiment using a 100 TW laser, a significant epithermal neutron flux of the order of 105 n/sr/pulse in the energy range of 0.5–300 eV was measured, produced by a compact moderator deployed downstream of the laser-driven fast neutron source. The moderator used in the campaign was specifically designed, by the help of MCNPX simulations, for an efficient and directional moderation of the fast neutron spectrum produced by a laser driven source.

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Imaging of cultural heritage objects using neutron resonances

Cited by 31 publications

References 17 publications

High resolution neutron resonance absorption imaging at a pulsed neutron beamline

High resolution neutron resonance absorption imaging at a pulsed neutron beamline

Orthodontic archwire composition and phase analyses by neutron spectroscopy

Experimental demonstration of a compact epithermal neutron source based on a high power laser

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