Abstract
The neutron, discovered in 1932 by James Chadwick, is a Fermion with no net electrostatic charge and a mass slightly higher than that of a proton. Owing to some of unique properties, various neutrons-based imaging and non-imaging techniques have been developed and are used extensively in various research applications. In this chapter, we discuss some of the basic properties of the neutron and classify the neutrons as per their energies. A brief discussion about the neutron interaction with matter in terms of scattering cross sections has also been presented. The concept of neutron imaging and its applications for characterization and non-destructive evaluation of wide variety of materials have been discussed to highlight the importance of these techniques. We also discuss a comparison of neutron with the X-rays.
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References
https://mappingignorance.org/2020/06/10/neutron-sciences-as-an-essential-tool-to-develop-materials-for-a-better-life/. Accessed on 15 July 2021
Bell RE, Elliott LG (1948) Gamma-rays from the reaction 1H(n, γ)D2 and the binding energy of the deuteron. Phys Rev 74(10):1552–1553
Bell RE, Elliott LG (1950) Gamma-rays from the reaction 1H(n, γ)D2 and the binding energy of the deuteron. Phys Rev 79(2):282–285
Shull CG, Billman KW, Wedgwood FA (1967) Experimental limit for the neutron charge. Phys Rev 153(5):1415–1422
Olive KA (2014) Review of particle physics. Chin Phys C 38(9):090001
Alvarez LW, Bloch F (1940) A quantitative determination of the neutron moment in absolute nuclear magnetons. Phys Rev 57(2):111–122
Perkins DH (1982) Introduction to high energy physics. Addison-Wesley Advanced Book Program/World Science Division
Bég MAB, Lee BW, Pais A (1964) SU(6) and electromagnetic interactions. Phys Rev Lett 13(16):514–517
Sherwood JE, Stephenson TE, Bernstein S (1954) Stern-gerlach experiment on polarized neutrons. Phys Rev 96(6):1546–1548
Hughes DJ, Burgy MT (1949) Reflection and polarization of neutrons by magnetized mirrors. Phys Rev 76(9):1413–1414
Wietfeldt FE, Greene GL (2011) Colloquium: the neutron lifetime. Rev Mod Phys 83(4):1173–1192
Yue AT et al (2013) Improved determination of the neutron lifetime. Phys Rev Lett 111(22):222501
Particle Data Group (2018) Review of particle physics. Phys Rev D 98(3):030001
Schlenker M, Baruchel J (1986) Neutron topography: a review. Physica B+C 137(1):309–319
Luschikov VI et al (1969) Observation of ultracold neutrons. Sov Phys—JETP Lett 9:23
Zeldovich YaB (1959) Storage of cold neutrons. Sov Phys—JETP 9:1389
https://www.psi.ch/en/niag/neutron-physics. Accessed on 15 Sept 2021
https://www.nuclear-power.com/nuclear-power/reactor-physics/atomic-nuclear-physics/fundamental-particles/neutron/neutron-energy/. Accessed on 15 Sept 2021
Carpenter J, Loong C (2015) Elements of slow-neutron scattering: basics, techniques, and applications. Cambridge University Press, Cambridge. https://doi.org/10.1017/CBO9781139029315
Ederth T (2018) Neutrons for scattering: what they are, where to get them, and how to deal withthem. EPJ Web Conf 188:01002. https://doi.org/10.1051/epjconf/201818801002. Accessed on 25 August 2021
http://cds.cern.ch/record/1514295/plots. Accessed on 27 July 2021
Kardjilov N, Manke I, Woracek R, Hilger A, Banhart J (2018) Advances in neutron imaging. Mater Today 21:652–672
Shukla M, Roy T, Kashyap Y et al (2018) Development of neutron imaging beamline for NDT applications at Dhruva reactor, India. Nucl Instrum Methods Phys Res Sect A 889:63–68
Saito Y, Mishima K, Tobita Y, Suzuki T, Matsubayashi M (2004) Velocity field measurement in gas–liquid metal two-phase flow with use of PIV and neutron radiography techniques. Appl Radiat Isot 61:683–691
Song B, Dhiman I, Carothers JC, Veith GM, Liu J, Bilheux HZ, Huq A (2019) Dynamic lithium distribution upon dendrite growth and shorting revealed by operando neutron imaging. ACS Energy Lett 4(10):2402–2408
Jacobson DL, Allman BE, McMahon PJ, Nugent KA, Paganin D, Arif M, Werner SA (2004) Thermal and cold neutron phase-contrast radiography. Appl Radiat Isot 61:547–550
Pfeiffer F, Grünzweig C, Bunk O, Frei G, Lehmann E, David C (2006) Neutron phase imaging and tomography. Phys Rev Lett 96:215505
Dawson M et al (2009) Imaging with polarized neutrons. New J Phys 11:043013. https://doi.org/10.1088/1367-2630/11/4/043013. Accessed on 25 August 2021
Piegsa FM, van den Brandt B, Hautle P, Konter JA (2009) A compact neutron Ramsey resonance apparatus for polarised neutron radiography. Nucl Instrum Methods Phys Res Sect A 605:5–8
Iwase et al (2012) In situ lattice strain mapping during tensile loading using the neutron transmission and diffraction methods. J Appl Cryst 45:113–118
Baruchel J, Schlenker M, Palmer SB (1990) Neutron diffraction topographic investigations of “exotic” magneticdomains. Nondestr Test Eval 5(5–6):349–367. https://doi.org/10.1080/02780899008952978
Kardjilov N, Manke I, Hilger A, Strobl M, Banhart J (2011) Neutron imaging in materials science. Mater Today 14:248–256
Mankea I, Banhart J et al (2007) In situ investigation of the discharge of alkaline Zn–MnO2 batteries with synchrotron X-ray and neutron tomographies. Appl Phys Lett 90:214102
Ziesche RF, Arlt T, Finegan DP et al (2020) 4D imaging of lithium-batteries using correlative neutron and X-ray tomography with a virtual unrolling technique. Nat Commun 11:777
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Kashyap, Y.S. (2022). Introduction to Neutron Physics. In: Aswal, D.K., Sarkar, P.S., Kashyap, Y.S. (eds) Neutron Imaging. Springer, Singapore. https://doi.org/10.1007/978-981-16-6273-7_1
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DOI: https://doi.org/10.1007/978-981-16-6273-7_1
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