TY - JOUR
T1 - Neutron diffraction
T2 - A primer
AU - Dronskowski, Richard
AU - Brückel, Thomas
AU - Kohlmann, Holger
AU - Avdeev, Maxim
AU - Houben, Andreas
AU - Meven, Martin
AU - Hofmann, Michael
AU - Kamiyama, Takashi
AU - Zobel, Mirijam
AU - Schweika, Werner
AU - Hermann, Raphaël P.
AU - Sano-Furukawa, Asami
N1 - Publisher Copyright:
© 2024 the author(s), published by De Gruyter, Berlin/Boston 2024.
PY - 2024
Y1 - 2024
N2 - Because of the neutron's special properties, neutron diffraction may be considered one of the most powerful techniques for structure determination of crystalline and related matter. Neutrons can be released from nuclear fission, from spallation processes, and also from low-energy nuclear reactions, and they can then be used in powder, time-of-flight, texture, single crystal, and other techniques, all of which are perfectly suited to clarify crystal and magnetic structures. With high neutron flux and sufficient brilliance, neutron diffraction also excels for diffuse scattering, for in situ and operando studies as well as for high-pressure experiments of today's materials. For these, the wave-like neutron's infinite advantage (isotope specific, magnetic) is crucial to answering important scientific questions, for example, on the structure and dynamics of light atoms in energy conversion and storage materials, magnetic matter, or protein structures. In this primer, we summarize the current state of neutron diffraction (and how it came to be), but also look at recent advances and new ideas, e.g., the design of new instruments, and what follows from that.
AB - Because of the neutron's special properties, neutron diffraction may be considered one of the most powerful techniques for structure determination of crystalline and related matter. Neutrons can be released from nuclear fission, from spallation processes, and also from low-energy nuclear reactions, and they can then be used in powder, time-of-flight, texture, single crystal, and other techniques, all of which are perfectly suited to clarify crystal and magnetic structures. With high neutron flux and sufficient brilliance, neutron diffraction also excels for diffuse scattering, for in situ and operando studies as well as for high-pressure experiments of today's materials. For these, the wave-like neutron's infinite advantage (isotope specific, magnetic) is crucial to answering important scientific questions, for example, on the structure and dynamics of light atoms in energy conversion and storage materials, magnetic matter, or protein structures. In this primer, we summarize the current state of neutron diffraction (and how it came to be), but also look at recent advances and new ideas, e.g., the design of new instruments, and what follows from that.
KW - diffuse scattering and PDF analysis
KW - in situ, operando and high-pressure studies
KW - magnetic diffraction
KW - multidimensional Rietveld and single-crystal diffraction
KW - neutron-matter interaction
KW - powder and time-of-flight diffraction
UR - http://www.scopus.com/inward/record.url?scp=85191961946&partnerID=8YFLogxK
U2 - 10.1515/zkri-2024-0001
DO - 10.1515/zkri-2024-0001
M3 - Article
AN - SCOPUS:85191961946
SN - 2194-4946
JO - Zeitschrift fur Kristallographie - Crystalline Materials
JF - Zeitschrift fur Kristallographie - Crystalline Materials
ER -