% IMPORTANT: The following is UTF-8 encoded. This means that in the presence
% of non-ASCII characters, it will not work with BibTeX 0.99 or older.
% Instead, you should use an up-to-date BibTeX implementation like “bibtex8” or
% “biber”.
@INPROCEEDINGS{Plokhikh:1041118,
author = {Plokhikh, Igor},
title = {{D}iffraction studies of quantum materials},
reportid = {FZJ-2025-02152},
year = {2025},
abstract = {Resolving crystal and magnetic structures using diffraction
methods is of indispensable importance, as it serves as the
key towards understanding the properties of functional
material in a broad sense. In this talk, I would like to
give a brief introduction to my previous research done using
X-ray and neutron diffraction focusing on three case
studies:1. The first object is kagome superconductor
LaRu3Si2, which besides superconductivity below ca. 7K
features a cascade of structural phase transitions with
temperature [1]. Using variable-temperature X-ray
diffraction I show which superstructure orders evolve in
this material. Furthermore, using (3+N)D crystallography
approaches, the models of crystal structures in direct space
were proposed.2. The interplay between band topology and
magnetism can result in intricate physics. Here I would like
to present the results of the microscopic magnetic studies
using neutron powder diffraction for the LnSbTe (Ln –
lanthanides) family of Dirac nodal line semimetals. Although
bulk properties measurements hint at single
antiferromagnetic transition in HoSbTe and TbSbTe, neutron
powder diffraction measurements reveal multiple
incommensurate and commensurate phases coexisting or
competing in below the Neel temperature [2]. Magnetic
symmetry arguments suggest multi-k order in one member,
TbSbTe. The possible relation of this peculiar magnetic
behavior with the electronic structure is outlined.3.
Layered nickelates were re-discovered recently as
high-temperature superconductors at elevated pressure.
Similar to cuprates and iron-based families, the
superconductivity, structural and magnetic instabilities
represent competing phenomena and can be tuned by external
(pressure) or internal (substitution) parameters. In the
case of the prototype member, La3Ni2O7, spin density wave
order has been deduced using various macroscopic and
microscopic probes. Still the most direct method – neutron
diffraction – was ineffective in detecting this magnetic
order, raising debates on the nature of the magnetically
ordered state in this material. Using high-flux cold neutron
diffraction, I unambiguously show long-range character of
the spin-density wave in the oxygen stoichiometric La3Ni2O7
and La2PrNi2O7. The magnetic structure represents
alternating Ni-moment stripes of 0.8µB and 0.15µB. The
proposed models reproduce also the features of muon spectra.
One peculiar feature of La3Ni2O7 is the presence of several
magnetic stacking polymorphs.[1] Plokhikh, I., Mielke III,
C., Nakamura, H., et al. (2024). Discovery of charge order
above room-temperature in the prototypical kagome
superconductor La(Ru₁₋ₓFeₓ)₃Si₂. Communications
Physics, 7, 182.[2] Plokhikh, I., Pomjakushin, V., Gawryluk,
D. J., Zaharko, O., $\&$ Pomjakushina, E. (2022). Competing
magnetic phases in LnSbTe (Ln = Ho and Tb). Inorganic
Chemistry, 61(29), 11399–11409.[3] Plokhikh, I., Hicken,
T. J., Keller, L., et al (2025). Unraveling spin density
wave order in layered nickelates La₃Ni₂O₇ and
La₂PrNi₂O₇ via neutron diffraction
(arXiv:2503.05287).},
organization = {(Digital) Institute Seminar JCNS-2,
(Germany)},
subtyp = {Invited},
cin = {JCNS-2 / JARA-FIT},
cid = {I:(DE-Juel1)JCNS-2-20110106 / $I:(DE-82)080009_20140620$},
pnm = {632 - Materials – Quantum, Complex and Functional
Materials (POF4-632) / 6G4 - Jülich Centre for Neutron
Research (JCNS) (FZJ) (POF4-6G4)},
pid = {G:(DE-HGF)POF4-632 / G:(DE-HGF)POF4-6G4},
typ = {PUB:(DE-HGF)31},
url = {https://juser.fz-juelich.de/record/1041118},
}
Gast ::