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32 results on '"Kim, Se-Kwon"'

1. Scalar Spin Chirality Hall Effect

Author

Go, Gyungchoon, Goli, Durga Prasad, Esaki, Nanse, Tserkovnyak, Yaroslav, and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The scalar spin chirality, which characterizes the fundamental unit of noncoplanar spin structures, plays an important role in rich chiral physics of magnetic materials. In particular, the intensive research efforts over the past two decades have demonstrated that the scalar spin chirality is the source of various novel Hall transports in solid-state systems, offering a primary route to bring about chiral phenomena in condensed matter physics. However, in all of the previous studies, the scalar spin chirality has been given as a stationary background, serving only a passive role in the transport properties of materials. It remains an open question whether or not the scalar spin chirality itself can exhibit a Hall-type transport. In this work, we show that the answer is yes: The scalar spin chirality is Hall-transported in Kagome ferromagnets and antiferromagnets under an external bias, engendering a phenomenon which we dub the scalar spin chirality Hall effect. Notably, this effect is present even in the absence of any spin-orbit coupling. The analytical theory for the scalar spin chirality Hall effect is corroborated by atomistic spin simulations. Our findings call for the need to lift the conventional assumption that the scalar spin chirality is a passive background in order to discover the active roles of the scalar spin chirality in transport properties., Comment: 9 pages, 4 figures

Published
2024

2. Intrinsic Nernst effect of the magnon orbital moment in a honeycomb ferromagnet

Author

An, Daehyeon and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The Nernst effect of the magnon orbital moment is theoretically investigated in a honeycomb ferromagnet, whose Hamiltonian contains the Heisenberg exchange, the Dzyaloshinskii-Moriya, the Kitaev, and the Zeeman interactions. More specifically, we obtain the magnon band structure, the Berry curvature, the magnon orbital moment Berry curvature, and the magnon orbital moment Nernst conductivity (MOMNC) for the Hamiltonian within the linear spin-wave theory in the polarized phase. We found the magnon orbital moment Berry curvature is largely independent of the sign of the Chern number of the band. For an experimental proposal, we estimate MOMNC of $\mathrm{CrI}_{3}$ for the Heisenberg-Kitaev-$\Gamma$-Zeeman model and Heisenberg-Dzyaloshinskii-Moriya-Zeeman model for a perpendicular external magnetic field. We found that certain Kitaev materials provide us with a broad tunability of the MOMNC through a magnetic field. We envision that our findings lead to further investigations of the novel transport properties of the magnon orbital moment.

Published
2024

3. Intersublattice entanglement entropy of ferrimagnetic spin chains

Author

Lee, Jongmin Y. and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Ferrimagnets are antiparallel-ordered magnetic states in a bipartite lattice with two alternating unequal spins, which exhibit both ferromagnetic and antiferromagnetic properties. Several theoretical studies have explored the magnetic properties of ferrimagnets, but the entanglement entropy of ferrimagnets with arbitrary spin combinations has not been studied. In this study, we analytically derive the intersublattice entanglement entropy of a ferrimagnetic spin chain using the method that has been applied to the antiferromagnetic case. The analytical results are numerically verified using the density matrix renormalization group. Going beyond the results for antiferromagnets, the entanglement entropy of ferrimagnets for fixed anisotropy is shown to solely depend on the difference of spins relative to its geometric average, and the quantity is shown to be stable against small parameter variations., Comment: 6 pages, 3 figures

Published
2024

4. Exchange striction induced thermal Hall effect in van der Waals antiferromagnet MnPS$_3$

Author

Yang, Heejun, Go, Gyungchoon, Park, Jaena, Kim, Se Kwon, and Park, Je-Geun

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter
Abstract

The thermal Hall effect has emerged as an ideal probe for investigating topological phenomena of charge-neutral excitation. Notably, it reveals crucial aspects of spin-lattice couplings that have been difficult to access for decades. However, the exchange striction mechanism from a lattice-induced change in exchange interaction has often been ignored in thermal Hall experiments. MnPS3 can offer a platform to study exchange striction on the thermal Hall effect due to its significant spin-lattice coupling and field-induced non-collinear spin configuration. Our thermal transport data show distinct temperature and field dependence of longitudinal thermal conductivity ($\kappa_{xx}$) and thermal Hall effect ($\kappa_{xy}$). By using detailed theoretical calculation, we found that the inclusion of the exchange striction is essential for a better description of both $\kappa_{xx}$ and $\kappa_{xy}$. Our result demonstrates the importance of the exchange striction mechanism for a complete understanding of the magnon-phonon-driven thermal Hall effect., Comment: 24 pages, 6 figures, accepted for publication in Phys. Rev. B

Published
2024
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5. Beyond skyrmion spin texture from quantum Kelvin-Helmholtz instability

Author

Huh, SeungJung, Yun, Wooyoung, Yun, Gabin, Hwang, Samgyu, Kwon, Kiryang, Hur, Junhyeok, Lee, Seungho, Takeuchi, Hiromitsu, Kim, Se Kwon, and Choi, Jae-yoon

Subjects
Condensed Matter - Quantum Gases, Physics - Atomic Physics, Quantum Physics
Abstract

Topology profoundly influences diverse fields of science, providing a powerful framework for classifying phases of matter and predicting nontrivial excitations, such as solitons, vortices, and skyrmions. These topological defects are typically characterized by integer numbers, called topological charges, representing the winding number in their order parameter field. The classification and prediction of topological defects, however, become challenging when singularities are included within the integration domain for calculating the topological charge. While such exotic nonlinear excitations have been proposed in the superfluid $^3$He-A phase and spinor Bose-Einstein condensate of atomic gases, experimental observation of these structures and studies of their stability have long been elusive. Here we report the observation of a singular skyrmion that goes beyond the framework of topology in a ferromagnetic superfluid. The exotic skyrmions are sustained by undergoing anomalous symmetry breaking associated with the eccentric spin singularity and carry half of the elementary charge, distinctive from conventional skyrmions or merons. By successfully realizing the universal regime of the quantum Kelvin-Helmholtz instability, we identified the eccentric fractional skyrmions, produced by emission from a magnetic domain wall and a spontaneous splitting of an integer skyrmion with spin singularities. The singular skyrmions are stable and can be observed after 2~s of hold time. Our results confirm the universality between classical and quantum Kelvin-Helmholtz instabilities and broaden our understanding on complex nonlinear dynamics of nontrivial texture beyond skyrmion in topological quantum systems., Comment: 13 pages, 5 main figures and 7 supplemental figures

Published
2024

6. Emergence of Meron Kekul\'e lattices in twisted N\'eel antiferromagnets

Author

Kim, Kyoung-Min and Kim, Se Kwon

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A Kekul\'e lattice is an exotic, distorted lattice structure distinguished by alternating bond lengths in contrast to naturally formed atomic crystals. While this structure has been explored through atomic crystals and metamaterials, the possibility of forming a Kekul\'e lattice from topological solitons in magnetic systems has remained elusive. Here, we propose twisted bilayer easy-plane N\'eel antiferromagnets as a promising platform for achieving a "Meron Kekul\'e lattice" -- a distorted topological soliton lattice comprised of antiferromagnetic merons as its lattice elements. Using atomistic spin simulations on these magnets, we demonstrate that due to the moir\'e-induced intricate pattern of interlayer exchange coupling, the cores of these merons are stabilized into the Kekul\'e-O pattern with different intracell and intercell bond lengths across moir\'e supercells, hence forming a Meron Kekul\'e lattice. Furthermore, we showcase that the two bond lengths of the Meron Kekul\'e lattice can be fine-tuned by adjusting the twist angle and specifics of the interlayer exchange coupling, suggesting extensive control over the meron lattice configuration in contrast to conventional magnetic systems. These discoveries pave the way for exploring topological solitons with distinctive Kekul\'e attributes, offering intriguing opportunities at the intersection of topological solitons and Kekul\'e physics., Comment: Supplementary Information is included in the published version

Published
2024

7. Non-Abelian Gauge Theory for Magnons in Topologically Textured Frustrated Magnets

Author

Zarzuela, Ricardo and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We develop an effective gauge theory for three-flavored magnons in frustrated magnets hosting topological textures with the aid of the quaternion representation of the SO(3) order parameter. We find that the effect of topological solitons on magnons is captured generally by the non-Abelian emergent electromagnetic fields, distinct from the previously established gauge theory for magnons in collinear magnets where the gauge theory is often restricted to be Abelian. As concrete examples, $4\pi$-vortices in two-/three-dimensional magnets and Shankar skyrmions in three-dimensional magnets are discussed in detail, which are shown to induce, respectively, the Abelian and the non-Abelian topological magnetic field on magnons, and thereby engender the topological Hall transport in textured frustrated magnets. Our work is applicable to a broad class of magnetic materials whose low-energy manifold is described by the SO(3) order parameter. We envision that the discovery of the non-Abelian magnonic gauge theory will enrich the field of magnonics as well as prompt the study of magnon transport in textured frustrated magnets., Comment: 6 pages, 2 figures

Published
2024

8. Domain Wall Networks as Skyrmion Crystals in Chiral Magnets

Author

Lee, Seungho, Fujimori, Toshiaki, Nitta, Muneto, and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory
Abstract

We theoretically investigate the ground states of a chiral magnet with a square anisotropy and show that it supports domain wall networks as stable ground states. A domain wall junction in the domain wall network turns out to be a skyrmion with half topological charge and, therefore, the found domain wall network has a second topological nature, a skyrmion crystal. More specifically, we present a ground-state phase diagram of the chiral magnet with varying anisotropy parameters consisting of skyrmion lattices, chiral soliton lattices, and ferromagnetic states. In the presence of the square anisotropy, the skyrmion crystal forms a domain wall network. The size of domains in the domain wall network is shown to be tunable by an external magnetic field, offering a way to realize experimentally detectable domain wall networks., Comment: 8 pages, 6 figures, 2 pages of supplemental material

Published
2024

9. Control of spin-wave polarity and velocity using a ferrimagnetic domain wall

Author

Faridi, Ehsan, Vignale, Giovanni, and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present a theoretical study of the scattering of spin waves by a domain wall (DW) in a ferrimagnetic (FiM) spin chain in which two sublattices carry spins of unequal magnitudes. We find that a narrow, but atomically smooth FiM DW exhibits a different behavior in comparison with similarly smooth ferromagnetic and antiferromagnetic DWs due to the inequivalence of the two sublattices. Specifically, for sufficiently weak anisotropy, the smaller spin at the center of the DW is found to become precisely normal to the easy-axis, selecting an arbitrary direction in the $xy$-plane and thereby breaking the U(1) spin-rotational symmetry spontaneously. This particular form of a FiM DW does not occur in antiferromagnetic systems and is shown to lead to a strong dependence of spin wave scattering pattern on the state of polarization of the spin wave, which can be either right-handed or left-handed, suggesting the utilization of such a narrow DW as a spin-wave filter. Moreover, we find that in the case of an atomically sharp DW, where all the spins point either up or down due to strong easy-axis anisotropy and therefore the polarization of the spin wave is conserved upon transmission, the wave vector of the spin wave changes after passing through the DW leading to a change in the group velocity of the spin wave. This change of the wave vector indicates the acceleration or deceleration of the spin waves and thus a sharp FiM DW could serve as a spin wave accelerator or decelerator in spintronics devices, offering a functionality absent in a ferromagnetic and an antiferromagnetic counterpart. Our results indicate that FiM spin textures can interact with spin waves distinctly from ferromagnetic and antiferromagnetic counterparts, suggesting that they may offer spin-wave functionalities that are absent in more conventional magnets.

Published
2024

10. Tunable Ultrafast Dynamics of Antiferromagnetic Vortices in Nanoscale Dots

Author

Zou, Ji, Thingstad, Even, Kim, Se Kwon, Klinovaja, Jelena, and Loss, Daniel

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Topological vortex textures in magnetic disks have garnered great attention due to their interesting physics and diverse applications. However, up to now, the vortex state has mainly been studied in microsize ferromagnetic disks, which have oscillation frequencies confined to the GHz range. Here, we propose an experimentally feasible ultrasmall and ultrafast vortex state in an antiferromagnetic nanodot surrounded by a heavy metal, which is further harnessed to construct a highly tunable vortex network. We theoretically demonstrate that, interestingly, the interfacial Dzyaloshinskii-Moriya interaction (iDMI) induced by the heavy metal at the boundary of the dot acts as an effective chemical potential for the vortices in the interior. Mimicking the creation of a superfluid vortex by rotation, we show that a magnetic vortex state can be stabilized by this iDMI. Subjecting the system to an electric current can trigger vortex oscillations via spin-transfer torque, which reside in the THz regime and can be further modulated by external magnetic fields. Furthermore, we show that coherent coupling between vortices in different nanodisks can be achieved via an antiferromagnetic link. Remarkably, this interaction depends on the vortex polarity and topological charge and is also exceptionally tunable through the vortex resonance frequency. This opens up the possibility for controllable interconnected networks of antiferromagnetic vortices. Our proposal therefore introduces a new avenue for developing high-density memory, ultrafast logic devices, and THz signal generators, which are ideal for compact integration into microchips., Comment: 11 pages including supplemental material; 4 figures

Published
2024

12. Designed spin-texture-lattice to control anisotropic magnon transport in antiferromagnets

Author

Meisenheimer, Peter, Ramesh, Maya, Husain, Sajid, Harris, Isaac, Park, Hyeon Woo, Zhou, Shiyu, Taghinejad, Hossein, Zhang, Hongrui, Martin, Lane W., Analytis, James, Stevenson, Paul, Íñiguez-González, Jorge, Kim, Se Kwon, Schlom, Darrell G., Caretta, Lucas, Yao, Zhi, and Ramesh, Ramamoorthy

Subjects
Condensed Matter - Materials Science
Abstract

Spin waves in magnetic materials are promising information carriers for future computing technologies due to their ultra-low energy dissipation and long coherence length. Antiferromagnets are strong candidate materials due, in part, to their stability to external fields and larger group velocities. Multiferroic aniferromagnets, such as BiFeO$_3$ (BFO), have an additional degree of freedom stemming from magnetoelectric coupling, allowing for control of the magnetic structure, and thus spin waves, with electric field. Unfortunately, spin-wave propagation in BFO is not well understood due to the complexity of the magnetic structure. In this work, we explore long-range spin transport within an epitaxially engineered, electrically tunable, one-dimensional (1D) magnonic crystal. We discover a striking anisotropy in the spin transport parallel and perpendicular to the 1D crystal axis. Multiscale theory and simulation suggests that this preferential magnon conduction emerges from a combination of a population imbalance in its dispersion, as well as anisotropic structural scattering. This work provides a pathway to electrically-reconfigurable magnonic crystals in antiferromagnets.

Published
2024

13. Topological magnon-polarons in honeycomb antiferromagnets with spin-flop transition

Author

Go, Gyungchoon, Yang, Heejun, Park, Je-Geun, and Kim, Se Kwon

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We theoretically investigate the thermal Hall transport of magnon-polarons in a two-dimensional honeycomb antiferromagnetic insulator under the influence of a perpendicular magnetic field, varying in strength. The application of a perpendicular magnetic field induces a magnetic phase transition from the collinear antiferromagnetic phase to the spin-flop phase, leading to a significant alteration in Hall transport across the transition point. In this paper, our focus is on the intrinsic contribution to thermal Hall transport arising from the magnetoelastic interaction. To facilitate experimental verification of our theoretical results, we present the dependence of thermal Hall conductivity on magnetic field strength and temperature., Comment: 10 pages, 6 figures

Published
2024
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19. Ferulic acid grafted onto chitooligosaccharides attenuates LPS-stimulated in murine macrophages by modulating the NF-κB and MAPK pathways.

Author

Bui, Van-Hoai, N Vo, Hong-Tham, Binh Vong, Long, Kim, Se-Kwon, and Ngo, Dai-Nghiep

Abstract

Although chitooligosaccharides (COS) improve the drawbacks of chitosan, their biological activities in medical applications have not been highly appreciated. The main approach is to synthesise the COS derivatives in order to improve the biological properties of the COS. In this study, ferulic acid (FA) grafted onto COS (FA-COS) were synthesised and their mechanism of anti-inflammatory activity was investigated in the murine macrophage cells. The synthesis conditions of FA-COS were optimised and confirmed that the FA was successfully conjugated onto COS with the grafting effect of 15-34%. FA-COS exhibited anti-inflammatory activities via suppressing of nitric oxide formation, reducing iNOS expression at transcription and translation levels, down-regulation of TNF-α, IL-6 and IL-1 β genes; NF-κB and MAPKs signalling pathways. These results show anti-inflammatory molecular mechanism of FA-COS that exhibit enormous potential for prevention of inflammatory diseases. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Natural hydroxyapatite-based nanobiocomposites and their biomaterials-to-cell interaction for bone tissue engineering.

Author

Venkatesan, Jayachandran, Anchan, Rowena Valeen, Murugan, Sesha Subramanian, Anil, Sukumaran, and Kim, Se-Kwon

Subjects
BONE substitutes, FOURIER transform infrared spectroscopy, BONE grafting, TRANSMISSION electron microscopy, SCANNING electron microscopy, HYDROXYAPATITE
Abstract

Hydroxyapatite (HA) is an extensively used biomaterial for dental and orthopaedic applications because of its biocompatibility and biomimetic nature. HA is extensively used as a bone-graft substitute. HA bone graft substitutes of bovine or synthetic origins have been extensively studied. However, caprine-based HA has not been explored. In this study, we aimed to determine the utilization of goat bone-derived HA for commercial applications. HA from caprine bone and teeth was isolated using thermal calcination. The developed HA can be used as a bone graft substitute. Chemical characterization of the isolated HA was carried out using Fourier transform infrared spectroscopy, X-Ray Diffraction, Raman spectroscopy, scanning electron microscopy, and transmission electron microscopy. The biocompatibility and apatite formation of isolated HA were assessed using MG-63 cells, MC3T3-E1, L929 cells, MSCs, adipose derived stem cells, human dermal tissue derived fibroblast cells and osteoblast-like cell line, The studies demonstrate that HA support cell adhesion and osteogenic properties. To improve sheep, lamp, or caprine bone-derived HA, several other composites have been developed with MgO2, ZrO2, ZnO2, and other polymeric substances. 3D printed technology was used to develop a bioink using sheep-derived HA and printed the composite scaffold as a bone graft substitute. Furthermore, the biomedical applications of sheep-derived HA been studied in terms of their antimicrobial activity, bone-forming ability, and wound healing applications. Sheep-, goat-, and caprine-derived HA are still underutilized and require further research to develop commercial possibilities and sustainable raw materials for HA-based bone graft substitutes. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Special Issue on Solitons in Quantum Physics

Author

Chung, Suk Bum, Kim, Se Kwon, Babaev, Egor, Zang, Jiadong, Chung, Suk Bum, Kim, Se Kwon, Babaev, Egor, and Zang, Jiadong

Abstract

This is an Editorial for the Special Issue on Solitons in Quantum Physics., QC 20240827

Published
2024
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26. Chapter 22: Recent Advances in the Application of Microalgae-based Bioremediation of Pharmaceutical Waste

Author

Ravishankar, Gokare A., Rao, Ambati Rango, Kim, Se-Kwon, Teoh, Ming-Li, Choo, Wu-Thong, Convey, Peter, Ravishankar, Gokare A., Rao, Ambati Rango, Kim, Se-Kwon, Teoh, Ming-Li, Choo, Wu-Thong, and Convey, Peter

Abstract

Pharmaceuticals are therapeutic drugs used to treat or prevent human or animal diseases. The incomplete breakdown of these drugs in the body can lead to their release into the environment through excretion, where they may bioaccumulation, and their toxicity may have negative impacts on aquatic and terrestrial organisms, ecosystems and human health. Conventional wastewater treatment plants (WWTPs) are not designed to effectively remove specific pharmaceutical waste. Other technologies such as membrane filtration, activated carbon adsorption, and hybrid processes can more efficiently remove pharmaceutical wastes. However, they are expensive, and their large-scale applications are currently not economical or sustainable. Therefore, the search for sustainable and low-cost technologies has been accelerating. Microalgae have attracted attention as a means of removing pharmaceutical waste in water. In this chapter, we describe and discuss the use of various low-cost methods of cultivating and applying microalgae to treat pharmaceutical products in wastewater.

Published
2024

27. "Drug-Free" chitosan nanoparticles as therapeutic for cancer treatment.

Author

Iskandar, Athirah, Kim, Se-Kwon, and Wong, Tin Wui

Subjects
*DEACETYLATION, *CHITOSAN, *NANOPARTICLES, *DRUG solubility, *CANCER treatment, *ANTINEOPLASTIC agents, *NANOMEDICINE
Abstract

Chitosan is cancer cytotoxic. It induces apoptosis/necrosis/autophagy and immuno-responses, and mitigates angiogenic and metastasis tendency of cancer cells. The lower molecular weight chitosan induces apoptosis, whereas the higher molecular weight chitosan exerts apoptosis and necrosis. Transforming chitosan into nanoparticles raises its anti-cancer efficacy with mode of cancer cell death governed by particle size to a greater extent than chitosan molecular weight. The larger nanoparticles tend to exert apoptosis. The smaller nanoparticles mediate necrosis. "Drug-free" small nanoparticles constituted of lower molecular weight chitosan are more cytotoxic than those of larger chitosan molecules/particles in vitro and in vivo, with no clear relationship between the deacetylation degree and zeta potential of nanoparticulate chitosan with anti-cancer activity. "Drug-free" chitosan nanoparticles are potentially as viable as the drug-loaded chitosan nanoparticles but with reduced systemic adverse effects. Their anti-cancer efficacy can be modulated through particle dose adjustment with lower risks of harmful effects than drugs and without processing hurdles faced in the development of drug-loaded chitosan nanoparticles such as low aqueous drug solubility, poor drug encapsulation, premature drug release and drug absorption, and drug instability with toxic metabolite formation. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Optimization of alginate/carboxymethyl chitosan microbeads for the sustained release of celecoxib and attenuation of intestinal inflammation in vitro.

Author

Biji CA, Balde A, Kim SK, and Nazeer RA

Abstract

Multiple anti-inflammatory medications have helped treat inflammatory bowel disease (IBD). However, oral administration has minimal absorption and systemic side effects. This study aims to investigate the potential of encapsulating anti-inflammatory drug celecoxib (Cele) within microbeads for the treatment of IBD. Microbeads were formed by cross-linking carboxymethyl chitosan (CMCs) with sodium alginate (Alg) through the ionic gelation method and optimized through response surface methodology. Additionally, the study revealed a mucoadhesivity value of 59.32 ± 0.74 % for the optimized microbead system. The drug release study demonstrated the sustained release of Cele CMCs/Alg microbeads upto 24 h compared to quick release of the free drug. The results of the cell viability assay indicated that the Cele-Alg/CMCs microbeads exhibited a non-toxic nature within the concentration range of 100-250 μM. A significant decrease in nitric oxide (NO) generation (61.14 ± 3.67 %) was seen in HCT-116 cells stimulated with lipopolysaccharide (LPS) upon treatment with Cele-250 μM /CMCs/Alg microbeads. The results of the reactive oxygen species and wound healing assay suggest that Cele-250 μM /CMCs/Alg microbeads had improved anti-inflammatory characteristics comparable to those of free drug treatment. The western blot analysis demonstrated that the microbeads composed of CMCs/Alg-Cele possess the capacity to inhibit the expression of COX-2 in vitro supressing inflammation., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published
2024
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32. Designed Spin-Texture-Lattice to Control Anisotropic Magnon Transport in Antiferromagnets.

Author

Meisenheimer P, Ramesh M, Husain S, Harris I, Park HW, Zhou S, Taghinejad H, Zhang H, Martin LW, Analytis J, Stevenson P, Íñiguez-González J, Kim SK, Schlom DG, Caretta L, Yao Z, and Ramesh R

Abstract

Spin waves in magnetic materials are promising information carriers for future computing technologies due to their ultra-low energy dissipation and long coherence length. Antiferromagnets are strong candidate materials due, in part, to their stability to external fields and larger group velocities. Multiferroic antiferromagnets, such as BiFeO 3 (BFO), have an additional degree of freedom stemming from magnetoelectric coupling, allowing for control of the magnetic structure, and thus spin waves, with the electric field. Unfortunately, spin-wave propagation in BFO is not well understood due to the complexity of the magnetic structure. In this work, long-range spin transport is explored within an epitaxially engineered, electrically tunable, 1D magnonic crystal. A striking anisotropy is discovered in the spin transport parallel and perpendicular to the 1D crystal axis. Multiscale theory and simulation suggest that this preferential magnon conduction emerges from a combination of a population imbalance in its dispersion, as well as anisotropic structural scattering. This work provides a pathway to electrically reconfigurable magnonic crystals in antiferromagnets., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published
2024
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