Your search keyword '"Fitzsimmons MR"' showing total 72 results

1. Realization of ordered magnetic skyrmions in thin films at ambient conditions

Author

Desautels, RD, Debeer-Schmitt, L, Montoya, SA, Borchers, JA, Je, SG, Tang, N, Im, MY, Fitzsimmons, MR, Fullerton, EE, and Gilbert, DA

Abstract

Magnetic skyrmions have captivated physicists due to their topological nature and novel physical properties. In addition, skyrmions hold significant promise for future information technologies. A key barrier to realizing skyrmion-based devices has been stabilizing these spin structures under ambient conditions. In this paper, we demonstrate that the tunable magnetic properties of amorphous Fe/Gd mulitlayers enable the formation of skyrmion lattices which are stable over a large temperature and magnetic field parameter space, including room temperature and zero magnetic field. These skyrmions, having a hybrid nature displaying both Bloch-type and Néel-type characteristics, are stabilized by dipolar interactions rather than Dzyaloshinskii-Moriya interactions, typically considered a requirement for the generation of skyrmions. Small angle neutron scattering (SANS) was used in combination with soft x-ray microscopy to provide a unique, multiscale probe of the local and long-range order of these structures. The hexagonal lattice seen in SANS results from the hybrid skyrmion picture obtained with micromagnetic simulations. These results identify a pathway to engineer controllable skyrmion phases in thin film geometries which are stable at ambient conditions.

Published

2019

2. Deposition order dependent magnetization reversal in pressure graded Co/Pd films

Author

Greene, PK, Kirby, BJ, Lau, JW, Borchers, JA, Fitzsimmons, MR, and Liu, Kai

Subjects

2.1 Biological and endogenous factors, Aetiology, cond-mat.mtrl-sci, Physical Sciences, Engineering, Technology, Applied Physics

Abstract

Magnetization reversal mechanisms and depth-dependent magnetic profile have been investigated in Co/Pd thin films magnetron-sputtered under continuously varying pressure with opposite deposition orders. For samples grown under increasing pressure, magnetization reversal is dominated by domain nucleation, propagation, and annihilation; an anisotropy gradient is effectively established, along with a pronounced depth-dependent magnetization profile. However, in films grown under decreasing pressure, disorders propagate vertically from the bottom high-pressure region into the top low-pressure region, impeding domain wall motion and forcing magnetization reversal via rotation; depth-dependent magnetization varies in an inverted order, but the spread is much suppressed. © 2014 AIP Publishing LLC.

Published

2014

3. Influence of in-plane crystalline quality of an antiferromagnet on perpendicular exchange coupling and exchange bias

Author

Fitzsimmons, MR, Leighton, C, Nogués, J, Hoffmann, A, Liu, Kai, Majkrzak, CF, Dura, JA, Groves, JR, Springer, RW, Arendt, PN, Leiner, V, Lauter, H, and Schuller, Ivan K

Subjects

Inorganic Chemistry, Chemical Sciences, Chemical sciences, Engineering, Physical sciences

Abstract

We have undertaken a systematic study of the influence of in-plane crystalline quality of the antiferromagnet on exchange bias. Polarized neutron reflectometry and magnetometry were used to determine the anisotropies of polycrystalline ferromagnetic (F) Fe thin films exchange coupled to antiferromagnetic (AF) untwinned single crystal (110) (formula presented) twinned single crystal (110) (formula presented) thin films and (110) textured polycrystalline (formula presented) thin films. A correlation between the anisotropies of the AF and F thin films with exchange bias was identified. Specifically, when exchange coupling across the F-AF interface introduces an additional anisotropy axis in the F thin film-one perpendicular to the cooling field, the magnetization reversal mechanism is affected (as observed with neutron scattering) and exchange bias is significantly enhanced. © 2002 The American Physical Society.

Published

2002

4. Influence of interfacial disorder and temperature on magnetization reversal in exchange-coupled bilayers

Author

Fitzsimmons, MR, Leighton, C, Hoffmann, A, Yashar, PC, Nogués, J, Liu, K, Majkrzak, CF, Dura, JA, Fritzsche, H, and Schuller, Ivan K

Subjects

Physical Sciences, Classical Physics, Brain Disorders, Chemical sciences, Engineering, Physical sciences

Abstract

Polarized neutron reflectometry is used to measure the thermal response of the net-magnetization vector of polycrystalline ferromagnetic (F) Fe films exchange coupled to twinned (110) MnF2 antiferromagnetic (AF) layers. We observe a strong correlation between the temperature dependencies of the net sample magnetization perpendicular to the applied field at coercivity and exchange bias. For cooling field and measurement conditions involving magnetization reversal via rotation, we find a range of temperature dependencies. For the smoothest F-AF interface, the temperature dependence of exchange bias compares well to a S=5/2 Brillouin function - an observation predicted by some theoretical models. This temperature dependence is expected for the sublattice magnetization and the square root of the anisotropy constant √K1 of bulk MnF2. In contrast, for a rough F-AF interface the magnetization reversal process (and exchange bias) showed little temperature dependence up to temperatures approaching the AF Néel point - a clear consequence of increasing interfacial disorder in a F-AF epitaxial system.

Published

2001

5. Helical magnetism in Sr-doped CaMn7O12 films

Author

Huon, A, Vibhakar, AM, Grutter, AJ, Borchers, JA, Disseler, S, Liu, Y, Tian, W, Orlandi, F, Manuel, P, Khalyavin, DD, Sharma, Y, Herklotz, A, Lee, HN, Fitzsimmons, MR, Johnson, RD, and May, SJ

Subjects

Condensed Matter::Materials Science

Abstract

Noncollinear magnetism can play an important role in multiferroic materials but is relatively understudied in oxide heterostructures compared to their bulk counterparts. Using variable temperature magnetometry and neutron diffraction, we demonstrate the presence of helical magnetic ordering in CaMn7O12 and Ca1−xSrxMn7O12 (for x up to 0.51) thin films. Consistent with bulk Ca1−xSrxMn7O12, the net magnetization increases with Sr doping. Neutron diffraction confirms that the helical magnetic structure remains incommensurate at all values of x, while the fundamental magnetic wavevector increases upon Sr substitution. This result demonstrates a chemical-based approach for tuning helical magnetism in quadruple perovskite films and enables future studies of strain and interfacial effects on helimagnetism in oxide heterostructures.

Published

2018

6. Structural Studies of Mixed Nano-Spheres and Polymers

Author

Washington, A, Li, X, Schofield, Andrew, Hong, K, Fitzsimmons, MR, and Pynn, Roger

Subjects

Condensed Matter::Soft Condensed Matter, Quantitative Biology::Biomolecules, COLLOID-POLYMER MIXTURES, Spin Echo Small Angle Neutron Scattering, Physics and Astronomy(all), equipment and supplies, Contributions to Practice

Abstract

A newly developed neutron scattering technique known as Spin Echo Small Angle Neutron Scattering (SESANS) allows real-space density correlations to be probed in bulk samples over distances ranging from ~20 nm to up to several microns. We have applied this technique to study correlations between polymer-stabilized poly(methyl methacrylate) (PMMA) spheres suspended in either dodecane or decalin. As expected, the data show that for colloid volume factions below about 40%, correlations between PMMA spheres are accurately described by the Percus-Yevick hard-sphere model. When a small amount of polymer is added to the colloidal suspension and when the carrier fluid is a good solvent for the polymer, short-range correlations between PMMA spheres are increased by the presence of the polymer depletant and are in reasonably agreement with calculations using an integral equation model. When higher concentrations of polymers are added, we find that long-range, power-law correlations develop between spheres, even though the sample flows freely. When the solvent is not a good solvent for the polymer depletant, correlations between PMMA spheres are unaffected by the addition of small quantities of polymer.

Published

2012

7. Influence of in-plane crystalline quality of an antiferromagnet on perpendicular exchange coupling and exchange bias

Author

FITZSIMMONS, MR, Leighton, C., and Nogues, J.

8. Investigating magnetic proximity effects in NiO/Pd with polarized neutron reflectometry

Author

Axel Hoffmann, FITZSIMMONS, MR, and Dura, Ja

9. Thickness-dependent coercive mechanisms in exchange-biased bilayers

Author

Leighton, C., FITZSIMMONS, MR, and Axel Hoffmann

10. Induced magnetic moments at a ferromagnet-antiferromagnet interface

Author

Axel Hoffmann, Seo, Jw, and FITZSIMMONS, MR

11. Strain Heterogeneity and Extended Defects in Halide Perovskite Devices.

Author

Orr KWP, Diao J, Dey K, Hameed M, Dubajić M, Gilbert HL, Selby TA, Zelewski SJ, Han Y, Fitzsimmons MR, Roose B, Li P, Fan J, Jiang H, Briscoe J, Robinson IK, and Stranks SD

Abstract

Strain is an important property in halide perovskite semiconductors used for optoelectronic applications because of its ability to influence device efficiency and stability. However, descriptions of strain in these materials are generally limited to bulk averages of bare films, which miss important property-determining heterogeneities that occur on the nanoscale and at interfaces in multilayer device stacks. Here, we present three-dimensional nanoscale strain mapping using Bragg coherent diffraction imaging of individual grains in Cs 0.1 FA 0.9 Pb(I 0.95 Br 0.05 ) 3 and Cs 0.15 FA 0.85 SnI 3 (FA = formamidinium) halide perovskite absorbers buried in full solar cell devices. We discover large local strains and striking intragrain and grain-to-grain strain heterogeneity, identifying distinct islands of tensile and compressive strain inside grains. Additionally, we directly image dislocations with surprising regularity in Cs 0.15 FA 0.85 SnI 3 grains and find evidence for dislocation-induced antiphase boundary formation. Our results shine a rare light on the nanoscale strains in these materials in their technologically relevant device setting., Competing Interests: The authors declare the following competing financial interest(s): Samuel D. Stranks is a co-founder of Swift Solar., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

12. Scintillator-based Timepix3 detector for neutron spin-echo techniques using intensity modulation.

Author

Funama F, Chong SA, Loyd M, Gofron KJ, Zhang Y, Kuhn SJ, Zhang C, Fitzsimmons MR, Khaplanov A, Vacaliuc B, Crow L, and Li F

Abstract

A scintillator-based Timepix3 (TPX3) detector was developed to resolve the high-frequency modulation of a neutron beam in both spatial and temporal domains, as required for neutron spin-echo experiments. In this system, light from a scintillator is manipulated with an optical lens and is intensified using an image intensifier, making it detectable with the TPX3 chip. Two different scintillators, namely, 6LiF:ZnS(Ag) and 6LiI:Eu, were investigated to achieve the high resolution needed for spin-echo modulated small-angle neutron scattering (SEMSANS) and modulation of intensity with zero effort (MIEZE). The methodology for conducting event-mode analysis is described, including the optimization of clustering parameters for both scintillators. The detector with both scintillators was characterized with respect to detection efficiency, spatial resolution, count rate, uniformity, and γ-sensitivity. The 6LiF:ZnS(Ag) scintillator-based detector achieved a spatial resolution of 200 μm and a count rate capability of 1.1 × 105 cps, while the 6LiI:Eu scintillator-based detector demonstrated a spatial resolution of 250 μm and a count rate capability exceeding 2.9 × 105 cps. Furthermore, high-frequency intensity modulations in both spatial and temporal domains were successfully observed, confirming the suitability of this detector for SEMSANS and MIEZE techniques, respectively., (© 2024 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2024

13. Electrochemical Impedance Spectroscopy of All-Perovskite Tandem Solar Cells.

Author

Roose B, Dey K, Fitzsimmons MR, Chiang YH, Cameron PJ, and Stranks SD

Abstract

This work explores electrochemical impedance spectroscopy to study recombination and ionic processes in all-perovskite tandem solar cells. We exploit selective excitation of each subcell to enhance or suppress the impedance signal from each subcell, allowing study of individual tandem subcells. We use this selective excitation methodology to show that the recombination resistance and ionic time constants of the wide gap subcell are increased with passivation. Furthermore, we investigate subcell-dependent degradation during maximum power point tracking and find an increase in recombination resistance and a decrease in capacitance for both subcells. Complementary optical and external quantum efficiency measurements indicate that the main driver for performance loss is the reduced capacity of the recombination layer to facilitate recombination due to the formation of a charge extraction barrier. This methodology highlights electrochemical impedance spectroscopy as a powerful tool to provide critical feedback to unlock the full potential of perovskite tandem solar cells., Competing Interests: The authors declare the following competing financial interest(s): S.D.S. is a co-founder of Swift Solar., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

14. Skyrmion-Excited Spin-Wave Fractal Networks.

Author

Tang N, Liyanage WLNC, Montoya SA, Patel S, Quigley LJ, Grutter AJ, Fitzsimmons MR, Sinha S, Borchers JA, Fullerton EE, DeBeer-Schmitt L, and Gilbert DA

Abstract

Magnetic skyrmions exhibit unique, technologically relevant pseudo-particle behaviors which arise from their topological protection, including well-defined, 3D dynamic modes that occur at microwave frequencies. During dynamic excitation, spin waves are ejected into the interstitial regions between skyrmions, creating the magnetic equivalent of a turbulent sea. However, since the spin waves in these systems have a well-defined length scale, and the skyrmions are on an ordered lattice, ordered structures from spin-wave interference can precipitate from the chaos. This work uses small-angle neutron scattering (SANS) to capture the dynamics in hybrid skyrmions and investigate the spin-wave structure. Performing simultaneous ferromagnetic resonance and SANS, the diffraction pattern shows a large increase in low-angle scattering intensity, which is present only in the resonance condition. This scattering pattern is best fit using a mass fractal model, which suggests the spin waves form a long-range fractal network. The fractal structure is constructed of fundamental units with a size that encodes the spin-wave emissions and are constrained by the skyrmion lattice. These results offer critical insights into the nanoscale dynamics of skyrmions, identify a new dynamic spin-wave fractal structure, and demonstrate SANS as a unique tool to probe high-speed dynamics., (© 2023 Wiley-VCH GmbH.)

Published

2023

15. Emergent Magnetic States and Tunable Exchange Bias at 3d Nitride Heterointerfaces.

Author

Jin Q, Zhang Q, Bai H, Huon A, Charlton T, Chen S, Lin S, Hong H, Cui T, Wang C, Guo H, Gu L, Zhu T, Fitzsimmons MR, Jin KJ, Wang S, and Guo EJ

Abstract

Interfacial magnetism stimulates the discovery of giant magnetoresistance (MR) and spin-orbital coupling across the heterointerfaces, facilitating the intimate correlation between spin transport and complex magnetic structures. Over decades, functional heterointerfaces composed of nitrides have seldom been explored due to the difficulty in synthesizing high-quality nitride films with correct compositions. Here, the fabrication of single-crystalline ferromagnetic Fe 3 N thin films with precisely controlled thicknesses is reported. As film thickness decreases, the magnetization dramatically deteriorates, and the electronic state changes from metallic to insulating. Strikingly, the high-temperature ferromagnetism is maintained in a Fe 3 N layer with a thickness down to 2 u.c. (≈8 Å). The MR exhibits a strong in-plane anisotropy; meanwhile, the anomalous Hall resistivity reverses its sign when the Fe 3 N layer thickness exceeds 5 u.c. Furthermore, a sizable exchange bias is observed at the interfaces between a ferromagnetic Fe 3 N and an antiferromagnetic CrN. The exchange bias field and saturation moment strongly depend on the controllable bending curvature using the cylinder diameter engineering technique, implying the tunable magnetic states under lattice deformation. This work provides a guideline for exploring functional nitride films and applying their interfacial phenomena for innovative perspectives toward practical applications., (© 2022 Wiley-VCH GmbH.)

Published

2023

16. Room-temperature valence transition in a strain-tuned perovskite oxide.

Author

Chaturvedi V, Ghosh S, Gautreau D, Postiglione WM, Dewey JE, Quarterman P, Balakrishnan PP, Kirby BJ, Zhou H, Cheng H, Huon A, Charlton T, Fitzsimmons MR, Korostynski C, Jacobson A, Figari L, Barriocanal JG, Birol T, Mkhoyan KA, and Leighton C

Abstract

Cobalt oxides have long been understood to display intriguing phenomena known as spin-state crossovers, where the cobalt ion spin changes vs. temperature, pressure, etc. A very different situation was recently uncovered in praseodymium-containing cobalt oxides, where a first-order coupled spin-state/structural/metal-insulator transition occurs, driven by a remarkable praseodymium valence transition. Such valence transitions, particularly when triggering spin-state and metal-insulator transitions, offer highly appealing functionality, but have thus far been confined to cryogenic temperatures in bulk materials (e.g., 90 K in Pr 1-x Ca x CoO 3 ). Here, we show that in thin films of the complex perovskite (Pr 1-y Y y ) 1-x Ca x CoO 3-δ , heteroepitaxial strain tuning enables stabilization of valence-driven spin-state/structural/metal-insulator transitions to at least 291 K, i.e., around room temperature. The technological implications of this result are accompanied by fundamental prospects, as complete strain control of the electronic ground state is demonstrated, from ferromagnetic metal under tension to nonmagnetic insulator under compression, thereby exposing a potential novel quantum critical point., (© 2022. The Author(s).)

Published

2022

17. Observing flow of He II with unsupervised machine learning.

Author

Wen X, McDonald L, Pierce J, Guo W, and Fitzsimmons MR

Abstract

Time dependent observations of point-to-point correlations of the velocity vector field (structure functions) are necessary to model and understand fluid flow around complex objects. Using thermal gradients, we observed fluid flow by recording fluorescence of [Formula: see text] excimers produced by neutron capture throughout a ~ cm 3 volume. Because the photon emitted by an excited excimer is unlikely to be recorded by the camera, the techniques of particle tracking (PTV) and particle imaging (PIV) velocimetry cannot be applied to extract information from the fluorescence of individual excimers. Therefore, we applied an unsupervised machine learning algorithm to identify light from ensembles of excimers (clusters) and then tracked the centroids of the clusters using a particle displacement determination algorithm developed for PTV., (© 2022. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2022

18. Induced Ferromagnetism in Epitaxial Uranium Dioxide Thin Films.

Author

Sharma Y, Paudel B, Huon A, Schneider MM, Roy P, Corey Z, Schönemann R, Jones AC, Jaime M, Yarotski DA, Charlton T, Fitzsimmons MR, Jia Q, Pettes MT, Yang P, and Chen A

Abstract

Actinide materials have various applications that range from nuclear energy to quantum computing. Most current efforts have focused on bulk actinide materials. Tuning functional properties by using strain engineering in epitaxial thin films is largely lacking. Using uranium dioxide (UO 2 ) as a model system, in this work, the authors explore strain engineering in actinide epitaxial thin films and investigate the origin of induced ferromagnetism in an antiferromagnet UO 2 . It is found that UO 2+ x thin films are hypostoichiometric (x<0) with in-plane tensile strain, while they are hyperstoichiometric (x>0) with in-plane compressive strain. Different from strain engineering in non-actinide oxide thin films, the epitaxial strain in UO 2 is accommodated by point defects such as vacancies and interstitials due to the low formation energy. Both epitaxial strain and strain relaxation induced point defects such as oxygen/uranium vacancies and oxygen/uranium interstitials can distort magnetic structure and result in magnetic moments. This work reveals the correlation among strain, point defects and ferromagnetism in strain engineered UO 2+ x thin films and the results offer new opportunities to understand the influence of coupled order parameters on the emergent properties of many other actinide thin films., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2022

19. Atomically engineered cobaltite layers for robust ferromagnetism.

Author

Chen S, Zhang Q, Li X, Zhao J, Lin S, Jin Q, Hong H, Huon A, Charlton T, Li Q, Yan W, Wang J, Ge C, Wang C, Wang B, Fitzsimmons MR, Guo H, Gu L, Yin W, Jin KJ, and Guo EJ

Abstract

Emergent phenomena at heterointerfaces are directly associated with the bonding geometry of adjacent layers. Effective control of accessible parameters, such as the bond length and bonding angles, offers an elegant method to tailor competing energies of the electronic and magnetic ground states. In this study, we construct unit-thick syntactic layers of cobaltites within a strongly tilted octahedral matrix via atomically precise synthesis. The octahedral tilt patterns of adjacent layers propagate into cobaltites, leading to a continuation of octahedral tilting while maintaining substantial misfit tensile strain. These effects induce severe rumpling within an atomic plane of neighboring layers, further triggering the electronic reconstruction between the splitting orbitals. First-principles calculations reveal that the cobalt ions transit to a higher spin state level upon octahedral tilting, resulting in robust ferromagnetism in ultrathin cobaltites. This work demonstrates a design methodology for fine-tuning the lattice and spin degrees of freedom in correlated quantum heterostructures by exploiting epitaxial geometric engineering.

Published

2022

20. Experimental Search for Neutron to Mirror Neutron Oscillations as an Explanation of the Neutron Lifetime Anomaly.

Author

Broussard LJ, Barrow JL, DeBeer-Schmitt L, Dennis T, Fitzsimmons MR, Frost MJ, Gilbert CE, Gonzalez FM, Heilbronn L, Iverson EB, Johnston A, Kamyshkov Y, Kline M, Lewiz P, Matteson C, Ternullo J, Varriano L, and Vavra S

Abstract

An unexplained >4σ discrepancy persists between "beam" and "bottle" measurements of the neutron lifetime. A new model proposed that conversions of neutrons n into mirror neutrons n^{'}, part of a dark mirror sector, can increase the apparent neutron lifetime by 1% via a small mass splitting Δm between n and n^{'} inside the 4.6 T magnetic field of the National Institute of Standards and Technology Beam Lifetime experiment. A search for neutron conversions in a 6.6 T magnetic field was performed at the Spallation Neutron Source which excludes this explanation for the neutron lifetime discrepancy.

Published

2022

21. Room-Temperature Ferromagnetism at an Oxide-Nitride Interface.

Author

Jin Q, Wang Z, Zhang Q, Yu Y, Lin S, Chen S, Qi M, Bai H, Huon A, Li Q, Wang L, Yin X, Tang CS, Wee ATS, Meng F, Zhao J, Wang JO, Guo H, Ge C, Wang C, Yan W, Zhu T, Gu L, Chambers SA, Das S, Charlton T, Fitzsimmons MR, Liu GQ, Wang S, Jin KJ, Yang H, and Guo EJ

Abstract

Heterointerfaces have led to the discovery of novel electronic and magnetic states because of their strongly entangled electronic degrees of freedom. Single-phase chromium compounds always exhibit antiferromagnetism following the prediction of the Goodenough-Kanamori rules. So far, exchange coupling between chromium ions via heteroanions has not been explored and the associated quantum states are unknown. Here, we report the successful epitaxial synthesis and characterization of chromium oxide (Cr&#95;{2}O&#95;{3})-chromium nitride (CrN) superlattices. Room-temperature ferromagnetic spin ordering is achieved at the interfaces between these two antiferromagnets, and the magnitude of the effect decays with increasing layer thickness. First-principles calculations indicate that robust ferromagnetic spin interaction between Cr^{3+} ions via anion-hybridization across the interface yields the lowest total energy. This work opens the door to fundamental understanding of the unexpected and exceptional properties of oxide-nitride interfaces and provides access to hidden phases at low-dimensional quantum heterostructures.

Published

2022

22. Ferroelectric Self-Polarization Controlled Magnetic Stratification and Magnetic Coupling in Ultrathin La 0.67 Sr 0.33 MnO 3 Films.

Author

Liu C, Liu Y, Zhang B, Sun CJ, Lan D, Chen P, Wu X, Yang P, Yu X, Charlton T, Fitzsimmons MR, Ding J, Chen J, and Chow GM

Abstract

Multiferroic oxide heterostructures consisting of ferromagnetic and ferroelectric components hold the promise for nonvolatile magnetic control via ferroelectric polarization, advantageous for the low-dissipation spintronics. Modern understanding of the magnetoelectric coupling in these systems involves structural, orbital, and magnetic reconstructions at interfaces. Previous works have long proposed polarization-dependent interfacial magnetic structures; however, direct evidence is still missing, which requires advanced characterization tools with near-atomic-scale spatial resolutions. Here, extensive polarized neutron reflectometry (PNR) studies have determined the magnetic depth profiles of PbZr 0.2 Ti 0.8 O 3 /La 0.67 Sr 0.33 MnO 3 (PZT/LSMO) bilayers with opposite self-polarizations. When the LSMO is 2-3 nm thick, the bilayers show two magnetic transitions on cooling. However, temperature-dependent magnetization is different below the lower-temperature transition for opposite polarizations. PNR finds that the LSMO splits into two magnetic sublayers, but the inter-sublayer magnetic couplings are of opposite signs for the two polarizations. Near-edge X-ray absorption spectroscopy further shows contrasts in both the Mn valences and the Mn-O bond anisotropy between the two polarizations. This work completes the puzzle for the magnetoelectric coupling model at the PZT/LSMO interface, showing a synergic interplay among multiple degrees of freedom toward emergent functionalities at complex oxide interfaces.

Published

2021

23. Dimensional Control of Octahedral Tilt in SrRuO 3 via Infinite-Layered Oxides.

Author

Lin S, Zhang Q, Sang X, Zhao J, Cheng S, Huon A, Jin Q, Chen S, Chen S, Cui W, Guo H, He M, Ge C, Wang C, Wang J, Fitzsimmons MR, Gu L, Zhu T, Jin K, and Guo EJ

Abstract

Manipulation of octahedral distortion at atomic scale is an effective means to tune the ground states of functional oxides. Previous work demonstrates that strain and film thickness are variable parameters to modify the octahedral parameters. However, selective control of bonding geometry by structural propagation from adjacent layers is rarely studied. Here we propose a new route to tune the ferromagnetism in SrRuO 3 (SRO) ultrathin layers by oxygen coordination of adjacent SrCuO 2 (SCO) layers. The infinite-layered CuO 2 exhibits a structural transformation from "planar-type" to "chain-type" with reduced film thickness. Two orientations dramatically modify the polyhedral connectivity at the interface, thus altering the octahedral distortion of SRO. The local structural variation changes the spin state of Ru and orbital hybridization strength, leading to a significant change in the magnetoresistance and anomalous Hall resistivity. These findings could launch investigations into adaptive control of functionalities in quantum oxide heterostructures using oxygen coordination.

Published

2021

24. Imaging Fluorescence of He&#95;{2}^{*} Excimers Created by Neutron Capture in Liquid Helium II.

Author

Wen X, Bao SR, McDonald L, Pierce J, Greene GL, Crow L, Tong X, Mezzacappa A, Glasby R, Guo W, and Fitzsimmons MR

Abstract

We show unequivocal evidence for formation of He&#95;{2}^{*} excimers in liquid He II created by ionizing radiation produced through neutron capture. Laser beams induce fluorescence of the excimers. The fluorescence is recorded at a rate of 55.6 Hz by a camera. The location of the fluorescence is determined with an uncertainty of 5  μm. The technique provides an opportunity to record the flow of He&#95;{2}^{*} excimers in a medium with very small viscosity and enables measurement of turbulence around macroscopic liter size objects or vortex matter in three dimensions.

Published

2020

25. Colossal oxygen vacancy formation at a fluorite-bixbyite interface.

Author

Lee D, Gao X, Sun L, Jee Y, Poplawsky J, Farmer TO, Fan L, Guo EJ, Lu Q, Heller WT, Choi Y, Haskel D, Fitzsimmons MR, Chisholm MF, Huang K, Yildiz B, and Lee HN

Abstract

Oxygen vacancies in complex oxides are indispensable for information and energy technologies. There are several means to create oxygen vacancies in bulk materials. However, the use of ionic interfaces to create oxygen vacancies has not been fully explored. Herein, we report an oxide nanobrush architecture designed to create high-density interfacial oxygen vacancies. An atomically well-defined (111) heterointerface between the fluorite CeO 2 and the bixbyite Y 2 O 3 is found to induce a charge modulation between Y 3+ and Ce 4+ ions enabled by the chemical valence mismatch between the two elements. Local structure and chemical analyses, along with theoretical calculations, suggest that more than 10% of oxygen atoms are spontaneously removed without deteriorating the lattice structure. Our fluorite-bixbyite nanobrush provides an excellent platform for the rational design of interfacial oxide architectures to precisely create, control, and transport oxygen vacancies critical for developing ionotronic and memristive devices for advanced energy and neuromorphic computing technologies.

Published

2020

26. Vertically Aligned Single-Crystalline CoFe 2 O 4 Nanobrush Architectures with High Magnetization and Tailored Magnetic Anisotropy.

Author

Fan L, Gao X, Farmer TO, Lee D, Guo EJ, Mu S, Wang K, Fitzsimmons MR, Chisholm MF, Ward TZ, Eres G, and Lee HN

Abstract

Micrometer-tall vertically aligned single-crystalline CoFe 2 O 4 nanobrush architectures with extraordinarily large aspect ratio have been achieved by the precise control of a kinetic and thermodynamic non-equilibrium pulsed laser epitaxy process. Direct observations by scanning transmission electron microscopy reveal that the nanobrush crystal is mostly defect-free by nature, and epitaxially connected to the substrate through a continuous 2D interface layer. In contrast, periodic dislocations and lattice defects such as anti-phase boundaries and twin boundaries are frequently observed in the 2D interface layer, suggesting that interface misfit strain relaxation under a non-equilibrium growth condition plays a critical role in the self-assembly of such artificial architectures. Magnetic property measurements have found that the nanobrushes exhibit a saturation magnetization value of 6.16 B/f.u., which is much higher than the bulk value. The discovery not only enables insights into an effective route for fabricating unconventional high-quality nanostructures, but also demonstrates a novel magnetic architecture with potential applications in nanomagnetic devices., Competing Interests: The authors declare no conflicts of interest.

Published

2020

27. Nanoscale magnetization inhomogeneity within single phase nanopillars.

Author

Farmer TO, Guo EJ, Desautels RD, DeBeer-Schmitt L, Chen A, Wang Z, Jia Q, Borchers JA, Gilbert DA, Holladay B, Sinha SK, and Fitzsimmons MR

Abstract

We report observation of a radial dependence in the magnetic anisotropy of epitaxially strained CoFe 2 O 4 nanopillars in a BaTiO 3 matrix. This archetypal example of a multiferroic heterostructure with a self-assembling three-dimensional architecture possesses significant out-of-plane uniaxial magnetic anisotropy. The anisotropy originates from the large magnetostriction of CoFe 2 O 4 and the state of stress within the nanocomposite. Magnetometry suggests the existence of two magnetic phases with different anisotropies. Micromagnetic simulations of a core-shell magnetic anisotropy qualitatively reproduce features of the magnetic hysteresis and elucidate the magnetization reversal mechanism: The magnetization initially reorients within the pillar core, followed by that of the shell. This is consistent with polarized small-angle neutron scattering which can be described by a CoFe 2 O 4 magnetization that is nonuniform on nanometer length scales. As the length scale of inhomogeneity of the magnetic anisotropy is similar to estimates of the relaxation of the displacement field from the CoFe 2 O 4 -BaTiO 3 interface, stress and its influence on structure provide an important route to new functionality of vertically aligned nanopillars for applications in low-power memory, computing, and sensing.

Published

2019

28. Exploiting Symmetry Mismatch to Control Magnetism in a Ferroelastic Heterostructure.

Author

Guo EJ, Desautels R, Lee D, Roldan MA, Liao Z, Charlton T, Ambaye H, Molaison J, Boehler R, Keavney D, Herklotz A, Ward TZ, Lee HN, and Fitzsimmons MR

Abstract

In the bulk, LaCoO&#95;{3} (LCO) is a paramagnet, yet the low-temperature ferromagnetism (FM) is observed in tensile strained thin films, and its origin remains unresolved. Here, we quantitatively measured the distribution of atomic density and magnetization in LCO films by polarized neutron reflectometry (PNR) and found that the LCO layers near the heterointerfaces exhibit a reduced magnetization but an enhanced atomic density, whereas the film's interior (i.e., its film bulk) shows the opposite trend. We attribute the nonuniformity to the symmetry mismatch at the interface, which induces a structural distortion related to the ferroelasticity of LCO. This assertion is tested by systematic application of hydrostatic pressure during the PNR experiments. The magnetization can be controlled at a rate of -20.4% per GPa. These results provide unique insights into mechanisms driving FM in strained LCO films while offering a tantalizing observation that tunable deformation of the CoO&#95;{6} octahedra in combination with the ferroelastic order parameter.

Published

2019

29. Nanoscale ferroelastic twins formed in strained LaCoO 3 films.

Author

Guo EJ, Desautels R, Keavney D, Roldan MA, Kirby BJ, Lee D, Liao Z, Charlton T, Herklotz A, Zac Ward T, Fitzsimmons MR, and Lee HN

Abstract

The coexistence and coupling of ferroelasticity and magnetic ordering in a single material offers a great opportunity to realize novel devices with multiple tuning knobs. Complex oxides are a particularly promising class of materials to find multiferroic interactions due to their rich phase diagrams, and are sensitive to external perturbations. Still, there are very few examples of these systems. Here, we report the observation of twin domains in ferroelastic LaCoO 3 epitaxial films and their geometric control of structural symmetry intimately linked to the material's electronic and magnetic states. A unidirectional structural modulation is achieved by selective choice of substrates having twofold rotational symmetry. This modulation perturbs the crystal field-splitting energy, leading to unexpected in-plane anisotropy of orbital configuration and magnetization. These findings demonstrate the use of structural modulation to control multiferroic interactions and may enable a great potential for stimulation of exotic phenomena through artificial domain engineering.

Published

2019

30. Large orbital polarization in nickelate-cuprate heterostructures by dimensional control of oxygen coordination.

Author

Liao Z, Skoropata E, Freeland JW, Guo EJ, Desautels R, Gao X, Sohn C, Rastogi A, Ward TZ, Zou T, Charlton T, Fitzsimmons MR, and Lee HN

Abstract

Artificial heterostructures composed of dissimilar transition metal oxides provide unprecedented opportunities to create remarkable physical phenomena. Here, we report a means to deliberately control the orbital polarization in LaNiO 3 (LNO) through interfacing with SrCuO 2 (SCO), which has an infinite-layer structure for CuO 2 . Dimensional control of SCO results in a planar-type (P-SCO) to chain-type (C-SCO) structure transition depending on the SCO thickness. This transition is exploited to induce either a NiO 5 pyramidal or a NiO 6 octahedral structure at the SCO/LNO interface. Consequently, a large change in the Ni d orbital occupation up to ~30% is achieved in P-SCO/LNO superlattices, whereas the Ni e g orbital splitting is negligible in C-SCO/LNO superlattices. The engineered oxygen coordination triggers a metal-to-insulator transition in SCO/LNO superlattices. Our results demonstrate that interfacial oxygen coordination engineering provides an effective means to manipulate the orbital configuration and associated physical properties, paving a pathway towards the advancement of oxide electronics.

Published

2019

31. Oxygen Diode Formed in Nickelate Heterostructures by Chemical Potential Mismatch.

Author

Guo EJ, Liu Y, Sohn C, Desautels RD, Herklotz A, Liao Z, Nichols J, Freeland JW, Fitzsimmons MR, and Lee HN

Abstract

Deliberate control of oxygen vacancy formation and migration in perovskite oxide thin films is important for developing novel electronic and iontronic devices. Here, it is found that the concentration of oxygen vacancies (V O ) formed in LaNiO 3 (LNO) during pulsed laser deposition is strongly affected by the chemical potential mismatch between the LNO film and its proximal layers. Increasing the V O concentration in LNO significantly modifies the degree of orbital polarization and drives the metal-insulator transition. Changes in the nickel oxidization state and carrier concentration in the films are confirmed by soft X-ray absorption spectroscopy and optical spectroscopy. The ability to unidirectional-control the oxygen flow across the heterointerface, e.g., a so-called "oxygen diode", by exploiting chemical potential mismatch at interfaces provides a new avenue to tune the physical and electrochemical properties of complex oxides., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

32. Correction to Orientation Control of Interfacial Magnetism at La 0.67 Sr 0.33 MnO 3 /SrTiO 3 Interfaces.

Author

Guo EJ, Charlton T, Ambaye H, Desautels RD, Lee HN, and Fitzsimmons MR

Published

2017

33. Spatially Resolved Large Magnetization in Ultrathin BiFeO 3 .

Author

Guo EJ, Petrie JR, Roldan MA, Li Q, Desautels RD, Charlton T, Herklotz A, Nichols J, van Lierop J, Freeland JW, Kalinin SV, Lee HN, and Fitzsimmons MR

Abstract

Here, a quantitative magnetic depth profile across the planar interfaces in BiFeO 3 /La 0.7 Sr 0.3 MnO 3 (BFO/LSMO) superlattices using polarized neutron reflectometry is obtained. An enhanced magnetization of 1.83 ± 0.16 μ B /Fe in BFO layers is observed when they are interleaved between two manganite layers. The enhanced magnetic order in BFO persists up to 200 K. The depth dependence of magnetic moments in BFO/LSMO superlattices as a function of the BFO layer thickness is also explored. The results show the enhanced net magnetic moment in BFO from the LSMO/BFO interface extends 3-4 unit cells into BFO. The interior part of a thicker BFO layer has a much smaller magnetization, suggesting it still keeps the small canted AFM state. The results exclude charge transfer, intermixing, epitaxial strain, and octahedral rotations/tilts as dominating mechanisms for the large net magnetization in BFO. An explanation-one suggested by others previously and consistent with the observations-attributes the temperature dependence of the net magnetization of BFO to strong orbital hybridization between Fe and Mn across the interfaces. Such orbital reconstruction would establish an upper temperature limit for magnetic ordering of BFO., (© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

34. Hidden Interface Driven Exchange Coupling in Oxide Heterostructures.

Author

Chen A, Wang Q, Fitzsimmons MR, Enriquez E, Weigand M, Harrell Z, McFarland B, Lü X, Dowden P, MacManus-Driscoll JL, Yarotski D, and Jia Q

Abstract

A variety of emergent phenomena have been enabled by interface engineering in complex oxides. The existence of an intrinsic interfacial layer has often been found at oxide heterointerfaces. However, the role of such an interlayerin controlling functionalities is not fully explored. Here, we report the control of the exchange bias (EB) in single-phase manganite thin films with nominallyuniform chemical composition across the interfaces. The sign of EB depends on the magnitude of the cooling field. A pinned layer, confirmed by polarized neutron reflectometry, provides the source of unidirectional anisotropy. The origin of the exchange bias coupling is discussed in terms of magnetic interactions between the interfacial ferromagnetically reduced layer and the bulk ferromagnetic region. The sign of EB is related to the frustration of antiferromagnetic coupling between the ferromagnetic region and the pinned layer. Our results shed new light on using oxide interfaces to design functional spintronic devices., (© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

35. Orientation Control of Interfacial Magnetism at La 0.67 Sr 0.33 MnO 3 /SrTiO 3 Interfaces.

Author

Guo EJ, Charlton T, Ambaye H, Desautels RD, Lee HN, and Fitzsimmons MR

Abstract

Understanding the magnetism at the interface between a ferromagnet and an insulator is essential because the commonly posited magnetic "dead" layer close to an interface can be problematic in magnetic tunnel junctions. Previously, degradation of the magnetic interface was attributed to charge discontinuity across the interface. Here, the interfacial magnetism was investigated using three identically prepared La 0.67 Sr 0.33 MnO 3 (LSMO) thin films grown on different oriented SrTiO 3 (STO) substrates by polarized neutron reflectometry. In all cases the magnetization at the LSMO/STO interface is larger than the film bulk. We show that the interfacial magnetization is largest across the LSMO/STO interfaces with (001) and (111) orientations, which have the largest net charge discontinuities across the interfaces. In contrast, the magnetization of LSMO/STO across the (110) interface, the orientation with no net charge discontinuity, is the smallest of the three orientations. We show that a magnetically degraded interface is not intrinsic to LSMO/STO heterostructures. The approach to use different crystallographic orientations provides a means to investigate the influence of charge discontinuity on the interfacial magnetization.

Published

2017

36. Reversible Control of Interfacial Magnetism through Ionic-Liquid-Assisted Polarization Switching.

Author

Herklotz A, Guo EJ, Wong AT, Meyer TL, Dai S, Ward TZ, Lee HN, and Fitzsimmons MR

Abstract

The ability to control magnetism of materials via electric field enables a myriad of technological innovations in information storage, sensing, and computing. We use ionic-liquid-assisted ferroelectric switching to demonstrate reversible modulation of interfacial magnetism in a multiferroic heterostructure composed of ferromagnetic (FM) La 0.8 Sr 0.2 MnO 3 and ferroelectric (FE) PbZr 0.2 Ti 0.8 O 3 . It is shown that ionic liquids can be used to persistently and reversibly switch a large area of a FE film. This is a prerequisite for polarized neutron reflectometry (PNR) studies that are conducted to directly probe magnetoelectric coupling of the FE polarization to the interfacial magnetization.

Published

2017

37. Emerging magnetism and anomalous Hall effect in iridate-manganite heterostructures.

Author

Nichols J, Gao X, Lee S, Meyer TL, Freeland JW, Lauter V, Yi D, Liu J, Haskel D, Petrie JR, Guo EJ, Herklotz A, Lee D, Ward TZ, Eres G, Fitzsimmons MR, and Lee HN

Abstract

Strong Coulomb repulsion and spin-orbit coupling are known to give rise to exotic physical phenomena in transition metal oxides. Initial attempts to investigate systems, where both of these fundamental interactions are comparably strong, such as 3d and 5d complex oxide superlattices, have revealed properties that only slightly differ from the bulk ones of the constituent materials. Here we observe that the interfacial coupling between the 3d antiferromagnetic insulator SrMnO3 and the 5d paramagnetic metal SrIrO3 is enormously strong, yielding an anomalous Hall response as the result of charge transfer driven interfacial ferromagnetism. These findings show that low dimensional spin-orbit entangled 3d-5d interfaces provide an avenue to uncover technologically relevant physical phenomena unattainable in bulk materials.

Published

2016

38. Composition dependence of charge and magnetic length scales in mixed valence manganite thin films.

Author

Singh S, Freeland JW, Fitzsimmons MR, Jeen H, and Biswas A

Abstract

Mixed-valence manganese oxides present striking properties like the colossal magnetoresistance, metal-insulator transition (MIT) that may result from coexistence of ferromagnetic, metallic and insulating phases. Percolation of such phase coexistence in the vicinity of MIT leads to first-order transition in these manganites. However the length scales over which the electronic and magnetic phases are separated across MIT which appears compelling for bulk systems has been elusive in (La1-yPry)1-xCaxMnO3 films. Here we show the in-plane length scale over which charge and magnetism are correlated in (La0.4Pr0.6)1-xCaxMnO3 films with x = 0.33 and 0.375, across the MIT temperature. We combine electrical transport (resistance) measurements, x-ray absorption spectroscopy (XAS), x-ray magnetic circular dichroism (XMCD), and specular/off-specular x-ray resonant magnetic scattering (XRMS) measurements as a function of temperature to elucidate relationships between electronic, magnetic and morphological structure of the thin films. Using off-specular XRMS we obtained the charge-charge and charge-magnetic correlation length of these LPCMO films across the MIT. We observed different charge-magnetic correlation length for two films which increases below the MIT. The different correlation length shown by two films may be responsible for different macroscopic (transport and magnetic) properties.

Published

2016

39. Synthetic magnetoelectric coupling in a nanocomposite multiferroic.

Author

Jain P, Wang Q, Roldan M, Glavic A, Lauter V, Urban C, Bi Z, Ahmed T, Zhu J, Varela M, Jia QX, and Fitzsimmons MR

Abstract

Given the paucity of single phase multiferroic materials (with large ferromagnetic moment), composite systems seem an attractive solution to realize magnetoelectric coupling between ferromagnetic and ferroelectric order parameters. Despite having antiferromagnetic order, BiFeO3 (BFO) has nevertheless been a key material due to excellent ferroelectric properties at room temperature. We studied a superlattice composed of 8 repetitions of 6 unit cells of La0.7Sr0.3MnO3 (LSMO) grown on 5 unit cells of BFO. Significant net uncompensated magnetization in BFO, an insulating superlattice, is demonstrated using polarized neutron reflectometry. Remarkably, the magnetization enables magnetic field to change the dielectric properties of the superlattice, which we cite as an example of synthetic magnetoelectric coupling. Importantly, controlled creation of magnetic moment in BFO is a much needed path toward design and implementation of integrated oxide devices for next generation magnetoelectric data storage platforms.

Published

2015

40. Phase diagram of a three-dimensional antiferromagnet with random magnetic anisotropy.

Author

Perez FA, Borisov P, Johnson TA, Stanescu TD, Trappen R, Holcomb MB, Lederman D, Fitzsimmons MR, Aczel AA, and Hong T

Abstract

Three-dimensional antiferromagnets with random magnetic anisotropy (RMA) that have been experimentally studied to date have competing two-dimensional and three-dimensional exchange interactions which can obscure the authentic effects of RMA. The magnetic phase diagram of Fe&#95;{x}Ni&#95;{1-x}F&#95;{2} epitaxial thin films with true random single-ion anisotropy was deduced from magnetometry and neutron scattering measurements and analyzed using mean-field theory. Regions with uniaxial, oblique, and easy-plane anisotropies were identified. A RMA-induced glass region was discovered where a Griffiths-like breakdown of long-range spin order occurs.

Published

2015

41. Spatial control of functional properties via octahedral modulations in complex oxide superlattices.

Author

Moon EJ, Colby R, Wang Q, Karapetrova E, Schlepütz CM, Fitzsimmons MR, and May SJ

Abstract

Control of atomic structure, namely the topology of the corner-connected metal-oxygen octahedra, has emerged as an important route to tune the functional properties at oxide interfaces. Here we investigate isovalent manganite superlattices (SLs), [(La(0.7)Sr(0.3)MnO(3))n/(Eu(0.7)Sr(0.3)MnO(3))n] × m, as a route to spatial control over electronic bandwidth and ferromagnetism through the creation of octahedral superstructures. Electron energy loss spectroscopy confirms a uniform Mn valence state throughout the SLs. In contrast, the presence of modulations of the MnO(6) octahedral rotations along the growth direction commensurate with the SL period is revealed by scanning transmission electron microscopy and X-ray diffraction. We show that the Curie temperatures of the constituent materials can be systematically engineered via the octahedral superstructures leading to a modulated magnetization in samples where the SL period is larger than the interfacial octahedral coupling length scale, whereas a single magnetic transition is observed in the short-period SLs.

Published

2014

42. Induced magnetization in La0.7Sr0.3MnO3/BiFeO3 superlattices.

Author

Singh S, Haraldsen JT, Xiong J, Choi EM, Lu P, Yi D, Wen XD, Liu J, Wang H, Bi Z, Yu P, Fitzsimmons MR, MacManus-Driscoll JL, Ramesh R, Balatsky AV, Zhu JX, and Jia QX

Abstract

Using polarized neutron reflectometry, we observe an induced magnetization of 75 ± 25 kA/m at 10 K in a La(0.7)Sr(0.3)MnO(3) (LSMO)/BiFeO(3) superlattice extending from the interface through several atomic layers of the BiFeO(3) (BFO). The induced magnetization in BFO is explained by density functional theory, where the size of band gap of BFO plays an important role. Considering a classical exchange field between the LSMO and BFO layers, we further show that magnetization is expected to extend throughout the BFO, which provides a theoretical explanation for the results of the neutron scattering experiment.

Published

2014

43. Reversible electric-field control of magnetization at oxide interfaces.

Author

Cuellar FA, Liu YH, Salafranca J, Nemes N, Iborra E, Sanchez-Santolino G, Varela M, Garcia Hernandez M, Freeland JW, Zhernenkov M, Fitzsimmons MR, Okamoto S, Pennycook SJ, Bibes M, Barthélémy A, te Velthuis SG, Sefrioui Z, Leon C, and Santamaria J

Abstract

Electric-field control of magnetism has remained a major challenge which would greatly impact data storage technology. Although progress in this direction has been recently achieved, reversible magnetization switching by an electric field requires the assistance of a bias magnetic field. Here we take advantage of the novel electronic phenomena emerging at interfaces between correlated oxides and demonstrate reversible, voltage-driven magnetization switching without magnetic field. Sandwiching a non-superconducting cuprate between two manganese oxide layers, we find a novel form of magnetoelectric coupling arising from the orbital reconstruction at the interface between interfacial Mn spins and localized states in the CuO2 planes. This results in a ferromagnetic coupling between the manganite layers that can be controlled by a voltage. Consequently, magnetic tunnel junctions can be electrically toggled between two magnetization states, and the corresponding spin-dependent resistance states, in the absence of a magnetic field.

Published

2014

44. Inter-particle correlations in a hard-sphere colloidal suspension with polymer additives investigated by Spin Echo Small Angle Neutron Scattering (SESANS).

Author

Washington AL, Li X, Schofield AB, Hong K, Fitzsimmons MR, Dalgliesh R, and Pynn R

Abstract

Using a neutron scattering technique that measures a statistically-averaged density correlation function in real space rather than the conventional reciprocal-space structure factor, we have measured correlations between poly(methyl-methacrylate) (PMMA) colloidal particles of several sizes suspended in decalin. The new method, called Spin Echo Small Angle Neutron Scattering (SESANS) provides accurate information about particle composition, including the degree of solvent penetration into the polymer brush grafted on to the PMMA spheres to prevent aggregation. It confirms for particles, between 85 nm and 150 nm in radius that inter-particle correlations closely follow the Percus-Yevick hard-sphere model when the colloidal volume-fraction is between 30% and 50% provided the volume-fraction is used as a fitted parameter. No particle aggregation occurs in these systems. When small amounts of polystyrene are added as a depletant to a concentrated suspension of PMMA particles, short-range clustering of the particles occurs and there is an increase in the frequency of near-neighbor contacts. Within a small range of depletant concentration, near-neighbor correlations saturate and large aggregates with power law density correlations are formed. SESANS clearly separates the short- and long-range correlations and shows that, in this case, the power-law correlations are visible for inter-particle distances larger than roughly two particle diameters. In some cases, aggregate sizes are within our measurement window, which can extend out to 16 microns in favorable cases. We discuss the advantages of SESANS for measurements of the structure of concentrated colloidal systems and conclude that the method offers several important advantages.

Published

2014

45. Emergent spin filter at the interface between ferromagnetic and insulating layered oxides.

Author

Liu Y, Cuellar FA, Sefrioui Z, Freeland JW, Fitzsimmons MR, Leon C, Santamaria J, and te Velthuis SG

Abstract

We report a strong effect of interface-induced magnetization on the transport properties of magnetic tunnel junctions consisting of ferromagnetic manganite La0.7Ca0.3MnO3 and insulating cuprate PrBa2Cu3O7. Contrary to the typically observed steady increase of the tunnel magnetoresistance with decreasing temperature, this system exhibits a sudden anomalous decrease at low temperatures. Interestingly, this anomalous behavior can be attributed to the competition between the positive spin polarization of the manganite contacts and the negative spin-filter effect from the interface-induced Cu magnetization.

Published

2013

46. Interfacial ferromagnetism in LaNiO3/CaMnO3 superlattices.

Author

Grutter AJ, Yang H, Kirby BJ, Fitzsimmons MR, Aguiar JA, Browning ND, Jenkins CA, Arenholz E, Mehta VV, Alaan US, and Suzuki Y

Abstract

We observe interfacial ferromagnetism in superlattices of the paramagnetic metal LaNiO3 and the antiferromagnetic insulator CaMnO3. LaNiO3 exhibits a thickness dependent metal-insulator transition and we find the emergence of ferromagnetism to be coincident with the conducting state of LaNiO3. That is, only superlattices in which the LaNiO3 layers are metallic exhibit ferromagnetism. Using several magnetic probes, we have determined that the ferromagnetism arises in a single unit cell of CaMnO3 at the interface. Together these results suggest that ferromagnetism can be attributed to a double exchange interaction among Mn ions mediated by the adjacent itinerant metal.

Published

2013

47. Interfacial ferromagnetism and exchange bias in CaRuO3/CaMnO3 superlattices.

Author

He C, Grutter AJ, Gu M, Browning ND, Takamura Y, Kirby BJ, Borchers JA, Kim JW, Fitzsimmons MR, Zhai X, Mehta VV, Wong FJ, and Suzuki Y

Abstract

We have found ferromagnetism in epitaxially grown superlattices of CaRuO(3)/CaMnO(3) that arises in one unit cell at the interface. Scanning transmission electron microscopy and electron energy loss spectroscopy indicate that the difference in magnitude of the Mn valence states between the center of the CaMnO(3) layer and the interface region is consistent with double exchange interaction among the Mn ions at the interface. Polarized neutron reflectivity and the CaMnO(3) thickness dependence of the exchange bias field together indicate that the interfacial ferromagnetism is only limited to one unit cell of CaMnO(3) at each interface. The interfacial moment alternates between the 1 μ(B)/interface Mn ion for even CaMnO(3) layers and the 0.5 μ(B)/interface Mn ion for odd CaMnO(3) layers. This modulation, combined with the exchange bias, suggests the presence of a modulating interlayer coupling between neighboring ferromagnetic interfaces via the antiferromagnetic CaMnO(3) layers.

Published

2012

48. Effect of interface-induced exchange fields on cuprate-manganite spin switches.

Author

Liu Y, Visani C, Nemes NM, Fitzsimmons MR, Zhu LY, Tornos J, Garcia-Hernandez M, Zhernenkov M, Hoffmann A, Leon C, Santamaria J, and te Velthuis SG

Abstract

We examine the anomalous inverse spin switch behavior in La0.7Ca0.3MnO3(LCMO)/YBa2Cu3O7-δ (YBCO)/LCMO trilayers by combined transport studies and polarized neutron reflectometry. Measuring magnetization profiles and magnetoresistance in an in-plane rotating magnetic field, we prove that, contrary to many accepted theoretical scenarios, the relative orientation between the two LCMO's magnetizations is not sufficient to determine the magnetoresistance. Rather the field dependence of magnetoresistance is explained by the interplay between the applied magnetic field and the (exponential tail of the) induced exchange field in YBCO, the latter originating from the electronic reconstruction at the LCMO/YBCO interfaces.

Published

2012

49. Magnetic nonuniformity and thermal hysteresis of magnetism in a manganite thin film.

Author

Singh S, Fitzsimmons MR, Lookman T, Thompson JD, Jeen H, Biswas A, Roldan MA, and Varela M

Abstract

We measured the chemical and magnetic depth profiles of a single crystalline (La(1-x)Pr(x))(1-y)Ca(y)MnO(3-δ) (x=0.52±0.05, y=0.23±0.04, δ=0.14±0.10) film grown on a NdGaO(3) substrate using x-ray reflectometry, electron microscopy, electron energy-loss spectroscopy, and polarized neutron reflectometry. Our data indicate that the film exhibits coexistence of different magnetic phases as a function of depth. The magnetic depth profile is correlated with a variation of chemical composition with depth. The thermal hysteresis of ferromagnetic order in the film suggests a first-order ferromagnetic transition at low temperatures.

Published

2012

50. Upper limit to magnetism in LaAlO3/SrTiO3 heterostructures.

Author

Fitzsimmons MR, Hengartner NW, Singh S, Zhernenkov M, Bruno FY, Santamaria J, Brinkman A, Huijben M, Molegraaf HJ, de la Venta J, and Schuller IK

Abstract

Using polarized neutron reflectometry we measured the neutron spin-dependent reflectivity from four LaAlO(3)/SrTiO(3) superlattices. Our results imply that the upper limit for the magnetization averaged over the lateral dimensions of the sample induced by an 11 T magnetic field at 1.7 K is less than 2 G. SQUID magnetometry of the neutron superlattice samples sporadically finds an enhanced moment, possibly due to experimental artifacts. These observations set important restrictions on theories which imply a strongly enhanced magnetism at the interface between LaAlO(3) and SrTiO(3).

Published

2011