Your search keyword '"Ciston, J."' showing total 315 results

1. The atomic-level structure and stability of interfaces of Pt nanoparticles in alumina: An experimental and computational evaluation

Author

Clauser, AL, Sarfo, K Oware, Ophus, C, Ciston, J, Giulian, R, Árnadóttir, L, and Santala, MK

Subjects

Engineering, Physical Sciences, Condensed Matter Physics, Materials Engineering, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

The atomic-level structure of interfaces between Pt and a transition form of Al2O3 were studied using a combination of electron microscopy and first principles calculations. A model system of Pt nanoprecipitates in Al2O3 were formed in sapphire wafers via high-energy ion implantation of Pt followed by thermal annealing at 1000 °C in air. The Pt nanoparticles took the form of tetrahedra and truncated tetrahedra primarily bound by {111}Pt facets. The high prevalence of these facets motivated the development of density functional theory (DFT) based models of (111)Pt interfaces with six different chemical terminations of (2¯01) θ-alumina. The atomic-level structure of the Pt/Al2O3 interfaces was characterized with aberration-corrected scanning transmission electron microscopy (STEM) and the experimental images were compared to STEM image simulations of the DFT models. The model interface with Pt bonded to oxygen-terminated θ-Al2O3, with the Pt located on top of the O and with an underlying layer of octahedral Al, provided the best match to the experimental images. This interfacial termination is also the most stable for the thermal annealing conditions used based on thermodynamic calculations of the interfacial energy as a function of temperature and oxygen partial pressure. This experimentally verified model provides a basis for improving models of Pt/γ-alumina interfaces.

Published

2024

2. Characterization of the atomic-level structure of γ-alumina and (111) Pt/γ-alumina interfaces

Author

Clauser, AL, Sarfo, K Oware, Giulian, R, Ophus, C, Ciston, J, Árnadóttir, L, and Santala, MK

Subjects

Physical Sciences, Engineering, Nanotechnology, Bioengineering, Alumina, Platinum, Interface structure, Atomic structure, STEM, Condensed Matter Physics, Materials Engineering, Mechanical Engineering, Materials, Materials engineering, Mechanical engineering, Condensed matter physics

Abstract

The atomic-level structure of platinum/γ-alumina interfaces is characterized in a model system of dense γ-alumina embedded with faceted Pt NPs produced by implantation of platinum ions into sapphire followed by thermal annealing in air at 800 °C. Aberration-corrected scanning transmission electron microscopy (STEM) was used to collect atomic-resolution images, which are compared to STEM image simulations of two experimentally-based bulk models of γ-alumina by Smrčok et al. and Zhou and Snyder. A density functional theory (DFT) based model of (111) interfaces with different chemical terminations (O, Al1, Al2) of the γ-alumina developed by Oware Sarfo et al. is also compared to experimental STEM data from Pt/γ-alumina interfaces. The Smrčok γ-alumina model provides a better fit than the Zhou structure to the bulk of the γ-alumina. The oxygen-terminated Oware Sarfo model best fits the experimental data and is a very good model close to the interface. However, the fit of the interface model to the experimental data is poorer beyond the third atomic layer in the γ-alumina. This is attributed to compromises required in the design of the model to limit the cell size and computational time for DFT calculations. Understanding the accuracy and limits of the structural models of γ-alumina and Pt/γ-alumina interfaces is important to further the understanding of the structure/property relationships in this system.

Published

2023

3. The atomic-level structure and stability of interfaces of Pt nanoparticles in alumina: An experimental and computational evaluation

Author

Clauser, A.L., Oware Sarfo, K., Ophus, C., Ciston, J., Giulian, R., Árnadóttir, L., and Santala, M.K.

Published

2024

4. Phase-contrast imaging of multiply-scattering extended objects at atomic resolution by reconstruction of the scattering matrix

Author

Pelz, PM, Brown, HG, Stonemeyer, S, Findlay, SD, Zettl, A, Ercius, P, Zhang, Y, Ciston, J, Scott, MC, and Ophus, C

Subjects

Bioengineering

Abstract

Three-dimensional phase-contrast imaging of multiply-scattering samples in x-ray and electron microscopy is challenging due to small numerical apertures, the unavailability of wave front shaping optics, and the highly nonlinear inversion required from intensity-only measurements. In this work, we present an algorithm using the scattering matrix formalism to solve the scattering from a noncrystalline medium from scanning diffraction measurements and simultaneously recover the illumination aberrations. We demonstrate our method experimentally in a scanning transmission electron microscope, recovering the scattering matrix of a heterogeneous sample with two layers of multiwall carbon nanotubes filled with TaTe2 core-shell structures, spaced 10nm apart in the axial direction. Our work enables phase contrast imaging and materials characterization in multiply-scattering samples at high resolution for a wide range of materials.

Published

2021

5. Hard x-ray standing-wave photoemission insights into the structure of an epitaxial Fe/MgO multilayer magnetic tunnel junction

Author

Conlon, C. S., Conti, G., Nemšák, S., Palsson, G., Moubah, R., Kuo, C. -T., Gehlmann, M., Ciston, J., Rault, J., Rueff, J. -P., Salmassi, F., Stolte, W., Rattanachata, A., Lin, S. -C., Keqi, A., Saw, A., Hjörvarsson, B., and Fadley, C. S.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The Fe/MgO magnetic tunnel junction is a classic spintronic system, with current importance technologically, and interest for future innovation. The key magnetic properties are linked directly to the structure of hard-to-access buried interfaces, and the Fe and MgO components near the surface are unstable when exposed to air, making a deeper probing, non-destructive, in-situ measurement ideal for this system. We have thus applied hard x-ray photoemission spectroscopy (HXPS) and standing-wave (SW) HXPS in the few keV energy range to probe the structure of an epitaxially-grown MgO/Fe superlattice. The superlattice consists of 9 repeats of MgO grown on Fe by magnetron sputtering on an MgO (001) substrate, with a protective Al2O3 capping layer. We determine through SW-HXPS that 8 of the 9 repeats are similar and ordered, with a period of 33 $\pm$ 4 angstrom, with minor presence of FeO at the interfaces and a significantly distorted top bilayer with ca. 3 times the oxidation of the lower layers at the top MgO/Fe interface. There is evidence of asymmetrical oxidation on the top and bottom of the Fe layers. We find agreement with dark-field scanning transmission electron microscope (STEM) and x-ray reflectivity measurements. Through the STEM measurements we confirm an overall epitaxial stack with dislocations and warping at the interfaces of ca. 5 angstrom. We also note a distinct difference in the top bilayer, especially MgO, with possible Fe inclusions. We thus demonstrate that SW-HXPS can be used to probe deep buried interfaces of novel magnetic devices with few angstrom precision., Comment: 37 pages, 13 figures

Published

2019

6. Probing single unit-cell resolved electronic structure modulations in oxide superlattices with standing-wave photoemission

Author

Yang, W., Chandrasena, R. U., Gu, M., Reis, R. M. S. dos, Moon, E. J., Arab, Arian, Husanu, M. -A., Ciston, J., Strocov, V. N., Rondinelli, J. M., May, S. J., and Gray, A. X.

Subjects

Condensed Matter - Materials Science

Abstract

Control of structural couplings at the complex-oxide interfaces is a powerful platform for creating new ultrathin layers with electronic and magnetic properties unattainable in the bulk. However, with the capability to design and control the electronic structure of such buried layers and interfaces at a unit-cell level, a new challenge emerges to be able to probe these engineered emergent phenomena with depth-dependent atomic resolution as well as element- and orbital selectivity. Here, we utilize a combination of core-level and valence-band soft x-ray standing-wave photoemission spectroscopy, in conjunction with scanning transmission electron microscopy, to probe the depth-dependent and single-unit-cell resolved electronic structure of an isovalent manganite superlattice [Eu0.7Sr0.3MnO3/La0.7Sr0.3MnO3]x15 wherein the electronic-structural properties are intentionally modulated with depth via engineered oxygen octahedra rotations/tilts and A-site displacements. Our unit-cell resolved measurements reveal significant transformations in the local chemical and electronic valence-band states, which are consistent with the layer-resolved first-principles theoretical calculations, thus opening the door for future depth-resolved studies of a wide variety of hetero-engineered material systems.

Published

2019

7. Origins of the transformability of nickel-titanium shape memory alloys

Author

Chen, X, Ophus, C, Song, C, Ciston, J, Das, S, Song, Y, Chumlyakov, Y, Minor, AM, Gavini, V, and James, RD

Subjects

cond-mat.mtrl-sci

Abstract

The near equiatomic NiTi alloy is the most successful shape memory alloy by a large margin. It is widely and increasingly used in biomedical devices. Yet, despite having a repeatable superelastic effect and excellent shape-memory, NiTi is very far from satisfying the conditions that characterize the most reversible phase-transforming materials. Thus, the scientific reasons underlying its vast success present an enigma. In this paper, we perform rigorous mathematical derivations and accurate density-functional theory calculations of transformation mechanisms to seek previously unrecognized twinlike defects that we term involution domains, and we observe them in real space in NiTi by aberration-corrected scanning transmission electron microscopy. Involution domains lead to an additional 216 compatible interfaces between phases in NiTi, and we theorize that this feature contributes importantly to its reliability. They are expected to arise in other transformations and to alter the conventional interpretation of the mechanism of the martensitic transformation.

Published

2020

8. Supported Metal Pair-Site Catalysts

Author

Guan, E, Ciston, J, Bare, SR, Runnebaum, RC, Katz, A, Kulkarni, A, Kronawitter, CX, and Gates, BC

Subjects

supported metal catalysts, dinuclear catalysts, active sites, zeolites, X-ray absorption spectroscopy, CO FTIR, scanning transmission electron microscopy, Inorganic Chemistry, Organic Chemistry, Chemical Engineering

Abstract

Complexes with neighboring metal centers in isolated pairs and their analogues on surfaces are drawing increasing attention as catalysts. These include molecular homogeneous catalysts incorporating various ligands, enzymes, and solids that include pairs of metal atoms mounted on supports. Catalysts in this broad class are active for numerous reactions and offer unexplored opportunities to address challenging reactions, such as oxidation of methane and oxidation of water in artificial photosynthesis. The subject of supported metal pair-site catalysts is in its infancy, facing challenges in (a) precise synthesis, (b) structure determination at the atomic scale, and (c) stabilization in reactive atmospheres. In this Perspective, we summarize key characteristics of molecular and enzymatic catalysts that incorporate neighboring metal centers and build on this foundation to assess the emerging literature of metal pair-site catalysts on various supports. The supported catalysts include those synthesized by anchoring molecular dinuclear precursors to support surfaces and those synthesized by selective formation of dinuclear surface species from mononuclear surface species. Examples of metals in this class are rhodium and iridium, and examples of supports are MgO and Fe2O3. We summarize characterization of these materials by electron microscopy and spectroscopy, emphasizing atomic-resolution aberration-corrected scanning transmission electron microscopy and spectroscopies that provide atomic-scale structural information and allow characterization of functioning catalysts, especially X-ray absorption spectroscopy. We list some opportunities for research, including suggestions that might lead to structurally well-defined supported metal pair-sites with new catalytic properties.

Published

2020

9. Dynamic Covalent Synthesis of Crystalline Porous Graphitic Frameworks

Author

Li, X, Wang, H, Chen, H, Zheng, Q, Zhang, Q, Mao, H, Liu, Y, Cai, S, Sun, B, Dun, C, Gordon, MP, Zheng, H, Reimer, JA, Urban, JJ, Ciston, J, Tan, T, Chan, EM, and Zhang, J

Subjects

Macromolecular and Materials Chemistry

Abstract

Porous graphitic framework (PGF) is a two-dimensional (2D) material that has emerging energy applications. An archetype contains stacked 2D layers, the structure of which features a fully annulated aromatic skeleton with embedded heteroatoms and periodic pores. Due to the lack of a rational approach in establishing in-plane order under mild synthetic conditions, the structural integrity of PGF has remained elusive and ultimately limited its material performance. Here, we report the discovery of the unusual dynamic character of the C=N bonds in the aromatic pyrazine ring system under basic aqueous conditions, which enables the successful synthesis of a crystalline porous nitrogenous graphitic framework with remarkable in-plane order, as evidenced by powder X-ray diffraction studies and direct visualization using high-resolution transmission electron microscopy. The crystalline framework displays superior performance as a cathode material for lithium-ion batteries, outperforming the amorphous counterparts in terms of capacity and cycle stability. Insertion of well-defined, evenly spaced nanoscale pores into the two-dimensional (2D) layers of graphene invokes exciting properties due to the modulation of its electronic band gaps and surface functionalities. A bottom-up synthesis approach to such porous graphitic frameworks (PGFs) is appealing but also remains a great challenge. The current methods of building covalent organic frameworks rely on a small collection of thermodynamically reversible reactions. Such reactions are, however, inadequate in generating a fully annulated aromatic skeleton in PGFs. With the discovery of dynamic pyrazine formation, we succeeded in applying this linking chemistry to obtain a crystalline PGF material, which has displayed high electrical conductivity and remarkable performance as a cathode material for lithium-ion batteries. We envision that the demonstrated success will open the door to a wide array of fully annulated 2D porous frameworks, which hold immense potential for clean energy applications. We report the unusual dynamic characteristics of the C=N bonds in the pyrazine ring promoted under basic aqueous conditions, which enables the successful synthesis of two-dimensional porous graphitic frameworks (PGFs) featuring fully annulated aromatic skeletons and periodic pores. The PGF displayed high electrical conductivity and remarkable performance as a cathode material for lithium-ion batteries, far outperforming the amorphous counterparts in terms of capacity and cycle stability.

Published

2020

10. Characterization of polyhedral nano-oxides and helium bubbles in an annealed nanostructured ferritic alloy

Author

Stan, T, Wu, Y, Ciston, J, Yamamoto, T, and Odette, GR

Subjects

ODS ferritic steel, Nanostructured metals, Electron backscatter diffraction, Transmission electron microscopy, High-resolution electron microscopy, Nanostructured ferritic alloy, Materials, Condensed Matter Physics, Materials Engineering, Mechanical Engineering

Abstract

Nanostructured ferritic alloys (NFAs) contain an ultra-high density of 2–4 nm fcc pyrochlore Y2Ti2O7 nano-oxides (NOs) embedded in a bcc Fe-14Cr ferritic matrix. Characterization of helium interactions with NOs and associated Fe-Y2Ti2O7 interfaces is important to the development of structural materials for nuclear fusion and fission applications. A benchmark 14YWT NFA was first annealed to coarsen the NOs, then insoluble helium was implanted at 700 °C to produce a high number density of bubbles. High-resolution scanning transmission electron microscopy characterization shows two dominant Fe-Y2Ti2O7 crystallographic orientation relationships (cube-on-edge and cube-on-cube). The smallest NOs (≈ 2 nm) are associated with the smaller bubbles (≈ 1.5 nm), while some of the largest NOs (> 6 nm) have larger, and sometimes multiple, bubbles. NO corner {111} facets are the preferred sites for He bubble nucleation. A refined sequence of events for He trapping and bubble formation is presented. These observations offer new insight on He management in NFAs, and provide a foundation for detailed modeling studies.

Published

2020

11. Linear-scaling algorithm for rapid computation of inelastic transitions in the presence of multiple electron scattering

Author

Brown, HG, Ciston, J, and Ophus, C

Subjects

Stem Cell Research, Bioengineering, cond-mat.mtrl-sci, physics.comp-ph

Abstract

Strong multiple scattering of the probe in scanning transmission electron microscopy (STEM) means image simulations are usually required for quantitative interpretation and analysis of elemental maps produced by electron energy-loss spectroscopy (EELS). These simulations require a full quantum-mechanical treatment of multiple scattering of the electron beam, both before and after a core-level inelastic transition. Current algorithms scale quadratically and can take up to a week to calculate on desktop machines even for simple crystal unit cells and do not scale well to the nanoscale heterogeneous systems that are often of interest to materials science researchers. We introduce an algorithm with linear scaling that typically results in an order of magnitude reduction in computation time for these calculations without introducing additional error and discuss approximations that further improve computational scaling for larger-scale objects with modest penalties in calculation error. We demonstrate these speedups by calculating the atomic resolution STEM-EELS map using the L-edge transition of Fe, for a nanoparticle 80 Å in diameter, in 16 hours, a calculation that would have taken at least 80 days using a conventional multislice approach.

Published

2019

12. Hierarchically-structured large superelastic deformation in ferroelastic-ferroelectrics

Author

Deng, Y, Gammer, C, Ciston, J, Ercius, P, Ophus, C, Bustillo, K, Song, C, Zhang, R, Wu, D, Du, Y, Chen, Z, Dong, H, Khachaturyan, AG, and Minor, AM

Subjects

Superelastic deformation, Ferroelastic-ferroelectrics, Hierarchical structure, In situ transmission electron microscope, 4D-STEM, Materials, Condensed Matter Physics, Materials Engineering, Mechanical Engineering

Abstract

Large superelastic deformation in ferroelastic-ferroelectrics (FMs) is a complex phenomenon involving multiple mechanisms operating simultaneously. Understanding how these mechanisms contribute corporately is critical to apply this useful property to the intrinsically brittle FMs, which can therefore display both excellent functional and mechanical performance. Here, we have directly observed and quantitatively analyzed in situ in a transmission electron microscope the three main mechanisms of twinning domain, phase transformation and mobile point defect contributing to extremely large superelastic deformation in single-crystal BaTiO3 (5.0% strain) and Pb(Mg1/3Nb2/3)O3-PbTiO3 (10.1% strain). Our results reveal the hierarchical origin of large recoverable strain in “brittle” FMs.

Published

2019

13. Nature of the metal-insulator transition in few-unit-cell-thick LaNiO3 films

Author

Golalikhani, M., Lei, Q., Chandrasena, R. U., Kasaei, L., Park, H., Bai, J., Orgiani, P., Ciston, J., Sterbinsky, G. E., Arena, D. A., Shafer, P., Arenholz, E., Davidson, B. A., Millis, A. J., Gray, A. X., and Xi, X. X.

Subjects

Condensed Matter - Materials Science

Abstract

The nature of the metal insulator transition in thin films and superlattices of LaNiO3 with only few unit cells in thickness remains elusive despite tremendous effort. Quantum confinement and epitaxial strain have been evoked as the mechanisms, although other factors such as growth-induced disorder, cation non-stoichiometry, oxygen vacancies, and substrate-film interface quality may also affect the observable properties in the ultrathin films. Here we report results obtained for near-ideal LaNiO3 films with different thicknesses and terminations grown by atomic layer-by-layer laser molecular beam epitaxy on LaAlO3 substrates. We find that the room-temperature metallic behavior persists until the film thickness is reduced to an unprecedentedly small 1.5 unit cells (NiO2 termination). Electronic structure measurements using x-ray absorption spectroscopy and first-principles calculation suggest that oxygen vacancies existing in the films also contribute to the metal insulator transition.

Published

2018

14. Probing single-unit-cell resolved electronic structure modulations in oxide superlattices with standing-wave photoemission

Author

Yang, W, Chandrasena, RU, Gu, M, Dos Reis, RMS, Moon, EJ, Arab, A, Husanu, MA, Nemšák, S, Gullikson, EM, Ciston, J, Strocov, VN, Rondinelli, JM, May, SJ, and Gray, AX

Subjects

cond-mat.mtrl-sci, Bioengineering

Abstract

Control of structural coupling at complex-oxide interfaces is a powerful platform for creating ultrathin layers with electronic and magnetic properties unattainable in the bulk. However, with the capability to design and control the electronic structure of such buried layers and interfaces at a unit-cell level, a new challenge emerges to be able to probe these engineered emergent phenomena with depth-dependent atomic resolution as well as element- and orbital selectivity. Here, we utilize a combination of core-level and valence-band soft x-ray standing-wave photoemission spectroscopy, in conjunction with scanning transmission electron microscopy, to probe the depth-dependent and single-unit-cell resolved electronic structure of an isovalent manganite superlattice [Eu0.7Sr0.3MnO3/La0.7Sr0.3MnO3]×15 wherein the electronic-structural properties are intentionally modulated with depth via engineered oxygen octahedra rotations/tilts and A-site displacements. Our unit-cell resolved measurements reveal significant transformations in the local chemical and electronic valence-band states, which are consistent with the layer-resolved first-principles theoretical calculations, thus opening the door for future depth-resolved studies of a wide variety of heteroengineered material systems.

Published

2019

15. Hard x-ray standing-wave photoemission insights into the structure of an epitaxial Fe/MgO multilayer magnetic tunnel junction

Author

Conlon, CS, Conti, G, Nemšák, S, Palsson, G, Moubah, R, Kuo, C-T, Gehlmann, M, Ciston, J, Rault, J, Rueff, J-P, Salmassi, F, Stolte, W, Rattanachata, A, Lin, S-C, Keqi, A, Saw, A, Hjörvarsson, B, and Fadley, CS

Subjects

cond-mat.mtrl-sci, cond-mat.mes-hall, Mathematical Sciences, Physical Sciences, Engineering, Applied Physics

Abstract

The Fe/MgO magnetic tunnel junction is a classic spintronic system, with current importance technologically and interest for future innovation. The key magnetic properties are linked directly to the structure of hard-to-access buried interfaces, and the Fe and MgO components near the surface are unstable when exposed to air, making a deeper probing, nondestructive, in-situ measurement ideal for this system. We have thus applied hard X-ray photoemission spectroscopy (HXPS) and standing-wave (SW) HXPS in the few kilo-electron-volt energy range to probe the structure of an epitaxially grown MgO/Fe superlattice. The superlattice consists of 9 repeats of MgO grown on Fe by magnetron sputtering on an MgO(001) substrate, with a protective Al2O3 capping layer. We determine through SW-HXPS that 8 of the 9 repeats are similar and ordered, with a period of 33 ± 4 Å, with the minor presence of FeO at the interfaces and a significantly distorted top bilayer with ca. 3 times the oxidation of the lower layers at the top MgO/Fe interface. There is evidence of asymmetrical oxidation on the top and bottom of the Fe layers. We find agreement with dark-field scanning transmission electron microscope (STEM) and X-ray reflectivity measurements. Through the STEM measurements, we confirm an overall epitaxial stack with dislocations and warping at the interfaces of ca. 5 Å. We also note a distinct difference in the top bilayer, especially MgO, with possible Fe inclusions. We thus demonstrate that SW-HXPS can be used to probe deep buried interfaces of novel magnetic devices with few-angstrom precision.

Published

2019

16. Atomic Resolution Probing of Phase Transformations and Domain Evolution During Large Superelastic Deformation in Ferroelectrics with in situ TEM

Author

Deng, Y, Gammer, C, Ciston, J, Ercius, Peter, Ophus, C, Bustillo, KC, Song, Chengyu, Zhang, Ruopeng, and Minor, AM

Subjects

Condensed Matter Physics, Materials Engineering, Biochemistry and Cell Biology, Microscopy

Published

2019

17. Structure Retrieval at Atomic Resolution in the Presence of Multiple Scattering of the Electron Probe

Author

Brown, HG, Chen, Z, Weyland, M, Ophus, C, Ciston, J, Allen, LJ, and Findlay, SD

Subjects

Physical Sciences, Condensed Matter Physics, Bioengineering, cond-mat.mtrl-sci, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences

Abstract

The projected electrostatic potential of a thick crystal is reconstructed at atomic resolution from experimental scanning transmission electron microscopy data recorded using a new generation fast-readout electron camera. This practical and deterministic inversion of the equations encapsulating multiple scattering that were written down by Bethe in 1928 removes the restriction of established methods to ultrathin (≲50  Å) samples. Instruments already coming on line can overcome the remaining resolution-limiting effects in this method due to finite probe-forming aperture size, spatial incoherence, and residual lens aberrations.

Published

2018

18. Interpretable and Efficient Interferometric Contrast in Scanning Transmission Electron Microscopy with a Diffraction-Grating Beam Splitter

Author

Harvey, TR, Yasin, FS, Chess, JJ, Pierce, JS, Dos Reis, RMS, Özdöl, VB, Ercius, P, Ciston, J, Feng, W, Kotov, NA, McMorran, BJ, and Ophus, C

Subjects

physics.ins-det, cond-mat.mtrl-sci, physics.optics, Stem Cell Research, Bioengineering, Physical Sciences, Engineering

Abstract

Efficient imaging of biomolecules, two-dimensional materials, and electromagnetic fields depends on retrieval of the phase of transmitted electrons. We demonstrate a method to measure phase in a scanning transmission electron microscope (STEM) using a nanofabricated diffraction grating to produce multiple probe beams. The measured phase is more interpretable than phase-contrast scanning transmission electron microscopy techniques without an off-axis reference wave, and the resolution could surpass that of off-axis electron holography. We apply this technique, called STEM holography, to image nanoparticles, carbon substrates, and electric fields. The contrast observed in experiments agrees well with contrast predicted in simulations.

Published

2018

19. Surface Structural and Chemical Evolution of Layered LiNi0.8Co0.15Al0.05O2 (NCA) under High Voltage and Elevated Temperature Conditions

Author

Mukherjee, P, Faenza, NV, Pereira, N, Ciston, J, Piper, LFJ, Amatucci, GG, and Cosandey, F

Subjects

Materials, Chemical Sciences, Engineering

Abstract

This paper reports new insights into structural and chemical evolution of surface phases of LiNi0.8Co0.15Al0.05O2 (NCA) held at constant high voltages (up to 4.75 V) as well as high temperatures (60 °C) by correlating crystal structure using high angle annular dark field scanning transmission electron microscopy (HAADF-STEM) imaging with chemistry using electron energy loss spectroscopy (EELS). We also followed the Al distribution within individual NCA particles by X-ray energy dispersive spectroscopy (EDS). The progression of these phases as a function of distance from the edge shows simultaneous evolution of crystal structures and chemistry from rocksalt to layered, forming a complete solid solution. We have also observed an extended disordered phase with rocksalt (Fm3m) symmetry in which quantitative electron energy loss spectroscopy reveals it to be an oxygen deficient cation disordered phase with chemical characteristics, as determined by EELS, similar to spinel. The formation of these disordered phases with cation and oxygen vacancies has been driven by surface oxygen loss caused by reactions with the electrolyte followed by cation migration from the octahedral 3a M (M = Ni, Co, Al) layer to the octahedral 3b Li layer. These surface rocksalt phases are not fully dense as they contain Al and Li as well as a high concentration of cation and oxygen vacancies. After discharge, Li is detected within these phases indicative that Li transport has occurred through these rocksalt phases. At 60 °C and 4.75 V a very large impedance rise is observed leading to complete cell irreversibility which is caused by significant metal dissolution from the cathode and formation of surface porosity. In the near surface region of some particles, a phase transformation from R3m (O3) to P3m1 (O1) is also observed which has become thermodynamically stable from complete delithiation as well as from local Al surface depletion.

Published

2018

20. Microstructure and magnetic properties of ultrathin FePt granular films

Author

Zhang, Y, Kalitsov, A, Ciston, J, Mryasov, O, Ozdol, B, Zhu, J, Jain, S, Zhang, B, Livshitz, B, Chernyshov, A, Ajan, A, Dorsey, P, Bertero, G, Acharya, R, Greene, A, and Myers, S

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Optical Physics, Quantum Physics, Electrical and Electronic Engineering

Abstract

FePt granular films with grain size smaller than 10 nm are promising candidates for storage media used in the next generation heat-assisted magnetic recording technology. However, FePt films show degraded magnetic properties when the grain size is reduced to this scale, which cannot be explained solely by the finite size theory. In this study, we explored the structural cause of property degradation by employing advanced electron microscopy and atomistic modeling. Structural features unique to the nanostructured FePt granular films at significantly reduced grain sizes of 2∼8 nm were studied by high-resolution scanning transmission electron microscopy with geometric aberrations corrected up to the third order. Two critical structural parameters, the threshold grain size corresponding to the upper size limit of the FePt grains with zero chemical ordering and the sub-nanometer thin interfacial impurity at grain boundaries, were identified. A new atomistic model was developed to correlate these structural characteristics with key magnetic properties such as Curie temperature, saturation magnetization, magnetocrystalline anisotropy, and their grain-to-grain variation. The model shows good agreement with the experimental magnetic data and explains the gap in magnetic properties between the bulk and nanostructured FePt.

Published

2018

21. Depth-resolved charge reconstruction at the LaNiO3/CaMnO3 interface

Author

Chandrasena, RU, Flint, CL, Yang, W, Arab, Arian, Nemšák, S, Gehlmann, M, Özdöl, VB, Bisti, F, Wijesekara, KD, Meyer-Ilse, J, Gullikson, E, Arenholz, E, Ciston, J, Schneider, CM, Strocov, VN, Suzuki, Y, and Gray, AX

Subjects

Engineering, Physical Sciences, Condensed Matter Physics, Chemical sciences, Physical sciences

Abstract

Rational design of low-dimensional electronic phenomena at oxide interfaces is currently considered to be one of the most promising schemes for realizing new energy-efficient logic and memory devices. An atomically abrupt interface between paramagnetic LaNiO3 and antiferromagnetic CaMnO3 exhibits interfacial ferromagnetism, which can be tuned via a thickness-dependent metal-insulator transition in LaNiO3. Once fully understood, such emergent functionality could turn this archetypal Mott-interface system into a key building block for the above-mentioned future devices. Here, we use depth-resolved standing-wave photoemission spectroscopy in conjunction with scanning transmission electron microscopy and x-ray absorption spectroscopy, to demonstrate a depth-dependent charge reconstruction at the LaNiO3/CaMnO3 interface. Our measurements reveal an increased concentration of Mn3+ and Ni2+ cations at the interface, which create an electronic environment favorable for the emergence of interfacial ferromagnetism mediated via the Mn4+-Mn3+ ferromagnetic double exchange and Ni2+-O-Mn4+ superexchange mechanisms. Our findings suggest a strategy for designing functional Mott oxide heterostructures by tuning the interfacial cation characteristics via controlled manipulation of thickness, strain, and ionic defect states.

Published

2018

22. Nature of the metal-insulator transition in few-unit-cell-thick LaNiO3 films.

Author

Golalikhani, M, Lei, Q, Chandrasena, RU, Kasaei, L, Park, H, Bai, J, Orgiani, P, Ciston, J, Sterbinsky, GE, Arena, DA, Shafer, P, Arenholz, E, Davidson, BA, Millis, AJ, Gray, AX, and Xi, XX

Subjects

cond-mat.mtrl-sci

Abstract

The nature of the metal-insulator transition in thin films and superlattices of LaNiO3 only a few unit cells in thickness remains elusive despite tremendous effort. Quantum confinement and epitaxial strain have been evoked as the mechanisms, although other factors such as growth-induced disorder, cation non-stoichiometry, oxygen vacancies, and substrate-film interface quality may also affect the observable properties of ultrathin films. Here we report results obtained for near-ideal LaNiO3 films with different thicknesses and terminations grown by atomic layer-by-layer laser molecular beam epitaxy on LaAlO3 substrates. We find that the room-temperature metallic behavior persists until the film thickness is reduced to an unprecedentedly small 1.5 unit cells (NiO2 termination). Electronic structure measurements using X-ray absorption spectroscopy and first-principles calculation suggest that oxygen vacancies existing in the films also contribute to the metal-insulator transition.

Published

2018

23. In situ nanobeam electron diffraction strain mapping of planar slip in stainless steel

Author

Pekin, TC, Gammer, C, Ciston, J, Ophus, C, and Minor, AM

Subjects

Nanobeam electron diffraction, Strain measurement, Scanning/transmission electron microscopy, Planar slip, Materials, Condensed Matter Physics, Materials Engineering, Mechanical Engineering

Abstract

Nanobeam electron diffraction strain mapping has been used to measure the strain evolution in stainless steel under in situ deformation. As the amount of deformation increases, the leading dislocation of a planar slip band leaves behind a residual strain in the form of a small lattice expansion. Dislocation analysis confirmed that the dislocations involved were type. While the characteristic residual strain of planar slip has often been observed, it has never before been directly measured. Our results provide a view into the dynamic mechanisms of planar slip, and showcase the possibilities of multidimensional in situ imaging.

Published

2018

24. Determination of the structural phase and octahedral rotation angle in halide perovskites

Author

Dos Reis, R, Yang, H, Ophus, C, Ercius, P, Bizarri, G, Perrodin, D, Shalapska, T, Bourret, E, Ciston, J, and Dahmen, U

Subjects

Applied Physics, Engineering, Physical Sciences, Technology

Abstract

A key to the unique combination of electronic and optical properties in halide perovskite materials lies in their rich structural complexity. However, their radiation sensitive nature limits nanoscale structural characterization requiring dose efficient microscopic techniques in order to determine their structures precisely. In this work, we determine the space-group and directly image the Br halide sites of CsPbBr3, a promising material for optoelectronic applications. Based on the symmetry of high-order Laue zone reflections of convergent-beam electron diffraction, we identify the tetragonal (I4/mcm) structural phase of CsPbBr3 at cryogenic temperature. Electron ptychography provides a highly sensitive phase contrast measurement of the halide positions under low electron-dose conditions, enabling imaging of the elongated Br sites originating from the out-of-phase octahedral rotation viewed along the [001] direction of I4/mcm persisting at room temperature. The measurement of these features and comparison with simulations yield an octahedral rotation angle of 6.5°(±1.5°). The approach demonstrated here opens up opportunities for understanding the atomic scale structural phenomena applying advanced characterization tools on a wide range of radiation sensitive halide-based all-inorganic and hybrid organic-inorganic perovskites.

Published

2018

25. Development of a fast framing detector for electron microscopy

Author

Johnson, IJ, Bustillo, KC, Ciston, J, Dart, E, Draney, BR, Ercius, P, Fong, E, Grace, CR, Joseph, JM, Lee, JR, Minor, AM, Ophus, C, Skinner, DE, Stezelberger, T, Tindall, CS, and Denes, P

Abstract

A high frame rate detector system is being developed to enable fast real-time data analysis of scanning diffraction experiments in scanning transmission electron microscopy (STEM). This is an end-to-end development that encompasses the data producing detector, data transportation, and real-time processing of data. The detector will consist of a central pixel sensor that is surrounded by annular silicon diodes. Both components of the detector system will synchronously capture data at almost 100 kHz frame rate, which produces an approximately 400 Gb/s data stream. Low-level preprocessing will be implemented in firmware before the data is streamed from the National Center for Electron Microscopy (NCEM) to the National Energy Research Scientific Computing Center (NERSC). Live data processing, before it lands on disk, will happen on the Cori supercomputer and aims to present scientists with prompt experimental feedback. This online analysis will provide rough information of the sample that can be utilized for sample alignment, sample monitoring and verification that the experiment is set up correctly. Only a compressed version of the relevant data is then selected for more in-depth processing.

Published

2017

26. Dynamics of Symmetry-Breaking Stacking Boundaries in Bilayer MoS2

Author

Yan, A, Ong, CS, Qiu, DY, Ophus, C, Ciston, J, Merino, C, Louie, SG, and Zettl, A

Subjects

cond-mat.mtrl-sci, cond-mat.mes-hall, Physical Chemistry, Engineering, Chemical Sciences, Technology

Abstract

Crystal symmetry of two-dimensional (2D) materials plays an important role in their electronic and optical properties. Engineering symmetry in 2D materials has recently emerged as a promising way to achieve novel properties and functions. The noncentrosymmetric structure of monolayer transition metal dichalcogenides (TMDCs), such as molybdenum disulfide (MoS2), has allowed for valley control via circularly polarized optical excitation. In bilayer TMDCs, inversion symmetry can be controlled by varying the stacking sequence, thus providing a pathway to engineer valley selectivity. Here, we report the in situ integration of AA′ and AB stacked bilayer MoS2 with different inversion symmetries by creating atomically sharp stacking boundaries between the differently stacked domains, via thermal stimulation and electron irradiation, inside an atomic-resolution scanning transmission electron microscopy. The setup enables us to track the formation and atomic motion of the stacking boundaries in real time and with ultrahigh resolution which enables in-depth analysis on the atomic structure at the boundaries. In conjunction with density functional theory calculations, we establish the dynamics of the boundary nucleation and expansion and further identify metallic boundary states. Our approach provides a means to synthesize domain boundaries with intriguing transport properties and opens up a new avenue for controlling valleytronics in nanoscale domains via real-time patterning of domains with different symmetry properties.

Published

2017

27. Non-spectroscopic composition measurements of SrTiO3-La0.7Sr0.3MnO3 multilayers using scanning convergent beam electron diffraction

Author

Ophus, C, Ercius, P, Huijben, M, and Ciston, J

Subjects

Applied Physics, Engineering, Physical Sciences, Technology

Abstract

The local atomic structure of a crystalline sample aligned along a zone axis can be probed with a focused electron probe, which produces a convergent beam electron diffraction pattern. The introduction of high speed direct electron detectors has allowed for experiments that can record a full diffraction pattern image at thousands of probe positions on a sample. By incoherently summing these patterns over crystalline unit cells, we demonstrate that in addition to crystal structure and thickness, we can also estimate the local composition of a perovskite superlattice sample. This is achieved by matching the summed patterns to a library of simulated diffraction patterns. This technique allows for atomic-scale chemical measurements without requiring a spectrometer or hardware aberration correction.

Published

2017

28. Theoretical and Experimental Study on the Optoelectronic Properties of Nb3O7(OH) and Nb2O5 Photoelectrodes

Author

Khan, W, Betzler, SB, Šipr, O, Ciston, J, Blaha, P, Scheu, C, and Minar, J

Subjects

Physical Chemistry, Engineering, Chemical Sciences, Technology

Abstract

Nb3O7(OH) and Nb2O5 nanostructures are promising alternative materials to conventionally used oxides, e.g. TiO2, in the field of photoelectrodes in dye-sensitized solar cells and photoelectrochemical cells. Despite this important future application, some of their central electronic properties such as the density of states, band gap, and dielectric function are not well understood. In this work, we present combined theoretical and experimental studies on Nb3O7(OH) and H-Nb2O5 to elucidate their spectroscopic, electronic, and transport properties. The theoretical results were obtained within the framework of density functional theory based on the full potential linearized augmented plane wave method. In particular, we show that the position of the H atom in Nb3O7(OH) has an important effect on its electronic properties. To verify theoretical predictions, we measured electron energy-loss spectra (EELS) in the low loss region, as well as, the O-K and Nb-M3 element-specific edges. These results are compared with corresponding theoretical EELS calculations and are discussed in detail. In addition, our calculations of thermoelectric conductivity show that Nb3O7(OH) has more suitable optoelectronic and transport properties for photochemical application than the calcined H-Nb2O5 phase.

Published

2016

29. Practical aspects of diffractive imaging using an atomic-scale coherent electron probe

Author

Chen, Z, Weyland, M, Ercius, P, Ciston, J, Zheng, C, Fuhrer, MS, D'Alfonso, AJ, Allen, LJ, and Findlay, SD

Subjects

Physical Sciences, Condensed Matter Physics, Stem Cell Research, Diffractive imaging, Convergent beam electron diffraction, Differential phase contrast, Phase reconstruction, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Optical Physics, Other Physical Sciences, Microscopy, Biochemistry and cell biology, Physical chemistry, Condensed matter physics

Abstract

Four-dimensional scanning transmission electron microscopy (4D-STEM) is a technique where a full two-dimensional convergent beam electron diffraction (CBED) pattern is acquired at every STEM pixel scanned. Capturing the full diffraction pattern provides a rich dataset that potentially contains more information about the specimen than is contained in conventional imaging modes using conventional integrating detectors. Using 4D datasets in STEM from two specimens, monolayer MoS2 and bulk SrTiO3, we demonstrate multiple STEM imaging modes on a quantitative absolute intensity scale, including phase reconstruction of the transmission function via differential phase contrast imaging. Practical issues about sampling (i.e. number of detector pixels), signal-to-noise enhancement and data reduction of large 4D-STEM datasets are emphasized.

Published

2016

30. Local and transient nanoscale strain mapping during in situ deformation

Author

Gammer, C, Kacher, J, Czarnik, C, Warren, OL, Ciston, J, and Minor, AM

Subjects

Engineering, Materials Engineering, Physical Sciences, Technology, Applied Physics, Physical sciences

Abstract

The mobility of defects such as dislocations controls the mechanical properties of metals. This mobility is determined both by the characteristics of the defect and the material, as well as the local stress and strain applied to the defect. Therefore, the knowledge of the stress and strain during deformation at the scale of defects is important for understanding fundamental deformation mechanisms. Here, we demonstrate a method of measuring local stresses and strains during continuous in situ deformation with a resolution of a few nanometers using nanodiffraction strain mapping. Our results demonstrate how large multidimensional data sets captured with high speed electron detectors can be analyzed in multiple ways after an in situ TEM experiment, opening the door for true multimodal analysis from a single electron scattering experiment.

Published

2016

31. Heat-Induced Phase Transformation of Three-Dimensional Nb3O7(OH) Superstructures: Effect of Atmosphere and Electron Beam

Author

Betzler, SB, Harzer, T, Ciston, J, Dahmen, U, Dehm, G, and Scheu, C

Subjects

Inorganic & Nuclear Chemistry, Physical Chemistry, Materials Engineering, Inorganic Chemistry, Physical Chemistry (incl. Structural)

Abstract

Nanostructured niobium oxides and hydroxides are potential candidates for photochemical applications due to their excellent optical and electronic properties. In the present work the thermal stability of Nb3O7(OH) superstructures prepared by a simple hydrothermal approach is investigated at the atomic scale. Transmission electron microscopy and electron energy-loss spectroscopy provide insights into the phase transformation occurring at elevated temperatures and probe the effect of the atmospheric conditions. In the presence of oxygen, H2O is released from the crystal at temperatures above 500 °C, and the crystallographic structure changes to H-Nb2O5. In addition to the high thermal stability of Nb3O7(OH), the morphology was found to be stable, and first changes in the form of a merging of nanowires are not observed until 850 °C. Under reducing conditions in a transmission electron microscope and during electron beam bombardment, an oxygen-deficient phase is formed at temperatures above 750 °C. This transformation starts with the formation of defects in the crystal lattice at 450 °C and goes along with the formation of pores in the nanowires which accommodate the volume differences of the two crystal phases.

Published

2016

32. The crystal structure, orientation relationships and interfaces of the nanoscale oxides in nanostructured ferritic alloys

Author

Wu, Y, Ciston, J, Kräemer, S, Bailey, N, Odette, GR, and Hosemann, P

Subjects

ODS steels, Nanoscale oxides, High-resolution electron microscopy, Scanning transmission electron microscopy, Nanostructured ferritic alloys, Condensed Matter Physics, Materials Engineering, Mechanical Engineering, Materials

Abstract

The capability of nanostructured ferritic alloys (NFAs) to manage high levels of transmutation product helium will help resolve one of the grand challenges to transforming the promise of C-free fusion energy into a reality. NFAs are dispersion strengthened by an ultrahigh density of Y-Ti-O nano-oxides (NOs), which result in both high strength and temperature limits, as well as unique irradiation tolerance. Here, aberration-corrected high-resolution transmission electron microscopy was used to characterize the NOs in four NFA conditions, including following severe deformation and extreme neutron radiation exposure. Fast Fourier Transform analysis of focal series images revealed the NO crystal structure, including the smallest at < 2 nm in diameter, to be Y2Ti2O7 pyrochlore in all cases, consistent with both exit wave analysis and scanning transmission Z-contrast imaging of the atomic columns in a larger feature. The faceted NOs exhibit a quasi-epitaxial orientation relationship with the ferrite matrix: [110]YTO||[100]Fe and [001]YTO||[010]Fe, forming a 5 × 7 near coincidence site interface. The NOs also exhibit size-dependent strains in both the oxide and matrix ferrite phases.

Published

2016

33. Identifying different stacking sequences in few-layer CVD-grown Mo S2 by low-energy atomic-resolution scanning transmission electron microscopy

Author

Yan, A, Chen, W, Ophus, C, Ciston, J, Lin, Y, Persson, K, and Zettl, A

Abstract

Atomically thin MoS2 grown by chemical vapor deposition (CVD) is a promising candidate for next-generation electronics due to inherent CVD scalability and controllability. However, it is well known that the stacking sequence in few-layer MoS2 can significantly impact electrical and optical properties. Herein we report different intrinsic stacking sequences in CVD-grown few-layer MoS2 obtained by atomic-resolution annular-dark-field imaging in an aberration-corrected scanning transmission electron microscope operated at 50 keV. Trilayer MoS2 displays a new stacking sequence distinct from the commonly observed 2H and 3R phases of MoS2. Density functional theory is used to examine the stability of different stacking sequences, and the findings are consistent with our experimental observations.

Published

2016

34. Vertically grown nanowire crystals of dibenzotetrathienocoronene (DBTTC) on large-area graphene

Author

Kim, B, Chiu, C-Y, Kang, SJ, Kim, KS, Lee, G-H, Chen, Z, Ahn, S, Yager, KG, Ciston, J, Nuckolls, C, and Schiros, T

Subjects

Chemical Sciences

Abstract

We demonstrate controlled growth of vertical organic crystal nanowires on single layer graphene. Using Scanning Electron Microscopy (SEM), high-resolution transmission electron microscopy (TEM), and Grazing Incidence X-ray Diffraction (GIXD), we probe the microstructure and morphology of dibenzotetrathienocoronene (DBTTC) nanowires epitaxially grown on graphene. The investigation is performed at both the ensemble and single nanowire level, and as a function of growth parameters, providing insight of and control over the formation mechanism. The size, density and height of the nanowires can be tuned via growth conditions, opening new avenues for tailoring three-dimensional (3-D) nanostructured architectures for organic electronics with improved functional performance.

Published

2016

35. Synthesis and characterization of (Ga1-xZnx)(N1-xOx) nanocrystals with a wide range of compositions

Author

Lee, K, Lu, YG, Chuang, CH, Ciston, J, and Dukovic, G

Subjects

Macromolecular and Materials Chemistry, Materials Engineering, Interdisciplinary Engineering

Abstract

We describe the synthesis and characterization of wurtzite (Ga1-xZnx)(N1-xOx) nanocrystals with a wide range of compositions and a focus on properties relevant for solar fuel generation. (Ga1-xZnx)(N1-xOx), a solid solution of GaN and ZnO, is an intriguing material because it exhibits composition-dependent visible absorption even though the parent semiconductors absorb in the UV. When functionalized with co-catalysts, (Ga1-xZnx)(N1-xOx) is also capable of water splitting under visible irradiation. Here, we examine the synthesis of (Ga1-xZnx)(N1-xOx) nanocrystals to understand how they form by nitridation of ZnO and ZnGa2O4 nanocrystalline precursors. We find that the ZnO precursor is critical for the formation of crystalline (Ga1-xZnx)(N1-xOx) at 650 °C, consistent with a mechanism in which wurtzite (Ga1-xZnx)(N1-xOx) nucleates topotactically on wurtzite ZnO at an interface with ZnGa2O4. Using this information, we expand the range of compositions from previously reported 0.30 ≤ x ≤ 0.87 to include the low-x and high-x ends of the range. The resulting compositions, 0.06 ≤ x ≤ 0.98, constitute the widest range of (Ga1-xZnx)(N1-xOx) compositions obtained by one synthetic method. We then examine how the band gap depends on sample composition and find a minimum of 2.25 eV at x = 0.87, corresponding to a maximum possible solar-to-H2 power conversion efficiency of 12%. Finally, we examine the photoelectrochemical (PEC) oxidation behavior of thick films of (Ga1-xZnx)(N1-xOx) nanocrystals with x = 0.40, 0.52, and 0.87 under visible illumination. (Ga1-xZnx)(N1-xOx) nanocrystals with x = 0.40 exhibit solar PEC oxidation activity that, while too low for practical applications, is higher than that of bulk (Ga1-xZnx)(N1-xOx) of the same composition. The highest photocurrents are observed at x = 0.52, even though x = 0.87 absorbs more visible light, illustrating that the observed photocurrents are a result of an interplay of multiple parameters which remain to be elucidated. This set of characterizations provides information useful for future studies of composition-dependent PEC properties of nanoscale (Ga1-xZnx)(N1-xOx).

Published

2016

36. Probing Local Electronic Transitions in Organic Semiconductors through Energy-Loss Spectrum Imaging in the Transmission Electron Microscope

Author

Guo, C, Allen, FI, Lee, Y, Le, TP, Song, C, Ciston, J, Minor, AM, and Gomez, ED

Subjects

energy-filtered transmission electron microscopy, low-loss spectrum imaging, morphology, organic semiconductors, valence EELS, Materials, Chemical Sciences, Engineering, Physical Sciences

Abstract

Improving the performance of organic electronic devices depends on exploiting the complex nanostructures formed in the active layer. Current imaging methods based on transmission electron microscopy provide limited chemical sensitivity, and thus the application to materials with compositionally similar phases or complicated multicomponent systems is challenging. Here, it is demonstrated that monochromated transmission electron microscopes can generate contrast in organic thin films based on differences in the valence electronic structure at energy losses below 10 eV. In this energy range, electronic fingerprints corresponding to interband excitations in organic semiconductors can be utilized to generate significant spectral contrast between phases. Based on differences in chemical bonding of organic materials, high-contrast images are thus obtained revealing the phase separation in polymer/fullerene mixtures. By applying principal component analysis to the spectroscopic image series, further details about phase compositions and local electronic transitions in the active layer of organic semiconductor mixtures can be explored. Monochromated transmission electron microscopes can generate contrast in organic thin films based on differences in the valence electronic structure at energy losses below 10 eV. By applying principal component analysis to the spectroscopic image series, further details about phase compositions and local electronic transitions in the active layer of organic semiconductor mixtures can be explored.

Published

2015

37. Strain mapping at nanometer resolution using advanced nano-beam electron diffraction

Author

Ozdol, VB, Gammer, C, Jin, XG, Ercius, P, Ophus, C, Ciston, J, and Minor, AM

Subjects

Applied Physics, Physical Sciences, Engineering, Technology

Abstract

We report on the development of a nanometer scale strain mapping technique by means of scanning nano-beam electron diffraction. Only recently possible due to fast acquisition with a direct electron detector, this technique allows for strain mapping with a high precision of 0.1% at a lateral resolution of 1 nm for a large field of view reaching up to 1 μm. We demonstrate its application to a technologically relevant strain-engineered GaAs/GaAsP hetero-structure and show that the method can even be applied to highly defected regions with substantial changes in local crystal orientation. Strain maps derived from atomically resolved scanning transmission electron microscopy images were used to validate the accuracy, precision and resolution of this versatile technique.

Published

2015

38. Momentum-resolved electronic structure at a buried interface from soft x-ray standing-wave angle-resolved photoemission

Author

Gray, A. X., Minár, J., Plucinski, L., Huijben, M., Bostwick, A., Rotenberg, E., Yang, S. -H., Braun, J., Winkelmann, A., Conti, G., Eiteneer, D., Rattanachata, A., Greer, A. A., Ciston, J., Ophus, C., Rijnders, G., Blank, D. H. A., Doennig, D., Pentcheva, R., Schneider, C. M., Ebert, H., and Fadley, C. S.

Subjects

Condensed Matter - Materials Science

Abstract

Angle-resolved photoemission spectroscopy (ARPES) is a powerful technique for the study of electronic structure, but it lacks a direct ability to study buried interfaces between two materials. We address this limitation by combining ARPES with soft x-ray standing-wave (SW) excitation (SWARPES), in which the SW profile is scanned through the depth of the sample. We have studied the buried interface in a prototypical magnetic tunnel junction La0.7Sr0.3MnO3/SrTiO3. Depth- and momentum-resolved maps of Mn 3d eg and t2g states from the central, bulk-like and interface-like regions of La0.7Sr0.3MnO3 exhibit distinctly different behavior consistent with a change in the Mn bonding at the interface. We compare the experimental results to state-of-the-art density-functional and one-step photoemission theory, with encouraging agreement that suggests wide future applications of this technique., Comment: 18 pages, 4 figures and Supplementary Information

Published

2013

39. Atomic Imaging Using Secondary Electrons in a Scanning Transmission Electron Microscope : Experimental Observations and Possible Mechanisms

Author

Inada, H., Su, D., Egerton, R. F., Konno, M., Wu, L., Ciston, J., Wall, J., and Zhu, Y.

Subjects

Condensed Matter - Materials Science

Abstract

We report our detailed investigation of high-resolution imaging using secondary electrons (SE) with a subnanometer probe in an aberration-corrected transmission electron microscope, Hitachi HD2700C. This instrument also allows us to acquire the corresponding annular-dark-field (ADF) images simultaneously and separately. We demonstrate that atomic SE imaging is achievable for a wide range of elements, from uranium to carbon. Using the ADF images as a reference, we study the SE image intensity and contrast as a function of applied bias, atomic number, crystal tilt and thickness to shed light on the origin of the unexpected ultrahigh resolution in SE imaging. We have also demonstrated that the SE signal is sensitive to the terminating species at a crystal surface. Possible mechanisms for atomicscale SE imaging are proposed. The ability to image both the surface and bulk of a sample at atomic scale is unprecedented, and could revolutionize the field of electron microscopy and imaging., Comment: 20 pages, including 16 figures and 2 tables

Published

2010

40. Structure and morphology of hydroxylated nickel oxide (111) surfaces

Author

Ciston, J., Subramanian, A., Kienzle, D. M., and Marks, L. D.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons

Abstract

We report an experimental and theoretical analysis of the sqrt(3)x sqrt(3)-R30 and 2x2 reconstructions on the NiO (111) surface combining transmission electron microscopy, x-ray photoelectron spectroscopy, and reasonably accurate density functional calculations using the meta-GGA hybrid functional TPSSh. While the main focus here is on the surface structure, we also observe an unusual step morphology with terraces containing only even numbers of unit cells during annealing of the surfaces. The experimental data clearly shows that the surfaces contain significant coverage of hydroxyl terminations, and the surface structures are essentially the same as those reported on the MgO (111) surface implying an identical kinetically-limited water-driven structural transition pathway. The octapole structure can therefore be all but ruled out for single crystals of NiO annealed in or transported through humid air. . The theoretical analysis indicates, as expected, that simple density functional theory methods for such strongly-correlated oxide surfaces are marginal, while better consideration of the metal d-electrons has a large effect although, it is still not perfect., Comment: Replaces previous submission with smaller PDF file size. 32 pages including 9 figures and 2 tables

Published

2009

41. Charge Density Refinement of the Si (111) 7x7 Surface

Author

Ciston, J., Subramanian, A., Robinson, I. K., and Marks, L. D.

Subjects

Condensed Matter - Materials Science

Abstract

We report an experimental refinement of the local charge density at the Si (111) 7x7 surface utilizing a combination of x-ray and high energy electron diffraction. By perturbing about a bond-centered pseudoatom model, we find experimentally that the adatoms are in an anti-bonding state with the atoms directly below. We are also able to experimentally refine a charge transfer of 0.26(4) e- from each adatom site to the underlying layers. These results are compared with a full-potential all-electron density functional DFT calculation., Comment: 10 pages including 1 Figure

Published

2009

42. Hydroxylated MgO (111) reconstructions: why the case for clean surfaces does not hold water

Author

Ciston, J., Subramanian, A., and Marks, L. D.

Subjects

Condensed Matter - Materials Science

Abstract

We report an experimental and theoretical analysis of the root(3)xroot(3)-R30 and 2x2 reconstructions on the MgO (111) surface combining transmission electron microscopy, x-ray photoelectron spectroscopy, and reasonably accurate density functional calculations using the meta-GGA functional TPSS. The experimental data clearly shows that the surfaces contain significant coverages of hydroxyl terminations, even after UHV annealing, and as such cannot be the structures which have been previously reported. For the 2x2 surfaces a relatively simple structural framework is detailed which fits all the experimental and theoretical data. For the root(3)xroot(3) there turn out to be two plausible structures and neither the experimental nor theoretical results can differentiate between the two within error. However, by examining the conditions under which the surface is formed we describe a kinetic route for the transformation between the different reconstructions that involves mobile hydroxyl groups and protons, and relatively immobile cations, which strongly suggests only one of the two root(3)xroot(3) structures., Comment: 29 Pages including 13 Figures

Published

2008

43. Characterization of the atomic-level structure of γ-alumina and (111) Pt/γ-alumina interfaces

Author

Clauser, A.L., primary, Sarfo, K. Oware, additional, Giulian, R., additional, Ophus, C., additional, Ciston, J., additional, Árnadóttir, L., additional, and Santala, M.K., additional

Published

2023

44. Stabilization and control of persistent current magnets using variable inductance

Author

Brouwer, L, Brouwer, L, Shen, T, Norris, R, Hafalia, A, Schlueter, R, Wang, L, Ciston, J, Ercius, P, Ji, Q, Mankos, M, Ophus, C, Stibor, A, Schmid, A, Minor, AM, Denes, P, Brouwer, L, Brouwer, L, Shen, T, Norris, R, Hafalia, A, Schlueter, R, Wang, L, Ciston, J, Ercius, P, Ji, Q, Mankos, M, Ophus, C, Stibor, A, Schmid, A, Minor, AM, and Denes, P

Abstract

Ultra-stable, tunable magnetic fields are desirable for a wide range of applications in medical imaging, electron microscopy, quantum science, and atomic physics. Superconducting magnets operated in persistent current mode, with device current flowing in a closed superconducting loop disconnected from a power source, are a common approach for applications with the most stringent requirements on temporal field stability. We present a method for active control of this persistent current by means of dynamic inductance change within the superconducting circuit. For a first realization of this general technique, we consider a variable superconducting inductor placed in series with the main magnet. The inductor acts as a dynamic flux storage device capable of transferring flux to or from the main magnet through inductance change. This allows for fine and fast adjustments of the persistent current without the use of thermal switches that limit the speed and accuracy of many present-day methods. With first experiments employing this technique, we demonstrate stabilization of a 1.95 T Nb-Ti round lens for electron microscopy against decay resulting from residual losses in the superconducting circuit, and more generally show flexibility for precise control over the magnitude and waveform of the persistent current.

Published

2022

45. A Three-Dimensional Reconstruction Algorithm for Scanning Transmission Electron Microscopy Data from a Single Sample Orientation

Author

Brown, HG, Brown, HG, Pelz, PM, Hsu, SL, Zhang, Z, Ramesh, R, Inzani, K, Sheridan, E, Griffin, SM, Schloz, M, Pekin, TC, Koch, CT, Findlay, SD, Allen, LJ, Scott, MC, Ophus, C, Ciston, J, Brown, HG, Brown, HG, Pelz, PM, Hsu, SL, Zhang, Z, Ramesh, R, Inzani, K, Sheridan, E, Griffin, SM, Schloz, M, Pekin, TC, Koch, CT, Findlay, SD, Allen, LJ, Scott, MC, Ophus, C, and Ciston, J

Abstract

Increasing interest in three-dimensional nanostructures adds impetus to electron microscopy techniques capable of imaging at or below the nanoscale in three dimensions. We present a reconstruction algorithm that takes as input a focal series of four-dimensional scanning transmission electron microscopy (4D-STEM) data. We apply the approach to a lead iridate, PbIrO, and yttrium-stabilized zirconia, YZrO, heterostructure from data acquired with the specimen in a single plan-view orientation, with the epitaxial layers stacked along the beam direction. We demonstrate that Pb-Ir atomic columns are visible in the uppermost layers of the reconstructed volume. We compare this approach to the alternative techniques of depth sectioning using differential phase contrast scanning transmission electron microscopy (DPC-STEM) and multislice ptychographic reconstruction.

Published

2022

46. On the provenance of GEMS, a quarter century post discovery

Author

Bradley, JP, Bradley, JP, Ishii, HA, Bustillo, K, Ciston, J, Ogliore, R, Stephan, T, Brownlee, DE, Joswiak, DJ, Bradley, JP, Bradley, JP, Ishii, HA, Bustillo, K, Ciston, J, Ogliore, R, Stephan, T, Brownlee, DE, and Joswiak, DJ

Abstract

The provenance of GEMS (glass with embedded metal and sulfides) in cometary type interplanetary dust particles is investigated using analytical scanning transmission electron microscopy and secondary ion mass spectrometry. We review the current state of knowledge and closely examine the densities, elemental compositions and distributions, iron oxidation states, and isotopic compositions of a subset of GEMS in chondritic porous interplanetary dust. We find that GEMS are underdense with estimated densities that are 35–65% of compositionally equivalent crystalline aggregates. GEMS low densities result in a lower contribution to the bulk compositions of IDPs than has been assumed based on their volume fraction. We also find that element/Si ratios, assumed to be primary (indigenous), are instead perturbed by contamination and secondary alteration, including pulse heating during atmospheric entry. Fe in pyrrhotite inclusions was oxidized and Mg, S, Ca, and Fe were depleted relative to lithophile Al and Si, resulting in reduction in element/Si ratios. Because they trap outgassing elements, Fe-rich oxide rims that formed on the surface of GEMS are serendipitous “witness plates” to the changes in composition that accompany atmospheric entry. As a result of alteration, GEMS elemental compositions cannot reliably inform about their provenance. Except for highly anomalous oxygen isotope ratios measured in some large GEMS grains that indicate a contribution from circumstellar dust, oxygen isotope compositions are generally poor indicators of provenance. Prior work indicates that most GEMS fall close to the terrestrial oxygen isotope composition, which, however, does not exclude a presolar interstellar origin. Nitrogen isotopic compositions are more diagnostic. Elevated 15N/14N ratios indicate that GEMS accreted in conjunction with formation of organic matter by ion–molecule reactions in a cold (<50 K) presolar environment like the extreme outer nebula or interstellar medium.

Published

2022

47. Characterization of the Atomic-Level Structure of Γ-Alumina and (111) Pt/Γ-Alumina Interfaces

Author

Clauser, A.L., primary, Sarfo, K. Oware, additional, Giulian, R., additional, Ophus, C., additional, Ciston, J., additional, Árnadóttir, L., additional, and Santala, Melissa, additional

Published

2022

48. Why the case for clean surfaces does not hold water: Structure and morphology of hydroxylated nickel oxide (1 1 1)

Author

Ciston, J., Subramanian, A., Kienzle, D.M., and Marks, L.D.

Published

2010

49. Direct Observation of Tribochemically Assisted Wear on Diamond-Like Carbon Thin Films

Author

M’ndange-Pfupfu, A., Ciston, J., Eryilmaz, O., Erdemir, A., and Marks, L. D.

Published

2013

50. Prismatic 2.0-Simulation software for scanning and high resolution transmission electron microscopy (STEM and HRTEM)

Author

DaCosta, LR, Brown, GH, Pelz, MP, Rakowski, A, Barber, N, O'Donovan, P, McBean, P, Jones, L, Ciston, J, Scott, MC, Ophus, C, DaCosta, LR, Brown, GH, Pelz, MP, Rakowski, A, Barber, N, O'Donovan, P, McBean, P, Jones, L, Ciston, J, Scott, MC, and Ophus, C

Abstract

Scanning transmission electron microscopy (STEM), where a converged electron probe is scanned over a sample's surface and an imaging, diffraction, or spectroscopic signal is measured as a function of probe position, is an extremely powerful tool for materials characterization. The widespread adoption of hardware aberration correction, direct electron detectors, and computational imaging methods have made STEM one of the most important tools for atomic-resolution materials science. Many of these imaging methods rely on accurate imaging and diffraction simulations in order to interpret experimental results. However, STEM simulations have traditionally required large calculation times, as modeling the electron scattering requires a separate simulation for each of the typically millions of probe positions. We have created the Prismatic simulation code for fast simulation of STEM experiments with support for multi-CPU and multi-GPU (graphics processing unit) systems, using both the conventional multislice and our recently-introduced PRISM method. In this paper, we introduce Prismatic version 2.0, which adds many new algorithmic improvements, an updated graphical user interface (GUI), post-processing of simulation data, and additional operating modes such as plane-wave TEM. We review various aspects of the simulation methods and codes in detail and provide various simulation examples. Prismatic 2.0 is freely available both as an open-source package that can be run using a C++ or Python command line interface, or GUI, as well within a Docker container environment.

Published

2021