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1. Superconducting phase diagram in Bi$_x$Ni$_{1-x}$ thin films$\colon$ the effects of Bi stoichiometry on superconductivity

Author

Park, Jihun, Horn, Jarryd A., Kirsch, Dylan J., Pant, Rohit K., Yoon, Hyeok, Baek, Sungha, Sarker, Suchismita, Mehta, Apurva, Zhang, Xiaohang, Lee, Seunghun, Greene, Richard, Paglione, Johnpierre, and Takeuchi, Ichiro

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

The Bi${-}$Ni binary system has been of interest due to possible unconventional superconductivity aroused therein, such as time-reversal symmetry breaking in Bi/Ni bilayers or the coexistence of superconductivity and ferromagnetism in Bi$_3$Ni crystals. While Ni acts as a ferromagnetic element in such systems, the role of strong spin-orbit-coupling element Bi in superconductivity has remained unexplored. In this work, we systematically studied the effects of Bi stoichiometry on the superconductivity of Bi$_x$Ni$_{1-x}$ thin films (${x} \approx$ 0.5 to 0.9) fabricated via a composition-spread approach. The superconducting phase map of Bi$_x$Ni$_{1-x}$ thin films exhibited a superconducting composition region attributable to the intermetallic Bi$_3$Ni phase with different amount of excess Bi, revealed by synchrotron X-ray diffraction analysis. Interestingly, the mixed phase region with Bi$_3$Ni and Bi showed unusual increases in the superconducting transition temperature and residual resistance ratio as more Bi impurities were included, with the maximum ${T}_{c}$ ($=$ 4.2 K) observed at $x \approx$ 0.79. A correlation analysis of structural, electrical, and magneto-transport characteristics across the composition variation revealed that the unusual superconducting $"$dome$"$ is due to two competing roles of Bi$\colon$ impurity scattering and carrier doping. We found that the carrier doping effect is dominant in the mild doping regime (0.74 $\leq {x} \leq$ 0.79), while impurity scattering becomes more pronounced at larger Bi stoichiometry.

Published
2024

2. Co-orchestration of Multiple Instruments to Uncover Structure-Property Relationships in Combinatorial Libraries

Author

Slautin, Boris N., Pratiush, Utkarsh, Ivanov, Ilia N., Liu, Yongtao, Pant, Rohit, Zhang, Xiaohang, Takeuchi, Ichiro, Ziatdinov, Maxim A., and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science, Computer Science - Machine Learning
Abstract

The rapid growth of automated and autonomous instrumentations brings forth an opportunity for the co-orchestration of multimodal tools, equipped with multiple sequential detection methods, or several characterization tools to explore identical samples. This can be exemplified by the combinatorial libraries that can be explored in multiple locations by multiple tools simultaneously, or downstream characterization in automated synthesis systems. In the co-orchestration approaches, information gained in one modality should accelerate the discovery of other modalities. Correspondingly, the orchestrating agent should select the measurement modality based on the anticipated knowledge gain and measurement cost. Here, we propose and implement a co-orchestration approach for conducting measurements with complex observables such as spectra or images. The method relies on combining dimensionality reduction by variational autoencoders with representation learning for control over the latent space structure, and integrated into iterative workflow via multi-task Gaussian Processes (GP). This approach further allows for the native incorporation of the system's physics via a probabilistic model as a mean function of the GP. We illustrated this method for different modalities of piezoresponse force microscopy and micro-Raman on combinatorial $Sm-BiFeO_3$ library. However, the proposed framework is general and can be extended to multiple measurement modalities and arbitrary dimensionality of measured signals. The analysis code that supports the funding is publicly available at https://github.com/Slautin/2024_Co-orchestration., Comment: 22 pages, 9 figures

Published
2024
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3. Newton saw the truth -- on the nature of fluid flow and viscous interaction

Author

He, Jian, Wang, Jin, Kong, Qiaocong, Zhao, Penglong, Cai, Xiaoshu, Zhang, Xiaohang, and Zou, Wennan

Subjects
Physics - Fluid Dynamics
Abstract

The viscous interaction of fluid is understood as the response to deformation, which is proportional to the strain rate. This model has gradually become the standard since Stokes, and has become the basis of the classical flow theory, namely the Navier-Stokes (N-S) equations. However, it has never been accurately verified in the curved laminar flow. Here, a distinctive unambiguous simple experiment is designed to falsify the viscosity model of deformation, and instead a new model is proposed, that is, the viscous friction originates from the slip of fluid layering at molecular scale. Though Newton contributed the initial idea of slip viscosity, the new model cannot be formulated without the help of modern differential geometry. From the new model, the analytical solution of laminar Taylor-Couette (T-C) flow between two concentric cylinders can reproduce the result of the ideal experiment proposed by Newton as the outer cylinder being infinite, which was once considered a mistake of Newton. A significant difference with the solution of the N-S equations when the outer cylinder is relatively large can be used to distinguish the viscosity models, even for the simplest case with both cylinders rotating with the same angular velocity. The accurate measurement data by the LDA support the slip model, and the consequent flow theory inevitably leads to a new vision in turbulence research., Comment: 25 pages, 14figures, 2 tables

Published
2023

8. Titanium Nitride Film on Sapphire Substrate with Low Dielectric Loss for Superconducting Qubits

Author

Deng, Hao, Song, Zhijun, Gao, Ran, Xia, Tian, Bao, Feng, Jiang, Xun, Ku, Hsiang-Sheng, Li, Zhisheng, Ma, Xizheng, Qin, Jin, Sun, Hantao, Tang, Chengchun, Wang, Tenghui, Wu, Feng, Yu, Wenlong, Zhang, Gengyan, Zhang, Xiaohang, Zhou, Jingwei, Zhu, Xing, Shi, Yaoyun, Zhao, Hui-Hai, and Deng, Chunqing

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Dielectric loss is one of the major decoherence sources of superconducting qubits. Contemporary high-coherence superconducting qubits are formed by material systems mostly consisting of superconducting films on substrate with low dielectric loss, where the loss mainly originates from the surfaces and interfaces. Among the multiple candidates for material systems, a combination of titanium nitride (TiN) film and sapphire substrate has good potential because of its chemical stability against oxidization, and high quality at interfaces. In this work, we report a TiN film deposited onto sapphire substrate achieving low dielectric loss at the material interface. Through the systematic characterizations of a series of transmon qubits fabricated with identical batches of TiN base layers, but different geometries of qubit shunting capacitors with various participation ratios of the material interface, we quantitatively extract the loss tangent value at the substrate-metal interface smaller than $8.9 \times 10^{-4}$ in 1-nm disordered layer. By optimizing the interface participation ratio of the transmon qubit, we reproducibly achieve qubit lifetimes of up to 300 $\mu$s and quality factors approaching 8 million. We demonstrate that TiN film on sapphire substrate is an ideal material system for high-coherence superconducting qubits. Our analyses further suggest that the interface dielectric loss around the Josephson junction part of the circuit could be the dominant limitation of lifetimes for state-of-the-art transmon qubits.

Published
2022

15. Hypothesis Learning in Automated Experiment: Application to Combinatorial Materials Libraries

Author

Ziatdinov, Maxim, Liu, Yongtao, Morozovska, Anna N., Eliseev, Eugene A., Zhang, Xiaohang, Takeuchi, Ichiro, and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science, Physics - Data Analysis, Statistics and Probability
Abstract

Machine learning is rapidly becoming an integral part of experimental physical discovery via automated and high-throughput synthesis, and active experiments in scattering and electron/probe microscopy. This, in turn, necessitates the development of active learning methods capable of exploring relevant parameter spaces with the smallest number of steps. Here we introduce an active learning approach based on co-navigation of the hypothesis and experimental spaces. This is realized by combining the structured Gaussian Processes containing probabilistic models of the possible system's behaviors (hypotheses) with reinforcement learning policy refinement (discovery). This approach closely resembles classical human-driven physical discovery, when several alternative hypotheses realized via models with adjustable parameters are tested during an experiment. We demonstrate this approach for exploring concentration-induced phase transitions in combinatorial libraries of Sm-doped BiFeO3 using Piezoresponse Force Microscopy, but it is straightforward to extend it to higher-dimensional parameter spaces and more complex physical problems once the experimental workflow and hypothesis-generation are available., Comment: Fixed typo in Eq. 1. Expanded the introduction part. The code reproducing Algorithm 1 is available at https://github.com/ziatdinovmax/hypoAL

Published
2021
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17. Becoming Equitable Educators: Practical Measures to Support Teachers' Dispositional Growth

Author

Jensen, Bryant, Whiting, Erin Feinauer, Hernández, Jimmy, Zhang, Xiaohang, Pliego, Diego, and Sudweeks, Richard

Abstract

Animating equity in teaching and learning depends on teacher dispositions--orientations to self, others, and society that underlie how we think and act. Teacher dispositions are virtues or qualities of moral character that modify the ways we interact with students and educator colleagues. Although interest in "measuring to improve" teaching and teacher education has grown recently, most measures lack validity evidence for practical usefulness. Integrating Messick's "unified validity framework" with Janssen et al.'s notion of "practicality" (as face validity), we find through an iterative, mixed-methods analysis of interviews with equitable educators and survey responses from teacher candidates that incorporating recognizability, relevance, and feasibility concerns of equity disposition concepts (i.e., Social Awareness, Meekness, Advocacy for Students) within survey items enhances item-to-factor structure of a self-report measure. We discuss implications (1) to develop and appraise formative measures and (2) to support teacher learning and development to become equitable educators.

Published
2023
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18. Fluxonium: an alternative qubit platform for high-fidelity operations

Author

Bao, Feng, Deng, Hao, Ding, Dawei, Gao, Ran, Gao, Xun, Huang, Cupjin, Jiang, Xun, Ku, Hsiang-Sheng, Li, Zhisheng, Ma, Xizheng, Ni, Xiaotong, Qin, Jin, Song, Zhijun, Sun, Hantao, Tang, Chengchun, Wang, Tenghui, Wu, Feng, Xia, Tian, Yu, Wenlong, Zhang, Fang, Zhang, Gengyan, Zhang, Xiaohang, Zhou, Jingwei, Zhu, Xing, Shi, Yaoyun, Chen, Jianxin, Zhao, Hui-Hai, and Deng, Chunqing

Subjects
Quantum Physics
Abstract

Superconducting qubits provide a promising path toward building large-scale quantum computers. The simple and robust transmon qubit has been the leading platform, achieving multiple milestones. However, fault-tolerant quantum computing calls for qubit operations at error rates significantly lower than those exhibited in the state of the art. Consequently, alternative superconducting qubits with better error protection have attracted increasing interest. Among them, fluxonium is a particularly promising candidate, featuring large anharmonicity and long coherence times. Here, we engineer a fluxonium-based quantum processor that integrates high qubit-coherence, fast frequency-tunability, and individual-qubit addressability for reset, readout, and gates. With simple and fast gate schemes, we achieve an average single-qubit gate fidelity of 99.97% and a two-qubit gate fidelity of up to 99.72%. This performance is comparable to the highest values reported in the literature of superconducting circuits. Thus our work, for the first time within the realm of superconducting qubits, reveals an approach toward fault-tolerant quantum computing that is alternative and competitive to the transmon system.

Published
2021
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19. Chiral Spin Bobbers in Exchange-Coupled Hard-Soft Magnetic Bilayers

Author

Zhang, Xiaohang, Gao, Tieren, Fang, Lei, Fackler, Sean, Borchers, Julie A., Kirby, Brian J., Maranville, Brian B., Lofland, Samuel E., N'Diaye, Alpha T., Arenholz, Elke, Ullah, Ahsan, Cui, Jun, Skomski, Ralph, and Takeuchi, Ichiro

Subjects
Condensed Matter - Materials Science
Abstract

The spin structure of exchange-coupled MnBi:Co-Fe bilayers is investigated by X-ray magnetic circular dichroism (XMCD), polarized neutron reflectometry (PNR), and micromagnetic simu-lations. The purpose of the present research is two-fold. First, the current search for new permanent-magnet materials includes hard-soft nanocomposites, and the analysis of coercivity mechanisms in these structures is an important aspect of this quest. Second, topological micro-magnetic structures such as skyrmions have recently become of intense fundamental and applied research, for example in the context of spin-based electronics. We find that the magnetization reversal of the MnBi:Co-Fe bilayer structure involves a curling-type twisting of the magnetization in the film plane. This curling in the exchange-coupled hard-soft magnetic bilayers is reminiscent of chiral spin structures known as bobbers and, in fact, establishes a new type of skyrmionic spin structure.

Published
2021
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25. Mapping causal patterns in crystalline solids

Author

Nelson, Chris, Morozovska, Anna N., Ziatdinov, Maxim A., Eliseev, Eugene A., Zhang, Xiaohang, Takeuchi, Ichiro, and Kalinin, Sergei V.

Subjects
Physics - Data Analysis, Statistics and Probability, Condensed Matter - Materials Science
Abstract

The evolution of the atomic structures of the combinatorial library of Sm-substituted thin film BiFeO3 along the phase transition boundary from the ferroelectric rhombohedral phase to the non-ferroelectric orthorhombic phase is explored using scanning transmission electron microscopy (STEM). Localized properties including polarization, lattice parameter, and chemical composition are parameterized from atomic-scale imaging and their causal relationships are reconstructed using a linear non-Gaussian acyclic model (LiNGAM). This approach is further extended toward exploring the spatial variability of the causal coupling using the sliding window transform method, which revealed that new causal relationships emerged both at the expected locations, such as domain walls and interfaces, but also at additional regions forming clusters in the vicinity of the walls or spatially distributed features. While the exact physical origins of these relationships are unclear, they likely represent nanophase separated regions in the morphotropic phase boundaries. Overall, we pose that an in-depth understanding of complex disordered materials away from thermodynamic equilibrium necessitates understanding not only of the generative processes that can lead to observed microscopic states, but also the causal links between multiple interacting subsystems.

Published
2021

26. Deep learning polarization distributions in ferroelectrics from STEM data: with and without atom finding

Author

Ghosh, Ayana, Nelson, Christopher T., Oxley, Mark, Zhang, Xiaohang, Ziatdinov, Maxim, Takeuchi, Ichiro, and Kalinin, Sergei V.

Subjects
Physics - Data Analysis, Statistics and Probability
Abstract

Over the last decade, scanning transmission electron microscopy (STEM) has emerged as a powerful tool for probing atomic structures of complex materials with picometer precision, opening the pathway toward exploring ferroelectric, ferroelastic, and chemical phenomena on the atomic-scale. Analyses to date extracting a polarization signal from lattice coupled distortions in STEM imaging rely on discovery of atomic positions from intensity maxima/minima and subsequent calculation of polarization and other order parameter fields from the atomic displacements. Here, we explore the feasibility of polarization mapping directly from the analysis of STEM images using deep convolutional neural networks (DCNNs). In this approach, the DCNN is trained on the labeled part of the image (i.e., for human labelling), and the trained network is subsequently applied to other images. We explore the effects of the choice of the descriptors (centered on atomic columns and grid-based), the effects of observational bias, and whether the network trained on one composition can be applied to a different one. This analysis demonstrates the tremendous potential of the DCNN for the analysis of high-resolution STEM imaging and spectral data and highlights the associated limitations.

Published
2021
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27. Unsupervised learning of ferroic variants from atomically resolved STEM images

Author

Valleti, Mani, Kalinin, Sergei V., Nelson, Christopher T., Peters, Jonathan J. P., Dong, Wen, Beanland, Richard, Zhang, Xiaohang, Takeuchi, Ichiro, and Ziatdinov, Maxim

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

An approach for the analysis of atomically resolved scanning transmission electron microscopy data with multiple ferroic variants in the presence of imaging non-idealities and chemical variabilities based on a rotationally invariant variational autoencoder (rVAE) is presented. We show that an optimal local descriptor for the analysis is a sub-image centered at specific atomic units, since materials and microscope distortions preclude the use of an ideal lattice as a reference point. The applicability of unsupervised clustering and dimensionality reduction methods is explored and are shown to produce clusters dominated by chemical and microscope effects, with a large number of classes required to establish the presence of rotational variants. Comparatively, the rVAE allows extraction of the angle corresponding to the orientation of ferroic variants explicitly, enabling straightforward identification of the ferroic variants as regions with constant or smoothly changing latent variables and sharp orientational changes. This approach allows further exploration of the chemical variability by separating the rotational degrees of freedom via rVAE and searching for remaining variability in the system. The code used in the manuscript is available at https://github.com/saimani5/ferroelectric_domains_rVAE., Comment: 19 pages, 7 Figures

Published
2021
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28. Boosting Adversarial Transferability Through Intermediate Feature

Author

He, Chenghai, Li, Xiaoqian, Zhang, Xiaohang, Zhang, Kai, Li, Hailing, Xiong, Gang, Li, Xuan, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Iliadis, Lazaros, editor, Papaleonidas, Antonios, editor, Angelov, Plamen, editor, and Jayne, Chrisina, editor

Published
2023
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29. Boosting the Robustness of Neural Networks with M-PGD

Author

He, Chenghai, Zhou, Li, Zhang, Kai, Li, Hailing, Cao, Shoufeng, Xiong, Gang, Zhang, Xiaohang, Filipe, Joaquim, Editorial Board Member, Ghosh, Ashish, Editorial Board Member, Prates, Raquel Oliveira, Editorial Board Member, Zhou, Lizhu, Editorial Board Member, Tanveer, Mohammad, editor, Agarwal, Sonali, editor, Ozawa, Seiichi, editor, Ekbal, Asif, editor, and Jatowt, Adam, editor

Published
2023
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30. Progress in Understanding the Relationship between Diabetes and Host Intestinal Microbiota and Diet-Mediated Microbiota Regulation

Author

WANG Danping, XU Jinzhao, ZHANG Xiaohang, NING Ke, LIU Ye, XU Yuanzhi, XIE Qinggang, XU Xiaoxi

Subjects
diabetes, diet, intestinal flora, system medicine, Food processing and manufacture, TP368-456
Abstract

Diabetes is a metabolic disease characterized by insulin secretion disorder. When serious, it can cause various complications (cardiovascular and cerebrovascular diseases, cataract and other eye diseases, kidney disease and cancer), bringing a huge economic burden to the society and families and torturing patients. The risk of diabetes is not only related to genes, living pressure and working environment, but also directly related to patients’ lifestyles and dietary habits. An unhealthy diet (high in fat and sugar) can induce the intestinal flora to produce adverse metabolites, which can in turn promote the occurrence and development of diabetes. Intestinal flora imbalance is widespread in the pathogenesis of various types of diabetes. As an important factor influencing the intestinal flora, diet is not only essential to maintain body functions, but also can contribute to intestinal immunity. Regulation of the intestinal environment through diet is expected to be an effective preventive means and auxiliary therapy for diabetes. By synthesizing the existing literature, this article discusses the features of the intestinal flora and the mechanism of the effect of diet-mediated regulation of the intestinal flora on diabetes based on systematic medical theory, and reviews the role scientific diet plays in regulating intestinal homeostasis and immunity and consequently reducing the incidence and complications of diabetes. We hope that this review will provide a basis for early diagnosis and prevention and adjuvant treatment of diabetes.

Published
2023
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31. No vortex in straight flows -- on the eigen-representations of velocity gradient

Author

Xu, Xiangyang, Xu, Zhiwen, Tang, Changxin, Zhang, Xiaohang, and Zou, Wennan

Subjects
Physics - Fluid Dynamics, 15A18, 15A23, 76M23, 76M27
Abstract

Velocity gradient is the basis of many vortex recognition methods, such as Q criterion, $\Delta$ criterion, $\lambda_{2}$ criterion, $\lambda_{ci}$ criterion and $\Omega$ criterion, etc.. Except the $\lambda_{ci}$ criterion, all these criterions recognize vortices by designing various invariants, based on the Helmholtz decomposition that decomposes velocity gradient into strain rate and spin. In recent years, the intuition of 'no vortex in straight flows' has promoted people to analyze the vortex state directly from the velocity gradient, in which vortex can be distinguished from the situation that the velocity gradient has couple complex eigenvalues. A specious viewpoint to adopt the simple shear as an independent flow mode was emphasized by many authors, among them, Kolar proposed the triple decomposition of motion by extracting a so-called effective pure shearing motion; Li et al. introduced the so-called quaternion decomposition of velocity gradient and proposed the concept of eigen rotation; Liu et al. further mined the characteristic information of velocity gradient and put forward an effective algorithm of Liutex, and then developed the vortex recognition method. However, there is another explanation for the increasingly clear representation of velocity gradient, that is the local streamline pattern based on critical-point theory. In this paper, the tensorial expressions of the right/left real Schur forms of velocity gradient are clarified from the characteristic problem of velocity gradient. The relations between the involved parameters are derived and numerically verified. Comparing with the geometrical features of local streamline pattern, we confirm that the parameters in the right eigen-representation based on the right real Schur form of velocity gradient have good meanings to reveal the local streamline pattern. Some illustrative examples from the DNS data are presented., Comment: 16 pages, 9 figures, 1 appendix

Published
2020

32. Exploring physics of ferroelectric domain walls via Bayesian analysis of atomically resolved STEM data

Author

Nelson, Christopher T., Vasudevan, Rama K., Zhang, Xiaohang, Ziatdinov, Maxim, Eliseev, Eugene A., Takeuchi, Ichiro, Morozovska, Anna N., and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science
Abstract

The physics of ferroelectric domain walls is explored using the Bayesian inference analysis of atomically resolved STEM data. We demonstrate that domain wall profile shapes are ultimately sensitive to the nature of the order parameter in the material, including the functional form of Ginzburg-Landau-Devonshire expansion, and numerical value of the corresponding parameters. The preexisting materials knowledge naturally folds in the Bayesian framework in the form of prior distributions, with the different order parameters forming competing (or hierarchical) models. Here, we explore the physics of the ferroelectric domain walls in BiFeO3 using this method, and derive the posterior estimates of relevant parameters. More generally, this inference approach both allows learning materials physics from experimental data with associated uncertainty quantification, and establishing guidelines for instrumental development answering questions on what resolution and information limits are necessary for reliable observation of specific physical mechanisms of interest., Comment: Upload the accepted version

Published
2020
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33. Predictability as a probe of manifest and latent physics: The case of atomic scale structural, chemical, and polarization behaviors in multiferroic Sm-doped BiFeO3

Author

Ziatdinov, Maxim, Creange, Nicole, Zhang, Xiaohang, Morozovska, Anna, Eliseev, Eugene, Vasudevan, Rama K., Takeuchi, Ichiro, Nelson, Chris, and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science
Abstract

The predictability of a certain effect or phenomenon is often equated with the knowledge of relevant physical laws, typically understood as a functional or numerically derived relationship between the observations and known states of the system. Correspondingly, observations inconsistent with prior knowledge can be used to derive new knowledge on the nature of the system or indicate the presence of yet unknown mechanisms. Here we explore the applicability of Gaussian Processes (GP) to establish predictability and uncertainty of local behaviors from multimodal observations, providing an alternative to this classical paradigm. Using atomic-resolution Scanning Transmission Electron Microscopy (STEM) of multiferroic Sm-doped BiFeO3 across a broad composition range, we directly visualize the atomic structure and structural, physical, and chemical order parameter fields for the material. GP regression is used to establish the predictability of the local polarization field from different groups of parameters, including the adjacent polarization values and several combinations of physical and chemical descriptors, including lattice parameters, column intensities, etc. We observe that certain elements of microstructure including charged and uncharged domain walls and interfaces with the substrate are best predicted with specific combinations of descriptors, and this predictability and their associated uncertainties are consistent across the composition series. The associated generative physical mechanisms are discussed. We argue that predictability and uncertainty in observational data offers a new pathway to probe the physics of condensed matter systems from multimodal local observations., Comment: Update the accepted version

Published
2020
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34. Causal analysis of competing atomistic mechanisms in ferroelectric materials from high-resolution Scanning Transmission Electron Microscopy data

Author

Ziatdinov, Maxim, Nelson, Chris, Zhang, Xiaohang, Vasudevan, Rama, Eliseev, Eugene, Morozovska, Anna N., Takeuchi, Ichiro, and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science
Abstract

Machine learning has emerged as a powerful tool for the analysis of mesoscopic and atomically resolved images and spectroscopy in electron and scanning probe microscopy, with the applications ranging from feature extraction to information compression and elucidation of relevant order parameters to inversion of imaging data to reconstruct structural models. However, the fundamental limitation of machine learning methods is their correlative nature, leading to extreme susceptibility to confounding factors. Here, we implement the workflow for causal analysis of structural scanning transmission electron microscopy (STEM) data and explore the interplay between physical and chemical effects in ferroelectric perovskite across the ferroelectric-antiferroelectric phase transitions. The combinatorial library of the Sm-doped BiFeO3 is grown to cover the composition range from pure ferroelectric BFO to orthorhombic 20% Sm-doped BFO. Atomically resolved STEM images are acquired for selected compositions and are used to create a set of local compositional, structural, and polarization field descriptors. The information-geometric causal inference (IGCI) and additive noise model (ANM) analysis are used to establish the pairwise causal directions between the descriptors, ordering the data set in the causal direction. The causal chain for IGCI and ANM across the composition is compared and suggests the presence of common causal mechanisms across the composition series. Ultimately, we believe that the causal analysis of the multimodal data will allow exploring the causal links between multiple competing mechanisms that control the emergence of unique functionalities of morphotropic materials and ferroelectric relaxors., Comment: Updated Figures 5 and 6 and the associated text

Published
2020

38. Microwave Meissner Screening of Proximity coupled Topological Insulator / Superconductor Bilayers

Author

Bae, Seokjin, Lee, Seunghun, Zhang, Xiaohang, Takeuchi, Ichiro, and Anlage, Steven M.

Subjects
Condensed Matter - Superconductivity
Abstract

The proximity coupled topological insulator / superconductor (TI/SC) bilayer system is a representative system to realize topological superconductivity. In order to better understand this unique state and design devices from the TI/SC bilayer, a comprehensive understanding of the microscopic properties of the bilayer is required. In this work, a microwave Meissner screening study, which exploits a high-precision microwave resonator technique, is conducted on the SmB6/YB6 thin film bilayers as an example TI/SC system. The study reveals spatially dependent electrodynamic screening response of the TI/SC system that is not accessible to other techniques, from which the corresponding microscopic properties of a TI/SC bilayer can be obtained. The TI thickness dependence of the effective penetration depth suggests the existence of a bulk insulating region in the TI layer. The spatially dependent electrodynamic screening model analysis provides an estimate for the characteristic lengths of the TI/SC bilayer: normal penetration depth, normal coherence length, and the thickness of the surface states. We also discuss implications of these characteristic lengths on the design of a vortex Majorana device such as the radius of the vortex core, the energy splitting due to intervortex tunneling, and the minimum thickness required for a device., Comment: 10 pages, 5 figures

Published
2019
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41. Observation of perfect Andreev reflection due to Klein paradox in a topological superconducting state

Author

Lee, Seunghun, Stanev, Valentin, Zhang, Xiaohang, Stasak, Drew, Flowers, Jack, Higgins, Joshua S., Dai, Sheng, Blum, Thomas, Pan, Xiaoqing, Yakovenko, Victor M., Paglione, Johnpierre, Greene, Richard L., Galitski, Victor, and Takeuchi, Ichiro

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

In 1928, P. Dirac proposed a new wave equation to describe relativistic electrons. Shortly afterwards, O. Klein solved a simple potential step problem for the Dirac equation and stumbled upon an apparent paradox - the potential becomes transparent when the height is larger than the electron energy. For massless particles, backscattering is completely forbidden in Klein tunneling, leading to perfect transmission through any potential barrier. Recent advent of condensed matter systems with Dirac-like excitations, such as graphene and topological insulators (TIs), has opened the possibility of observing the Klein tunneling experimentally. In the surface states of TIs, fermions are bound by spin-momentum locking, and are thus immune to backscattering due to time-reversal symmetry. Here we report the observation of perfect Andreev reflection in point contact spectroscopy - a clear signature of Klein tunneling and a manifestation of the underlying relativistic physics of a proximity-induced superconducting state in a topological Kondo insulator.

Published
2018
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