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1. ϕ ( ρz ) Distributions in Bulk and Thin Film Samples for EPMA. Part 1: A Modified ϕ ( ρz ) Distribution for Bulk Materials, Including Characteristic and Bremsstrahlung Fluorescence

   https://doi.org/10.1017/S1431927620024915  

   Moy, Aurélien; Fournelle, John (April 2021, Microscopy and Microanalysis)

   null (Ed.)

   Electron probe microanalysis is a nondestructive technique widely used to determine the elemental composition of bulk samples. This was extended to layered specimens, with the development of appropriate software. The traditional quantification method requires the use of matrix correction procedures based upon models of the ionization depth distribution, the so-called ϕ ( ρz ) distribution. Most of these models have led to commercial quantification programs but only few of them allow the quantification of layered specimens. Therefore, we developed BadgerFilm, a free open-source thin film program available to the general public. This program implements a documented ϕ ( ρz ) model as well as algorithms to calculate fluorescence in bulk and thin film samples. Part 1 of the present work aims at describing the operation of the implemented ϕ ( ρz ) distribution model and validating its implementation against experimental measurements and Monte Carlo simulations on bulk samples. The program has the ability to predict absolute X-ray intensities that can be directly compared to Monte Carlo simulations. We demonstrate that the implemented model works very well for bulk materials. And as will be shown in Part 2, BadgerFilm predictions for thin film specimens are also shown to be in good agreements with experimental and Monte Carlo results. 

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2. Thin‐Film Ferroelectrics

   https://doi.org/10.1002/adma.202108841  

   Fernandez, Abel; Acharya, Megha; Lee, Han‐Gyeol; Schimpf, Jesse; Jiang, Yizhe; Lou, Djamila; Tian, Zishen; Martin, Lane_W (June 2022, Advanced Materials)

   Abstract Over the last 30 years, the study of ferroelectric oxides has been revolutionized by the implementation of epitaxial‐thin‐film‐based studies, which have driven many advances in the understanding of ferroelectric physics and the realization of novel polar structures and functionalities. New questions have motivated the development of advanced synthesis, characterization, and simulations of epitaxial thin films and, in turn, have provided new insights and applications across the micro‐, meso‐, and macroscopic length scales. This review traces the evolution of ferroelectric thin‐film research through the early days developing understanding of the roles of size and strain on ferroelectrics to the present day, where such understanding is used to create complex hierarchical domain structures, novel polar topologies, and controlled chemical and defect profiles. The extension of epitaxial techniques, coupled with advances in high‐throughput simulations, now stands to accelerate the discovery and study of new ferroelectric materials. Coming hand‐in‐hand with these new materials is new understanding and control of ferroelectric functionalities. Today, researchers are actively working to apply these lessons in a number of applications, including novel memory and logic architectures, as well as a host of energy conversion devices. 

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3. Intermolecular interaction and cooperativity in an Fe(II) spin crossover molecular thin film system

   https://doi.org/10.1088/1361-648X/ac6cbc  

   Hao, Guanhua; Dale, Ashley S; N’Diaye, Alpha T; Chopdekar, Rajesh V; Koch, Roland J; Jiang, Xuanyuan; Mellinger, Corbyn; Zhang, Jian; Cheng, Ruihua; Xu, Xiaoshan; et al (May 2022, Journal of Physics: Condensed Matter)

   Abstract Compact domain features have been observed in spin crossover [Fe{H 2 B(pz) 2 } 2 (bipy)] molecular thin film systems via soft x-ray absorption spectroscopy and photoemission electron microscopy. The domains are in a mixed spin state that on average corresponds to roughly 2/3 the high spin occupation of the pure high spin state. Monte Carlo simulations support the presence of intermolecular interactions that can be described in terms of an Ising model in which interactions beyond nearest-neighbors cannot be neglected. This suggests the presence of short-range order to permit interactions between molecules beyond nearest neighbor that contribute to the formation of largely high spin state domains structure. The formation of a spin state domain structure appears to be the result of extensive cooperative effects. 

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4. Distributed Bayesian Varying Coefficient Modeling Using a Gaussian Process Prior

   Guhaniyogi, R.; Li, C.; Savitsky, T.D.; Srivastava, S. (May 2022, Journal of machine learning research)

   McCulloch, R. (Ed.)

   Varying coefficient models (VCMs) are widely used for estimating nonlinear regression functions for functional data. Their Bayesian variants using Gaussian process priors on the functional coefficients, however, have received limited attention in massive data applications, mainly due to the prohibitively slow posterior computations using Markov chain Monte Carlo (MCMC) algorithms. We address this problem using a divide-and-conquer Bayesian approach. We first create a large number of data subsamples with much smaller sizes. Then, we formulate the VCM as a linear mixed-effects model and develop a data augmentation algorithm for obtaining MCMC draws on all the subsets in parallel. Finally, we aggregate the MCMC-based estimates of subset posteriors into a single Aggregated Monte Carlo (AMC) posterior, which is used as a computationally efficient alternative to the true posterior distribution. Theoretically, we derive minimax optimal posterior convergence rates for the AMC posteriors of both the varying coefficients and the mean regression function. We provide quantification on the orders of subset sample sizes and the number of subsets. The empirical results show that the combination schemes that satisfy our theoretical assumptions, including the AMC posterior, have better estimation performance than their main competitors across diverse simulations and in a real data analysis. 

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5. Reliability Improvement and Effective Switching Layer Model of Thin‐Film MoS ₂ Memristors

   https://doi.org/10.1002/adfm.202214250  

   Huang, Yifu; Gu, Yuqian; Mohan, Sivasakthya; Dolocan, Andrei; Ignacio, Nicholas_D; Kutagulla, Shanmukh; Matthews, Kevin; Londoño‐Calderon, Alejandra; Chang, Yao‐Feng; Chen, Ying‐Chen; et al (April 2023, Advanced Functional Materials)

   Abstract 2D memristors have demonstrated attractive resistive switching characteristics recently but also suffer from the reliability issue, which limits practical applications. Previous efforts on 2D memristors have primarily focused on exploring new material systems, while damage from the metallization step remains a practical concern for the reliability of 2D memristors. Here, the impact of metallization conditions and the thickness of MoS₂films on the reliability and other device metrics of MoS₂‐based memristors is carefully studied. The statistical electrical measurements show that the reliability can be improved to 92% for yield and improved by ≈16× for average DC cycling endurance in the devices by reducing the top electrode (TE) deposition rate and increasing the thickness of MoS₂films. Intriguing convergence of switching voltages and resistance ratio is revealed by the statistical analysis of experimental switching cycles. An “effective switching layer” model compatible with both monolayer and few‐layer MoS₂, is proposed to understand the reliability improvement related to the optimization of fabrication configuration and the convergence of switching metrics. The Monte Carlo simulations help illustrate the underlying physics of endurance failure associated with cluster formation and provide additional insight into endurance improvement with device fabrication optimization. 

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