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1. Strain-driven stabilization of a room-temperature chiral ferroelectric

Author

Ren, Guodong, Jung, Gwan Yeong, Chen, Huandong, Wang, Chong, Zhao, Boyang, Vasudevan, Rama K., Hachtel, Jordan A., Lupini, Andrew R., Chi, Miaofang, Xiao, Di, Ravichandran, Jayakanth, and Mishra, Rohan

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

Noncollinear ferroic materials are sought after as testbeds to explore the intimate connections between topology and symmetry, which result in electronic, optical and magnetic functionalities not observed in collinear ferroic materials. For example, ferroaxial materials have ordered rotational structural distortions that break mirror symmetry and induce chirality. When ferroaxial order is coupled with ferroelectricity arising from a broken inversion symmetry, it offers the prospect of electric-field-control of the ferroaxial distortions and opens up new tunable functionalities. However, chiral ferroelectrics, especially ones stable at room temperature, are rare. We report the discovery of a strain-stabilized, room-temperature chiral ferroelectric phase in single crystals of BaTiS$_3$, a quasi-one-dimensional (1D) hexagonal chalcogenide. Using first-principles calculations, we predict the stabilization of this multiferroic phase having $P6_3$ space group for biaxial tensile strains exceeding 1.5% applied on the basal ab-plane of the room temperature $P6_3cm$ phase of BaTiS$_3$. The chiral ferroelectric phase is characterized by rotational distortions of select TiS$_6$ octahedra around the long $c$-axis and polar displacement of Ti atoms along the $c$-axis. We used an innovative approach using focused ion beam milling to make appropriately strained samples of BaTiS$_3$. The ferroaxial and ferroelectric distortions, and their domains in $P6_3$-BaTiS$_3$ were directly resolved using atomic resolution scanning transmission electron microscopy. Landau-based phenomenological modeling predicts a strong coupling between the ferroelectric and the ferroaxial order making $P6_3$-BaTiS$_3$ an attractive test bed for achieving electric-field control of chirality-related phenomena such as circular photo-galvanic current and the Rashba effect., Comment: 19 pages, 4 figures

Published
2024

2. Ferroelectricity in Hafnia: The Origin of Nanoscale Stabilization

Author

Li, Xin, Ren, Guodong, Lu, Haidong, Samanta, Kartik, Shah, Amit Kumar, Omprakash, Pravan, Yun, Yu, Buragohain, Pratyush, Cao, Huibo, Hachtel, Jordan A., Lupini, Andrew R., Chi, Miaofang, Tsymbal, Evgeny Y., Gruverman, Alexei, Mishra, Rohan, and Xu, Xiaoshan

Subjects
Condensed Matter - Materials Science
Abstract

The discovery of ferroelectricity in hafnia-based materials have boosted the potential of incorporating ferroelectrics in advanced electronics, thanks to their compatibility with silicon technology. However, comprehending why these materials defy the common trend of reduced ferroelectric ordering at the nanoscale, and the mechanism that stabilizes the ferroelectric phase (absent in hafnia phase diagram) presents significant challenges to traditional knowledge of ferroelectricity. In this work, we show that the formation of the orthorhombic ferroelectric phase (o-FE, space group Pca21) of the single-crystalline epitaxial films of 10% La-doped HfO2 (LHO) on (111)-oriented yttria stabilized zirconia (YSZ) relies on the stability of the high-pressure orthorhombic antiferroelectric phase (o-AFE, space group Pbca). Our detailed structural characterizations demonstrate that as-grown LHO films represent largely the o-AFE phase being thermodynamically stabilized by the compressive strain. Our Kelvin probe force microscopy studies show, under mechanical poling, the o-AFE phase is converted to the o-FE phase which remains stable under ambient conditions. We find that the orthorhombic phase stability is enhanced in thinner films down to one-unit-cell thickness, a trend that is unknown in any other ferroelectric films. This is due to the vanishing depolarization field of the o-AFE phase and the isomorphic LHO/YSZ interface, supporting strain-enhanced ferroelectricity in the ultrathin films. This results in an unprecedented increase of the Curie temperature up to 850 {\deg}C, the highest reported for sub-nanometer-thick ferroelectrics. Overall, our findings opens the way for advanced engineering of hafnia-based materials for ferroelectric applications and heralding a new frontier of high-temperature ferroelectrics at the two-dimensional limit.

Published
2024

3. Giant Modulation of Refractive Index from Picoscale Atomic Displacements

Author

Zhao, Boyang, Ren, Guodong, Mei, Hongyan, Wu, Vincent C, Singh, Shantanu, Jung, Gwan Yeong, Chen, Huandong, Giovine, Raynald, Niu, Shanyuan, Thind, Arashdeep S, Salman, Jad, Settineri, Nick S, Chakoumakos, Bryan C, Manley, Michael E, Hermann, Raphael P, Lupini, Andrew R, Chi, Miaofang, Hachtel, Jordan A, Simonov, Arkadiy, Teat, Simon J, Clément, Raphaële J, Kats, Mikhail A, Ravichandran, Jayakanth, and Mishra, Rohan

Subjects
Quantum Physics, Physical Sciences, anisotropy, structural disorder, STEM, DFT, NMR, refractive index, synchrotron diffraction, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

It is shown that structural disorder-in the form of anisotropic, picoscale atomic displacements-modulates the refractive index tensor and results in the giant optical anisotropy observed in BaTiS3, a quasi-1D hexagonal chalcogenide. Single-crystal X-ray diffraction studies reveal the presence of antipolar displacements of Ti atoms within adjacent TiS6 chains along the c-axis, and threefold degenerate Ti displacements in the a-b plane. 47/49Ti solid-state NMR provides additional evidence for those Ti displacements in the form of a three-horned NMR lineshape resulting from a low symmetry local environment around Ti atoms. Scanning transmission electron microscopy is used to directly observe the globally disordered Ti a-b plane displacements and find them to be ordered locally over a few unit cells. First-principles calculations show that the Ti a-b plane displacements selectively reduce the refractive index along the ab-plane, while having minimal impact on the refractive index along the chain direction, thus resulting in a giant enhancement in the optical anisotropy. By showing a strong connection between structural disorder with picoscale displacements and the optical response in BaTiS3, this study opens a pathway for designing optical materials with high refractive index and functionalities such as large optical anisotropy and nonlinearity.

Published
2024

4. Dynamic structural evolution of MgO-supported palladium catalysts: from metal to metal oxide nanoparticles to surface then subsurface atomically dispersed cations

Author

Chen, Yizhen, Rana, Rachita, Zhang, Yizhi, Hoffman, Adam S, Huang, Zhennan, Yang, Bo, Vila, Fernando D, Perez-Aguilar, Jorge E, Hong, Jiyun, Li, Xu, Zeng, Jie, Chi, Miaofang, Kronawitter, Coleman X, Wang, Haiyan, Bare, Simon R, Kulkarni, Ambarish R, and Gates, Bruce C

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Chemical sciences
Abstract

Supported noble metal catalysts, ubiquitous in chemical technology, often undergo dynamic transformations between reduced and oxidized states-which influence the metal nuclearities, oxidation states, and catalytic properties. In this investigation, we report the results of in situ X-ray absorption spectroscopy, scanning transmission electron microscopy, and other physical characterization techniques, bolstered by density functional theory, to elucidate the structural transformations of a set of MgO-supported palladium catalysts under oxidative treatment conditions. As the calcination temperature increased, the as-synthesized supported metallic palladium nanoparticles underwent oxidation to form palladium oxides (at approximately 400 °C), which, at approximately 500 °C, were oxidatively fragmented to form mixtures of atomically dispersed palladium cations. The data indicate two distinct types of atomically dispersed species: palladium cations located at MgO steps and those embedded in the first subsurface layer of MgO. The former exhibit significantly higher (>500 times) catalytic activity for ethylene hydrogenation than the latter. The results pave the way for designing highly active and stable supported palladium hydrogenation catalysts with optimized metal utilization.

Published
2024

5. Probing Lithium Ion Transport at Individual Interfaces

Author

Venkatraman, Kartik, Cheng, Yongqiang, Moy, Alexandra, Hachtel, Jordan A., Zachman, Michael J., Kumar, Abinash, Delaire, Olivier, Sakamoto, Jeff, and Chi, Miaofang

Subjects
Condensed Matter - Materials Science
Abstract

Ion transport across solid solid interfaces is often slower than through the bulk of a material, impeding the charge and discharge rate of batteries. Designing highly conductive interfaces is challenging due to the need to probe ion conduction at individual interfaces and correlate it with the local structure. In this study, we address this challenge by enabling the simultaneous measurements of local Li-dominated optical phonons and ion distributions, using high-energy and high-spatial-resolution spectroscopy in a scanning transmission electron microscope (STEM). Further, this method allows for a direct correlation of ion conduction with interfacial structures identified by STEM imaging. By examining diverse individual interfaces of LiCoO2, we reveal the sensitivity of ion conduction to interface atomic-scale structure and chemistry. Our method enables correlative analysis of ion transport behavior, and atomic and band structures, and can serve as a robust experimental approach for identifying interface structures that offer high conductivity and cyclability for batteries.

Published
2023

6. Orbital degree of freedom in high entropy oxides

Author

Yan, Jiaqiang, Kumar, Abinash, Chi, Miaofang, Brahlek, Matthew, Ward, Thomas Z, and McGuire, Michael

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

The spin, charge, and lattice degrees of freedom and their interplay in high entropy oxides were intensively investigated in recent years. However, how the orbital degree of freedom is affected by the extreme disorder in high entropy oxides hasn't been studied. In this work, using perovskite structured \textit{R}VO$_3$ as a materials playground, we report how the disorder arising from mixing different rare earth ions at the rare earth site affects the orbital ordering of V$^{3+}$ t$_{2g}$-electrons. Since each member of \textit{R}VO$_3$ crystallizes into the same orthorhombic \textit{Pbnm} structure, the configurational entropy should not be critical for the success synthesis of (\textit{R}$_1$,...,\textit{R}$_n$)VO$_3$. The spin and orbital ordering was studied by measuring magnetic properties and specific heat of single crystals. Rather than the number and type of rare earth ions, the average ionic radius and size variance are the key factors determining the spin and orbital order in (\textit{R}$_1$,...,\textit{R}$_n$)VO$_3$. When the size variance is small, the average ionic radius takes precedence in dictating spin and orbital order. Increasing size variance suppresses the G-type orbital order and C-type magnetic order but favors the C-OO/G-AF state and the spin-orbital entanglement. These findings suggest that the extreme disorder introduced by mixing multiple rare earth ions in high entropy perovskites might be employed to preserve the orbital degree of freedom to near the magnetic ordering temperature, which is necessary for the electronic driven orbital ordering in a Kugel-Khomskii compound., Comment: 3 figures, 7 pages

Published
2023

7. Giant Modulation of Refractive Index from Picoscale Atomic Displacements

Author

Zhao, Boyang, Ren, Guodong, Mei, Hongyan, Wu, Vincent C., Singh, Shantanu, Jung, Gwan-Yeong, Chen, Huandong, Giovine, Raynald, Niu, Shanyuan, Thind, Arashdeep S., Salman, Jad, Settineri, Nick S., Chakoumakos, Bryan C., Manley, Michael E., Hermann, Raphael P., Lupini, Andrew R., Chi, Miaofang, Hachtel, Jordan A., Simonov, Arkadiy, Teat, Simon J., Clément, Raphaële J., Kats, Mikhail A., Ravichandran, J., and Mishra, Rohan

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

Structural disorder has been shown to enhance and modulate magnetic, electrical, dipolar, electrochemical, and mechanical properties of materials. However, the possibility of obtaining novel optical and optoelectronic properties from structural disorder remains an open question. Here, we show unambiguous evidence of disorder in the form of anisotropic, picoscale atomic displacements modulating the refractive index tensor and resulting in the giant optical anisotropy observed in BaTiS$_3$, a quasi-one-dimensional hexagonal chalcogenide. Single crystal X-ray diffraction studies reveal the presence of antipolar displacements of Ti atoms within adjacent TiS$_6$ chains along the c-axis, and three-fold degenerate Ti displacements in the a-b plane. $^{47/49}$Ti solid-state NMR provides additional evidence for those Ti displacements in the form of a three-horned NMR lineshape resulting from a low symmetry local environment around Ti atoms. We used scanning transmission electron microscopy to directly observe the globally disordered Ti a-b plane displacements and find them to be ordered locally over a few unit cells. First-principles calculations show that the Ti a-b plane displacements selectively reduce the refractive index along the ab-plane, while having minimal impact on the refractive index along the chain direction, thus resulting in a giant enhancement in the optical anisotropy. By showing a strong connection between structural disorder with picoscale displacements and the optical response in BaTiS$_3$, this study opens a pathway for designing optical materials with high refractive index and functionalities such as large optical anisotropy and nonlinearity., Comment: 24 pages, 3 figures

Published
2023
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8. Simultaneous High-Speed and Low-Dose 4-D STEM Using Compressive Sensing Techniques

Author

Robinson, Alex W., Moshtaghpour, Amirafshar, Wells, Jack, Nicholls, Daniel, Chi, Miaofang, MacLaren, Ian, Kirkland, Angus I., and Browning, Nigel D.

Subjects
Condensed Matter - Materials Science
Abstract

Here we show that compressive sensing allow 4-dimensional (4-D) STEM data to be obtained and accurately reconstructed with both high-speed and low fluence. The methodology needed to achieve these results compared to conventional 4-D approaches requires only that a random subset of probe locations is acquired from the typical regular scanning grid, which immediately generates both higher speed and the lower fluence experimentally. We also consider downsampling of the detector, showing that oversampling is inherent within convergent beam electron diffraction (CBED) patterns, and that detector downsampling does not reduce precision but allows faster experimental data acquisition. Analysis of an experimental atomic resolution yttrium silicide data-set shows that it is possible to recover over 25dB peak signal-to-noise in the recovered phase using 0.3% of the total data.

Published
2023

9. Colossal Optical Anisotropy from Atomic‐Scale Modulations

Author

Mei, Hongyan, Ren, Guodong, Zhao, Boyang, Salman, Jad, Jung, Gwan Yeong, Chen, Huandong, Singh, Shantanu, Thind, Arashdeep S, Cavin, John, Hachtel, Jordan A, Chi, Miaofang, Niu, Shanyuan, Joe, Graham, Wan, Chenghao, Settineri, Nick, Teat, Simon J, Chakoumakos, Bryan C, Ravichandran, Jayakanth, Mishra, Rohan, and Kats, Mikhail A

Subjects
Quantum Physics, Physical Sciences, birefringence, chalcogenides, optical anisotropy, structural modulation, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Materials with large birefringence (Δn, where n is the refractive index) are sought after for polarization control (e.g., in wave plates, polarizing beam splitters, etc.), nonlinear optics, micromanipulation, and as a platform for unconventional light-matter coupling, such as hyperbolic phonon polaritons. Layered 2D materials can feature some of the largest optical anisotropy; however, their use in most optical systems is limited because their optical axis is out of the plane of the layers and the layers are weakly attached. This work demonstrates that a bulk crystal with subtle periodic modulations in its structure-Sr9/8 TiS3 -is transparent and positive-uniaxial, with extraordinary index ne = 4.5 and ordinary index no = 2.4 in the mid- to far-infrared. The excess Sr, compared to stoichiometric SrTiS3 , results in the formation of TiS6 trigonal-prismatic units that break the chains of face-sharing TiS6 octahedra in SrTiS3 into periodic blocks of five TiS6 octahedral units. The additional electrons introduced by the excess Sr form highly oriented electron clouds, which selectively boost the extraordinary index ne and result in record birefringence (Δn > 2.1 with low loss). The connection between subtle structural modulations and large changes in refractive index suggests new categories of anisotropic materials and also tunable optical materials with large refractive-index modulation.

Published
2023

10. Stacking disorder and thermal transport properties of $\alpha$-RuCl$_3$

Author

Zhang, Heda, McGuire, Michael A, May, Andrew F, Chao, Joy, Zheng, Qiang, Chi, Miaofang, Sales, Brian C, Mandrus, David G, Nagler, Stephen E, Miao, Hu, Ye, Feng, and Yan, Jiaqiang

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

$\alpha$-RuCl$_3$, a well-known candidate material for Kitaev quantum spin liquid, is prone to stacking disorder due to the weak van der Waals bonding between the honeycomb layers. After a decade of intensive experimental and theoretical studies, the detailed correlation between stacking degree of freedom, structure transition, magnetic and thermal transport properties remains unresolved. In this work, we reveal the effects of a small amount of stacking disorder inherent even in high quality $\alpha$-RuCl$_3$ crystals. This small amount of stacking disorder results in the variation of the magnetic ordering temperature, suppresses the structure transition and thermal conductivity. Crystals with minimal amount of stacking disorder have a T$_N>$7.4\,K and exhibit a well-defined structure transition around 140\,K upon cooling. For those with more stacking faults and a T$_N$ below 7\,K, the structure transition occurs well below 140\,K upon cooling and is incomplete, manifested by the diffuse streaks and the coexistence of both high temperature and low temperature phases down to the lowest measurement temperature. Both types of crystals exhibit oscillatory field dependent thermal conductivity and a plateau-like feature in thermal Hall resistivity in the field-induced quantum spin liquid state. However, $\alpha$-RuCl$_3$ crystals with minimal amount of stacking disorder have a higher thermal conductivity that pushes the thermal Hall conductivity to be closer to the half-integer quantized value. These findings demonstrate a strong correlation between layer stacking, structure transition, magnetic and thermal transport properties, underscoring the importance of interlayer coupling in $\alpha$-RuCl$_3$ despite the weak van der Waals bonding.

Published
2023
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11. Machine-learning-assisted material discovery of oxygen-rich highly porous carbon active materials for aqueous supercapacitors.

Author

Wang, Tao, Pan, Runtong, Martins, Murillo, Cui, Jinlei, Huang, Zhennan, Thapaliya, Bishnu, Do-Thanh, Chi-Linh, Zhou, Musen, Fan, Juntian, Yang, Zhenzhen, Chi, Miaofang, Kobayashi, Takeshi, Mamontov, Eugene, Dai, Sheng, and Wu, Jianzhong

Abstract

Porous carbons are the active materials of choice for supercapacitor applications because of their power capability, long-term cycle stability, and wide operating temperatures. However, the development of carbon active materials with improved physicochemical and electrochemical properties is generally carried out via time-consuming and cost-ineffective experimental processes. In this regard, machine-learning technology provides a data-driven approach to examine previously reported research works to find the critical features for developing ideal carbon materials for supercapacitors. Here, we report the design of a machine-learning-derived activation strategy that uses sodium amide and cross-linked polymer precursors to synthesize highly porous carbons (i.e., with specific surface areas > 4000 m2/g). Tuning the pore size and oxygen content of the carbonaceous materials, we report a highly porous carbon-base electrode with 0.7 mg/cm2 of electrode mass loading that exhibits a high specific capacitance of 610 F/g in 1 M H2SO4. This result approaches the specific capacitance of a porous carbon electrode predicted by the machine learning approach. We also investigate the charge storage mechanism and electrolyte transport properties via step potential electrochemical spectroscopy and quasielastic neutron scattering measurements.

Published
2023

12. A stable atmospheric-pressure plasma for extreme-temperature synthesis

Author

Xie, Hua, Liu, Ning, Zhang, Qian, Zhong, Hongtao, Guo, Liqun, Zhao, Xinpeng, Li, Daozheng, Liu, Shufeng, Huang, Zhennan, Lele, Aditya Dilip, Brozena, Alexandra H., Wang, Xizheng, Song, Keqi, Chen, Sophia, Yao, Yan, Chi, Miaofang, Xiong, Wei, Rao, Jiancun, Zhao, Minhua, Shneider, Mikhail N., Luo, Jian, Zhao, Ji-Cheng, Ju, Yiguang, and Hu, Liangbing

Published
2023
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13. Atomically Dispersed Platinum in Surface and Subsurface Sites on MgO Have Contrasting Catalytic Properties for CO Oxidation

Author

Chen, Yizhen, Rana, Rachita, Huang, Zhennan, Vila, Fernando D, Sours, Tyler, Perez-Aguilar, Jorge E, Zhao, Xiao, Hong, Jiyun, Hoffman, Adam S, Li, Xu, Shang, Chunyan, Blum, Thomas, Zeng, Jie, Chi, Miaofang, Salmeron, Miquel, Kronawitter, Coleman X, Bare, Simon R, Kulkarni, Ambarish R, and Gates, Bruce C

Subjects
Chemical Sciences, Physical Sciences, Chemical sciences, Physical sciences
Abstract

Atomically dispersed metals on metal oxide supports are a rapidly growing class of catalysts. Developing an understanding of where and how the metals are bonded to the supports is challenging because support surfaces are heterogeneous, and most reports lack a detailed consideration of these points. Herein, we report two atomically dispersed CO oxidation catalysts having markedly different metal-support interactions: platinum in the first layer of crystalline MgO powder and platinum in the second layer of this support. Structural models have been determined on the basis of data and computations, including those determined by extended X-ray absorption fine structure and X-ray absorption near edge structure spectroscopies, infrared spectroscopy of adsorbed CO, and scanning transmission electron microscopy. The data demonstrate the transformation of surface to subsurface platinum as the temperature of sample calcination increased. Catalyst performance data demonstrate the lower activity but greater stability of the subsurface platinum than of the surface platinum.

Published
2022

14. Multi-principal elemental intermetallic nanoparticles synthesized via a disorder-to-order transition

Author

Cui, Mingjin, Yang, Chunpeng, Hwang, Sooyeon, Yang, Menghao, Overa, Sean, Dong, Qi, Yao, Yonggang, Brozena, Alexandra H, Cullen, David A, Chi, Miaofang, Blum, Thomas F, Morris, David, Finfrock, Zou, Wang, Xizheng, Zhang, Peng, Goncharov, Vitaliy G, Guo, Xiaofeng, Luo, Jian, Mo, Yifei, Jiao, Feng, and Hu, Liangbing

Subjects
Nanotechnology, Bioengineering
Abstract

Nanoscale multi-principal element intermetallics (MPEIs) may provide a broad and tunable compositional space of active, high-surface area materials with potential applications such as catalysis and magnetics. However, MPEI nanoparticles are challenging to fabricate because of the tendency of the particles to grow/agglomerate or phase-separated during annealing. Here, we demonstrate a disorder-to-order phase transition approach that enables the synthesis of ultrasmall (4 to 5 nm) and stable MPEI nanoparticles (up to eight elements). We apply just 5 min of Joule heating to promote the phase transition of the nanoparticles into L10 intermetallic structure, which is then preserved by rapidly cooling. This disorder-to-order transition results in phase-stable nanoscale MPEIs with compositions (e.g., PtPdAuFeCoNiCuSn), which have not been previously attained by traditional synthetic methods. This synthesis strategy offers a new paradigm for developing previously unexplored MPEI nanoparticles by accessing a nanoscale-size regime and novel compositions with potentially broad applications.

Published
2022

15. Neutron diffraction study of magnetism in van der Waals layered MnBi$_{2n}$Te$_{3n+1}$

Author

Ding, Lei, Hu, Chaowei, Feng, Erxi, Jiang, Chenyang, Kibalin, Iurii A., Gukasov, Arsen, Chi, MiaoFang, Ni, Ni, and Cao, Huibo

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

Two-dimensional van der Waals MnBi$_{2n}$Te$_{3n+1}$ (n = 1, 2, 3, 4) compounds have been recently found to be intrinsic magnetic topological insulators rendering quantum anomalous Hall effect and diverse topological states. Here, we summarize and compare the crystal and magnetic structures of this family, and discuss the effects of chemical composition on their magnetism. We found that a considerable fraction of Bi occupies at the Mn sites in MnBi$_{2n}$Te$_{3n+1}$ (n = 1, 2, 3, 4) while Mn is no detectable at the non-magnetic atomic sites within the resolution of neutron diffraction experiments. The occupancy of Mn monotonically decreases with the increase of n. The polarized neutron diffraction on the representative MnBi$_{4}$Te$_{7}$ reveals that its magnetization density is exclusively accumulated at the Mn site, in good agreement with the results from the unpolarized neutron diffraction. The defects of Bi at the Mn site naturally explain the continuously reduced saturated magnetic moments from n = 1 to n = 4. The experimentally estimated critical exponents of all the compounds generally suggest a three-dimensional character of magnetism. Our work provides material-specified structural parameters that may be useful for band structure calculations to understand the observed topological surface states and for designing quantum magnetic materials through chemical doping., Comment: 5 figures, typos corrected

Published
2020

16. Interferometric 4D-STEM for Lattice Distortion and Interlayer Spacing Measurements in Bilayer and Trilayer Two-dimensional Materials

Author

Zachman, Michael J, Madsen, Jacob, Zhang, Xiang, Ajayan, Pulickel M, Susi, Toma, and Chi, Miaofang

Subjects
Condensed Matter - Materials Science
Abstract

Van der Waals materials composed of stacks of individual atomic layers have attracted considerable attention due to their exotic electronic properties that can be altered by, for example, manipulating the twist angle of bilayer materials or the stacking sequence of trilayer materials. To fully understand and control the unique properties of these few-layer materials, a technique that can provide information about their local in-plane structural deformations, twist direction, and out-of-plane structure is needed. In principle, interference in overlap regions of Bragg disks originating from separate layers of a material encodes three-dimensional information about the relative positions of atoms in the corresponding layers. Here, we describe an interferometric four-dimensional scanning transmission electron microscopy technique that utilizes this phenomenon to extract precise structural information from few-layer materials with nm-scale resolution. We demonstrate how this technique enables measurement of local pm-scale in-plane lattice distortions as well as twist direction and average interlayer spacings in bilayer and trilayer graphene, and therefore provides a means to better understand the interplay between electronic properties and precise structural arrangements of few-layer 2D materials.

Published
2020
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17. Site Mixing for Engineering Magnetic Topological Insulators

Author

Liu, Yaohua, Wang, Lin-Lin, Zheng, Qiang, Huang, Zengle, Wang, Xiaoping, Chi, Miaofang, Wu, Yan, Chakoumakos, Bryan C., McGuire, Michael A., Sales, Brian C., Wu, Weida, and Yan, Jiaqiang

Subjects
Condensed Matter - Materials Science, Quantum Physics
Abstract

The van der Waals compound, MnBi$_2$Te$_4$, is the first intrinsic magnetic topological insulator, providing a materials platform for exploring exotic quantum phenomena such as the axion insulator state and the quantum anomalous Hall effect. However, intrinsic structural imperfections lead to bulk conductivity, and the roles of magnetic defects are still unknown. With higher concentrations of same types of magnetic defects, the isostructural compound MnSb$_2$Te$_4$ is a better model system for a systematic investigation of the connections among magnetic, topology and lattice defects. In this work, the impact of antisite defects on the magnetism and electronic structure is studied in MnSb$_2$Te$_4$. Mn-Sb site mixing leads to complex magnetic structures and tunes the interlayer magnetic coupling between antiferromagnetic and ferromagnetic. The detailed nonstoichiometry and site-mixing of MnSb$_2$Te$_4$ crystals depend on the growth parameters, which can lead to $\approx$40\% of Mn sites occupied by Sb and $\approx$15\% of Sb sites by Mn in as-grown crystals. Single crystal neutron diffraction and electron microscopy studies show nearly random distribution of the antisite defects. Band structure calculations suggest that the Mn-Sb site-mixing favors a FM interlayer coupling, consistent with experimental observation, but is detrimental to the band inversion required for a nontrivial topology. Our results suggest a long range magnetic order of Mn ions sitting on Bi sites in MnBi$_2$Te$_4$. The effects of site mixing should be considered in all layered heterostructures that consist of alternating magnetic and topological layers, including the entire family of MnTe(Bi$_2$Te$_3$)$_n$, its Sb analogs and their solid solution., Comment: The effects of Mn/Sb antisite mixing on the magnetic structure (experiment) and band topology (theory) in the van der Waals magnet MnSb$_2$Te$_4$. PRX in press

Published
2020
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18. Extreme mixing in nanoscale transition metal alloys

Author

Yao, Yonggang, Huang, Zhennan, Hughes, Lauren A, Gao, Jinlong, Li, Tangyuan, Morris, David, Zeltmann, Steven Eric, Savitzky, Benjamin H, Ophus, Colin, Finfrock, Y Zou, Dong, Qi, Jiao, Miaolun, Mao, Yimin, Chi, Miaofang, Zhang, Peng, Li, Ju, Minor, Andrew M, Shahbazian-Yassar, Reza, and Hu, Liangbing

Abstract

The ability to alloy different elements is critical for property tuning and materials discovery. However, general alloying at the nanoscale remains extremely challenging due to strong immiscibility and easy oxidation, particularly for early transition metals that are highly reactive. Here, we report nanoscale alloying using a high-temperature- and high-entropy-based strategy (T∗ΔSmix) to significantly expand the possible alloys and include early transition metals. While high-temperature synthesis favors alloy formation and metal reduction, the high-entropy compositional design is critical to further extending the alloying to strongly repelling combinations (e.g., Au-W) and easily oxidized elements (e.g., Zr). In particular, we explicitly characterized a record 15-element nanoalloy, which showed a solid-solution structure featuring localized strain and lattice distortions as a result of extreme mixing. Our study significantly broadens available compositions of nanoalloys and provides clear guidelines by utilizing the less-explored entropic chemistry.

Published
2021

20. Atomistic insights into the nucleation and growth of platinum on palladium nanocrystals

Author

Gao, Wenpei, Elnabawy, Ahmed O, Hood, Zachary D, Shi, Yifeng, Wang, Xue, Roling, Luke T, Pan, Xiaoqing, Mavrikakis, Manos, Xia, Younan, and Chi, Miaofang

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences
Abstract

Despite the large number of reports on colloidal nanocrystals, very little is known about the mechanistic details in terms of nucleation and growth at the atomistic level. Taking bimetallic core-shell nanocrystals as an example, here we integrate in situ liquid-cell transmission electron microscopy with first-principles calculations to shed light on the atomistic details involved in the nucleation and growth of Pt on Pd cubic seeds. We elucidate the roles played by key synthesis parameters, including capping agent and precursor concentration, in controlling the nucleation site, diffusion path, and growth pattern of the Pt atoms. When the faces of a cubic seed are capped by Br-, Pt atoms preferentially nucleate from corners and then diffuse to edges and faces for the creation of a uniform shell. The diffusion does not occur until the Pt deposited at the corner has reached a threshold thickness. At a high concentration of the precursor, self-nucleation takes place and the Pt clusters then randomly attach to the surface of a seed for the formation of a non-uniform shell. These atomistic insights offer a general guideline for the rational synthesis of nanocrystals with diverse compositions, structures, shapes, and related properties.

Published
2021

23. Nanoscale Interlayer Defects in Iron Arsenides

Author

Zheng, Qiang, Chi, Miaofang, Ziatdinov, Maxim, Li, 2 Li, Maksymovych, Petro, Chisholm, Matt F., Kalinin, 1 Sergei V., and Sefat, Athena S.

Subjects
Condensed Matter - Superconductivity
Abstract

Using a local real-space microscopy probe, we discover evidence of nanoscale interlayer defects along the c-crystallographic direction in BaFe2As2 (122) based iron-arsenide superconductors. We find ordered 122 atomic arrangements within the ab-plane, and within regions of ~10 to 20 nm size perpendicular to this plane. While the FeAs substructure is very rigid, Ba ions are relatively weakly bound and can be displaced from the 122, forming stacking faults resulting in the physical separation of the 122 between adjacent ordered domains. The evidence for interlayer defects between the FeAs superconducting planes gives perspective on the minimal connection between interlayer chemical disorder and high-temperature superconductivity. In particular, the Cooper pairs may be finding a way around such localized interlayer defects through a percolative path of the ordered layered 122 lattice that may not affect Tc.

Published
2019
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26. Antisite pairs suppress the thermal conductivity of BAs

Author

Zheng, Qiang, Polanco, Carlos A., Du, Mao-Hua, Lindsay, Lucas R., Chi, Miaofang, Yan, Jiaqiang, and Sales, Brian C.

Subjects
Condensed Matter - Materials Science
Abstract

BAs was predicted to have an unusually high thermal conductivity at room temperature of 2000$\,$Wm$^{-1}$$\,$K$^{-1}$, comparable to that of diamond. However, the experimentally measured thermal conductivity of BAs single crystals is an order of magnitude lower. To identify the origin of this large inconsistency, we investigated the lattice structure and potential defects in BAs single crystals at atomic scale using aberration-corrected scanning transmission electron microscopy (STEM). Rather than finding a large concentration As vacancies ($V_\mathrm{As}$), as widely thought to dominate the thermal resistance in BAs crystals, our STEM results showed enhanced intensity of some B columns and reduced intensity of some As columns, suggesting the presence of antisite defects with As$_\mathrm{B}$ (As-atom on B site) and B$_\mathrm{As}$ (B-atom on As site) with significant concentrations. Further calculations show that the antisite pair with As$_\mathrm{B}$ next to B$_\mathrm{As}$ is preferred energetically among the different types of point defects investigated, and confirm that such defects lower the thermal conductivity for BAs. Using a concentration of 6.6$\pm$3$\times$10$^{20}$$\,$cm$^{-3}$ for the antisite pairs estimated from STEM images, thermal conductivity is estimated to be 65-100$\,$Wm$^{-1}$$\,$K$^{-1}$, in reasonable agreement with our measured value. Our study suggests that As$_\mathrm{B}$-B$_\mathrm{As}$ antisite pairs are the primary lattice defects suppressing thermal conductivity of BAs. Possible approaches are proposed for growth of high quality crystals or films with high thermal conductivity., Comment: 4 pages and 3 figures in main text; 4 pages and 4 figures in the Supplementary Material

Published
2018
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31. The Key Role of Grain Boundary Dynamics in Revolutionizing the Potential of Solid Electrolytes.

Author

Wang, Yangyang, Thomas, Charlotte, Garman, Kaitlin, Kim, Hwangsun, Chen, Zonghai, Chi, Miaofang, and Ban, Chunmei

Subjects
CONDUCTIVITY of electrolytes, CRYSTAL grain boundaries, IONIC conductivity, SOLID electrolytes, DIELECTRIC breakdown
Abstract

Solid electrolytes (SEs) have the potential to enhance the safety and performance of Li‐metal batteries. However, the existence of grain boundaries in polycrystalline SEs presents a significant challenge for both ionic and electronic migration, promoting the propagation of detrimental lithium dendrites. This study compares the roles of grain boundaries in electrical properties of three distinct SEs including garnet‐type Li6.5La3Zr1.5Ta0.5O12 (LLZO), argyrodite‐type Li6PS5Cl (LPSC), and NASICON‐type Li1+x+yAlx(Ti,Ge)2‐xSiyP3‐yO12 (LATP). Results demonstrate that the electronic and ionic conductivities of solid‐state electrolytes are affected differently by grain boundaries, depending on the specific type of electrolyte. For instance, LLZO and LATP experience dielectric breakdown at 3.7 and 5.3 V, respectively, while LPSC does not exhibit such behavior. Here, a new chemical modification is proposed that simultaneously alters the composition of both the surface and grain boundaries of SEs, ultimately reducing electronic conductivity for the LLZO SEs. Consequently, the proposed LLZO exhibits unprecedented dendrite‐free cycling stability, achieving a remarkable 12 000‐h lifetime at room temperature, surpassing conventional strategies such as surface coatings in dendrite mitigation. This study highlights the significance of modifying grain boundaries to design safe and durable Li‐metal batteries. It provides new insights for developing SEs that are highly resistant to dendrite formation. [ABSTRACT FROM AUTHOR]

Published
2024
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33. High‐speed 4‐dimensional scanning transmission electron microscopy using compressive sensing techniques.

Author

Robinson, Alex W., Moshtaghpour, Amirafshar, Wells, Jack, Nicholls, Daniel, Chi, Miaofang, MacLaren, Ian, Kirkland, Angus I., and Browning, Nigel D.

Subjects
SCANNING transmission electron microscopy, ELECTRON beams, DIFFRACTION patterns, ACQUISITION of data, YTTRIUM
Abstract

Here we show that compressive sensing allows 4‐dimensional (4‐D) STEM data to be obtained and accurately reconstructed with both high‐speed and reduced electron fluence. The methodology needed to achieve these results compared to conventional 4‐D approaches requires only that a random subset of probe locations is acquired from the typical regular scanning grid, which immediately generates both higher speed and the lower fluence experimentally. We also consider downsampling of the detector, showing that oversampling is inherent within convergent beam electron diffraction (CBED) patterns and that detector downsampling does not reduce precision but allows faster experimental data acquisition. Analysis of an experimental atomic resolution yttrium silicide dataset shows that it is possible to recover over 25 dB peak signal‐to‐noise ratio in the recovered phase using 0.3% of the total data. Lay abstract: Four‐dimensional scanning transmission electron microscopy (4‐D STEM) is a powerful technique for characterizing complex nanoscale structures. In this method, a convergent beam electron diffraction pattern (CBED) is acquired at each probe location during the scan of the sample. This means that a 2‐dimensional signal is acquired at each 2‐D probe location, equating to a 4‐D dataset. Despite the recent development of fast direct electron detectors, some capable of 100kHz frame rates, the limiting factor for 4‐D STEM is acquisition times in the majority of cases, where cameras will typically operate on the order of 2kHz. This means that a raster scan containing 256^2 probe locations can take on the order of 30s, approximately 100‐1000 times longer than a conventional STEM imaging technique using monolithic radial detectors. As a result, 4‐D STEM acquisitions can be subject to adverse effects such as drift, beam damage, and sample contamination. Recent advances in computational imaging techniques for STEM have allowed for faster acquisition speeds by way of acquiring only a random subset of probe locations from the field of view. By doing this, the acquisition time is significantly reduced, in some cases by a factor of 10‐100 times. The acquired data is then processed to fill‐in or inpaint the missing data, taking advantage of the inherently low‐complex signals which can be linearly combined to recover the information. In this work, similar methods are demonstrated for the acquisition of 4‐D STEM data, where only a random subset of CBED patterns are acquired over the raster scan. We simulate the compressive sensing acquisition method for 4‐D STEM and present our findings for a variety of analysis techniques such as ptychography and differential phase contrast. Our results show that acquisition times can be significantly reduced on the order of 100‐300 times, therefore improving existing frame rates, as well as further reducing the electron fluence beyond just using a faster camera. [ABSTRACT FROM AUTHOR]

Published
2024
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35. In situ TEM observation of the electrochemical lithiation of N-doped anatase TiO2 nanotubes as anodes for lithium-ion batteries

Author

Zhang, Minghao, Yin, Kuibo, Hood, Zachary D, Bi, Zhonghe, Bridges, Craig A, Dai, Sheng, Meng, Ying Shirley, Paranthaman, Mariappan Parans, and Chi, Miaofang

Subjects
Macromolecular and Materials Chemistry
Abstract

The effects of N-doping and the lithiation mechanism of TiO2 nanotubes were elucidated by integrated in situ microscopy and electrochemical measurements.

Published
2017

36. Self-Assembled Framework Formed During Lithiation of SnS2 Nanoplates Revealed by in Situ Electron Microscopy

Author

Yin, Kuibo, Zhang, Minghao, Hood, Zachary D, Pan, Jie, Meng, Ying Shirley, and Chi, Miaofang

Subjects
Affordable and Clean Energy, Chemical Sciences, General Chemistry
Abstract

Lithium-ion batteries (LIBs) commercially dominate portable energy storage and have been extended to hybrid/electric vehicles by utilizing electrode materials with enhanced energy density. However, the energy density and cycling life of LIBs must extend beyond the current reach of commercial electrodes to meet the performance requirements for transportation applications. Carbon-based anodes, serving as the main negative electrodes in LIBs, have an intrinsic capacity limitation due to the intercalation mechanism. Some nanostructured carbon materials offer very interesting reversible capacities and can be considered as future anode materials. However, their fabrication processes are often complicated and expensive. Theoretically, using a lithium metal anode is the best way of delivering high energy density due to its largest theoretical capacity of more than 3800 mAh g-1; however, lithium metal is highly reactive with liquid electrolytes. Alternative anodes are being explored, including other lithium-reactive metals, such as Si, Ge, Zn, V, and so forth. These metals react reversibly with a large amount of Li per formula unit to form lithium-metal alloys, rendering these materials promising candidates for next-generation LIBs with high energy density. Though, most of these pure metallic anodes experience large volume changes during lithiation and delithiation processes that often results in cracking of the anode material and a loss electrical contact between the particles. Nanosized metal sulfides were recently found to possess better cycling stability and larger reversible capacities over pure metals. Further improvements and developments of metal sulfide-based anodes rely on a fundamental understanding of their electrochemical cycling mechanisms. Not only must the specific electrochemical reactions be correctly identified, but also the microstructural evolution upon electrochemical cycling, which often dictates the cyclability and stability of nanomaterials in batteries, must be clearly understood. Probing these dynamic evolution processes, i.e. the lithiation reactions and morphology evolutions, are often challenging. It requires both high-resolution chemical analysis and microstructural identification. In situ transmission electron microscopy (TEM) coupled with electron energy loss spectroscopy (EELS) has recently been raised as one of the most powerful techniques for monitoring electrochemical processes in anode materials for LIBs. In this work, we focus on elucidating the origin of the structural stability of SnS2 during electrochemical cycling by revealing the microstructural evolution of SnS2 upon lithiation using in situ TEM. Crystalline SnS2 was observed to undergo a two-step reaction after the initial lithium intercalation: (1) irreversible formation of metallic tin and amorphous lithium sulfide and (2) reversible transformation of metallic tin to Li-Sn alloys, which is determined to be the rate-determining step. More interestingly, it was discovered that a self-assembled composite framework formed during the irreversible conversion reaction, which has not been previously reported. Crystalline Sn nanoparticles are well arranged within an amorphous Li2S "matrix" in this self-assembled framework. This nanoscale framework confines the locations of individual Sn nanoparticles and prevents particle agglomeration during the subsequent cycling processes, therefore providing desired structural tolerance and warranting a sufficientelectron pathway. Our results not only explain the outstanding cycling stability of SnS2 over metallic tin anodes, but also provide important mechanistic insights into the design of high-performance electrodes for next-generation LIBs through the integration of a unique nanoframework.

Published
2017

37. In situ TEM observation of the electrochemical lithiation of N-doped anatase TiO 2 nanotubes as anodes for lithium-ion batteries

Author

Zhang, Minghao, Yin, Kuibo, Hood, Zachary D, Bi, Zhonghe, Bridges, Craig A, Dai, Sheng, Meng, Ying Shirley, Paranthaman, Mariappan Parans, and Chi, Miaofang

Subjects
Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Chemical engineering, Materials engineering
Abstract

The effects of N-doping and the lithiation mechanism of TiO2 nanotubes were elucidated by integrated in situ microscopy and electrochemical measurements.

Published
2017

38. Dynamic Behavior of Pt Multimetallic Alloys for Active and Stable Propane Dehydrogenation Catalysts

Author

Werghi, Baraa, Saini, Shikha, Chung, Pin-Hung, Kumar, Abinash, Ebrahim, Amani M., Abels, Kristen, Chi, Miaofang, Abild-Pedersen, Frank, Bare, Simon R., and Cargnello, Matteo

Abstract

Improving the use of platinum in propane dehydrogenation catalysts is a crucial aspect to increasing the efficiency and sustainability of propylene production. A known and practiced strategy involves incorporating more abundant metals in supported platinum catalysts, increasing its activity and stability while decreasing the overall loading. Here, using colloidal techniques to control the size and composition of the active phase, we show that Pt/Cu alloy nanoparticles supported on alumina (Pt/Cu/Al2O3) displayed elevated rates for propane dehydrogenation at low temperature compared to a monometallic Pt/Al2O3catalyst. We demonstrate that the enhanced catalytic activity is correlated with a higher surface Cu content and formation of a Pt-rich core and Cu-rich shell that isolates Pt sites and increases their intrinsic activity. However, rates declined on stream because of dynamic metal diffusion processes that led to a more uniform alloy structure. This transformation was only partially inhibited by adding excess hydrogen to the feed stream. Instead, cobalt was introduced to provide trimetallic Pt/Cu/Co catalysts with stabilized surface structure and stable activity and higher rates than the original Pt/Cu system. The structure–activity relationship insights in this work offer improved knowledge of propane dehydrogenation catalyst development featuring reduced Pt loadings and notable thermal stability for propylene production.

Published
2024
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39. Metallicity of Ca2Cu6P5 with Single and Double Copper-Pnictide Layers

Author

Li, Li, Parker, David, Chi, Miaofang, Tsoi, Georgiy M., Vohra, Yogesh K., and Sefat, Athena S.

Subjects
Condensed Matter - Superconductivity
Abstract

We report thermodynamic and transport properties, and also theoretical calculations, for Cu-based compound Ca2Cu6P5 and compare with CaCu(2-x)P2. Both materials have layers of edge-sharing copper pnictide tetrahedral CuP4, similar to Fe-As and Fe-Se layers (with FeAs4, FeSe4) in the iron-based superconductors. Despite the presence of this similar transition-metal pnictide layer, we find that both Ca2Cu6P5 and CaCu(2-x)P2 have temperature-independent magnetic susceptibility and show metallic behavior with no evidence of either magnetic ordering or superconductivity down to 1.8 K. CaCu(2-x)P2 is slightly off-stoichiometric, with delta = 0.14. Theoretical calculations suggest that unlike Fe 3d-based magnetic materials with a large density of states (DOS) at the Fermi surface, Cu have comparatively low DOS, with the majority of the 3d spectral weight located well below Fermi level. The room-temperature resistivity value of Ca2Cu6P5 is only 9 micro ohm-cm, due to a substantial plasma frequency and an inferred electron-phonon coupling lambda of 0.073 (significantly smaller than that of metallic Cu). Also, microscopy result shows that Cu-Cu distance along the c-axis within the double layers can be very short (2.5 A), even shorter than metallic elemental copper bond (2.56 A). The value of dp over dT for CaCu(2-x)P2 at 300 K is approximately three times larger than in Ca2Cu6P5, which suggests the likelihood of stronger electron-phonon coupling. This study shows that the details of Cu-P layers and bonding are important for their transport characteristics. In addition, it emphasizes the remarkable character of the DOS of '122' iron-based materials, despite much structural similarities., Comment: 13 pages, 5 figures

Published
2015
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47. Stacking disorder and thermal transport properties of α−RuCl3

Author

Zhang, Heda, primary, McGuire, Michael A., additional, May, Andrew F., additional, Chao, Hsin-Yun, additional, Zheng, Qiang, additional, Chi, Miaofang, additional, Sales, Brian C., additional, Mandrus, David G., additional, Nagler, Stephen E., additional, Miao, Hu, additional, Ye, Feng, additional, and Yan, Jiaqiang, additional

Published
2024
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