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1. Lattice-Matched Multiple Channel AlScN/GaN Heterostructures

Author

Nguyen, Thai-Son, Pieczulewsi, Naomi, Savant, Chandrashekhar, Cooper, Joshua J. P., Casamento, Joseph, Goldman, Rachel S., Muller, David A., Xing, Huili G., and Jena, Debdeep

Subjects
Condensed Matter - Materials Science
Abstract

AlScN is a new wide bandgap, high-k, ferroelectric material for RF, memory, and power applications. Successful integration of high quality AlScN with GaN in epitaxial layer stacks depends strongly on the ability to control lattice parameters and surface or interface through growth. This study investigates the molecular beam epitaxy growth and transport properties of AlScN/GaN multilayer heterostructures. Single layer Al$_{1-x}$Sc$_x$N/GaN heterostructures exhibited lattice-matched composition within $x$ = 0.09 -- 0.11 using substrate (thermocouple) growth temperatures between 330 $ ^\circ$C and 630 $ ^\circ$C. By targeting the lattice-matched Sc composition, pseudomorphic AlScN/GaN multilayer structures with ten and twenty periods were achieved, exhibiting excellent structural and interface properties as confirmed by X-ray diffraction (XRD) and scanning transmission electron microscopy (STEM). These multilayer heterostructures exhibited substantial polarization-induced net mobile charge densities of up to 8.24 $\times$ 10$^{14}$/cm$^2$ for twenty channels. The sheet density scales with the number of AlScN/GaN periods. By identifying lattice-matched growth condition and using it to generate multiple conductive channels, this work enhances our understanding of the AlScN/GaN material platform.

Published
2024
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2. Defect Landscape Engineering to Tune Skyrmion-Antiskyrmion Systems in FeGe

Author

Liu, Jiangteng, Schoell, Ryan, Zhang, Xiyue S., Yang, Hongbin, Venuti, M. B., Paik, Hanjong, Muller, David A., Lu, Tzu-Ming, Hattar, Khalid, and Eley, Serena

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

A promising architecture for next-generation, low energy spintronic devices uses skyrmions -- nanoscale whirlpools of magnetic moment -- as information carriers. Notably, schemes for racetrack memory have been proposed in which skyrmions and antiskyrmions, their antiparticle, serve as the logical bits 1 and 0. However, major challenges exist to designing skyrmion-antiskyrmion based computing. The presence of both particles in one material is often mutually exclusive such that few systems have been identified in which they coexist, and in these systems their appearance is stochastic rather than deterministic. Here, we create a tunable skyrmion-antiskyrmion system in FeGe films through ion-irradiation and annealing, and detail the structural properties of the films under these various conditions. Specifically, we irradiate epitaxial B20-phase FeGe films with 2.8 MeV Au$^{4+}$ ions, showing evidence that the amorphized regions preferentially host antiskyrmions at densities controlled by the irradiation fluence. In this work, we focus on a subsequent, systematic electron diffraction study with in-situ annealing, demonstrating the ability to recrystallize controllable fractions of the material at temperatures ranging from approximately 150$^{\circ}$ C to 250$^{\circ}$ C, enabling further tunability of skyrmion/antiskyrmion populations. We describe the crystallization kinetics using the Johnson-Mehl-Avrami-Kolmogorov model, finding that growth of crystalline grains is consistent with diffusion-controlled one-to-two dimensional growth with a decreasing nucleation rate. The procedures developed here can be applied towards creation of skyrmion-antiskyrmion systems for energy-efficient, high-density data storage, spin wave emission produced by skyrmion-antiskyrmion pair annihilation, and more generally testbeds for research on skyrmion-antiskyrmion liquids and crystals.

Published
2024

4. Electron ptychography reveals a ferroelectricity dominated by anion displacements

Author

P., Harikrishnan K., Xu, Ruijuan, Patel, Kinnary, Crust, Kevin J., Khandelwal, Aarushi, Zhang, Chenyu, Prosandeev, Sergey, Zhou, Hua, Shao, Yu-Tsun, Bellaiche, Laurent, Hwang, Harold Y., and Muller, David A.

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

Sodium niobate, a lead-free ferroic material, hosts delicately-balanced, competing order parameters, including ferroelectric states that can be stabilized by epitaxial strain. Here, we show that the resulting macroscopic ferroelectricity exhibits an unconventional microscopic structure using multislice electron ptychography. This technique overcomes multiple scattering artifacts limiting conventional electron microscopy, enabling both lateral spatial resolution beyond the diffraction limit and recovery of three-dimensional structural information. These imaging capabilities allow us to separate the ferroelectric interior of the sample from the relaxed surface structure and identify the soft phonon mode and related structural distortions with picometer precision. Unlike conventional ferroelectric perovskites, we find that the polar distortion in this material involves minimal distortions of the cation sublattices and is instead dominated by anion displacements. We establish limits on film thickness for interfacial octahedral rotation engineering and directly visualize an incommensurate octahedral rotation pattern, arising from the flat dispersion of the associated phonon mode., Comment: 63 pages, 5 figures, 17 supplementary figures

Published
2024

5. Imaging interstitial atoms with multislice electron ptychography

Author

Chen, Zhen, Shao, Yu-Tsun, Zeltmann, Steven E., P., Harikrishnan K., Rosenberg, Ethan R., Ross, Caroline A., Jiang, Yi, and Muller, David A.

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

Doping impurity atoms is a strategy commonly used to tune the functionality of materials including catalysts, semiconductors, and quantum emitters. The location of dopants and their interaction with surrounding atoms could significantly modulate the transport, optical, or magnetic properties of materials. However, directly imaging individual impurity atoms inside materials remains a generally unaddressed need. Here, we demonstrate how single atoms can be detected and located in three dimensions via multislice electron ptychography.Interstitial atoms in a complex garnet oxide heterostructure are resolved with a depth resolution better than 2.7 nm, together with a deep-sub-{\AA}ngstrom lateral resolution. Single-scan atomic-layer depth resolution should be possible using strongly divergent electron probe illumination. Our results provide a new approach to detecting individual atomic defects and open doors to characterize the local environments and spatial distributions that underlie a broad range of systems such as single-atom catalysts, nitrogen-vacancy centers, and other atomic-scale quantum sensors., Comment: 28 pages, 5 figures, 10 supplementary figures

Published
2024

8. Leveraging both faces of polar semiconductor wafers for functional devices

Author

van Deurzen, Len, Kim, Eungkyun, Pieczulewski, Naomi, Zhang, Zexuan, Feduniewicz-Zmuda, Anna, Chlipala, Mikolaj, Siekacz, Marcin, Muller, David, Xing, Huili Grace, Jena, Debdeep, and Turski, Henryk

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Unlike non-polar semiconductors such as silicon, the broken inversion symmetry of the wide bandgap semiconductor gallium nitride leads to a large electronic polarization along a unique crystal axis. This makes the two surfaces of the semiconductor wafer perpendicular to the polar axis dramatically different in their physical and chemical properties. In the last three decades, the cation (gallium) face of gallium nitride has been used for photonic devices such as LEDs and lasers. Though the cation face has also been predominantly used for electronic devices, the anion (nitrogen) face has recently shown promise for high electron mobility transistors due to favorable polarization discontinuities. In this work we introduce dualtronics, showing that it is possible to make photonic devices on the cation face, and electronic devices on the anion face, of the same semiconductor wafer. This opens the possibility for leveraging both faces of polar semiconductors in a single structure, where electronic, photonic, and acoustic properties can be implemented on opposite faces of the same wafer, dramatically enhancing the functional capabilities of this revolutionary semiconductor family.

Published
2024

11. Millimeter-scale freestanding superconducting infinite-layer nickelate membranes

Author

Lee, Yonghun, Wei, Xin, Yu, Yijun, Bhatt, Lopa, Lee, Kyuho, Goodge, Berit H., Harvey, Shannon P., Wang, Bai Yang, Muller, David A., Kourkoutis, Lena F., Lee, Wei-Sheng, Raghu, Srinivas, and Hwang, Harold Y.

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

Progress in the study of infinite-layer nickelates has always been highly linked to materials advances. In particular, the recent development of superconductivity via hole-doping was predicated on the controlled synthesis of Ni in a very high oxidation state, and subsequent topotactic reduction to a very low oxidation state, currently limited to epitaxial thin films. Here we demonstrate a process to combine these steps with a heterostructure which includes an epitaxial soluble buffer layer, enabling the release of freestanding membranes of (Nd,Sr)NiO2 encapsulated in SrTiO3, which serves as a protective layer. The membranes have comparable structural and electronic properties to that of optimized thin films, and range in lateral dimensions from millimeters to ~100 micron fragments, depending on the degree of strain released with respect to the initial substrate. The changes in the superconducting transition temperature associated with membrane release are quite similar to those reported for substrate and pressure variations, suggestive of a common underlying mechanism. These membranes structures should provide a versatile platform for a range of experimental studies and devices free from substrate constraints.

Published
2024

12. Room‐Temperature, Current‐Induced Magnetization Self‐Switching in A Van Der Waals Ferromagnet

Author

Zhang, Hongrui, Chen, Xiang, Wang, Tianye, Huang, Xiaoxi, Chen, Xianzhe, Shao, Yu‐Tsun, Meng, Fanhao, Meisenheimer, Peter, N'Diaye, Alpha, Klewe, Christoph, Shafer, Padraic, Pan, Hao, Jia, Yanli, Crommie, Michael F, Martin, Lane W, Yao, Jie, Qiu, Ziqiang, Muller, David A, Birgeneau, Robert J, and Ramesh, Ramamoorthy

Subjects
Quantum Physics, Physical Sciences, Condensed Matter Physics, current-induced magnetization self-switching, polar magnet, room temperature, spin-orbit torque, van der Waals materials, MSD-General, MSD-Quantum Materials, MSD-VdW Heterostructures, MSD-CMOS, MSD-Nanocomposites, Chemical Sciences, Engineering, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

2D layered materials with broken inversion symmetry are being extensively pursued as  spin source layers to realize high-efficiency magnetic switching. Such low-symmetry layered systems are, however, scarce. In addition, most layered magnets with perpendicular magnetic anisotropy show a low Curie temperature. Here, the experimental observation of spin-orbit torque magnetization self-switching at room temperature in a layered polar ferromagnetic metal, Fe2.5 Co2.5 GeTe2 is reported. The spin-orbit torque is generated from the broken inversion symmetry along the c-axis of the crystal. These results provide a direct pathway toward applicable 2D spintronic devices.

Published
2024

13. Inducing a Tunable Skyrmion-Antiskyrmion System through Ion Beam Modification of FeGe Films

Author

Venuti, M. B., Zhang, Xiyue S., Lang, Eric J, Addamane, Sadhvikas J., Paik, Hanjong, Allen, Portia, Sharma, Peter, Muller, David, Hattar, Khalid, Lu, Tzu-Ming, and Eley, Serena

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

Skyrmions and antiskyrmions are nanoscale swirling textures of magnetic moments formed by chiral interactions between atomic spins in magnetic non-centrosymmetric materials and multilayer films with broken inversion symmetry. These quasiparticles are of interest for use as information carriers in next-generation, low-energy spintronic applications. To develop skyrmion-based memory and logic, we must understand skyrmion-defect interactions with two main goals -- determining how skyrmions navigate intrinsic material defects and determining how to engineer disorder for optimal device operation. Here, we introduce a tunable means of creating a skyrmion-antiskyrmion system by engineering the disorder landscape in FeGe using ion irradiation. Specifically, we irradiate epitaxial B20-phase FeGe films with 2.8 MeV Au$^{4+}$ ions at varying fluences, inducing amorphous regions within the crystalline matrix. Using low-temperature electrical transport and magnetization measurements, we observe a strong topological Hall effect with a double-peak feature that serves as a signature of skyrmions and antiskyrmions. These results are a step towards the development of information storage devices that use skyrmions and anitskyrmions as storage bits and our system may serve as a testbed for theoretically predicted phenomena in skyrmion-antiskyrmion crystals.

Published
2023

14. Spin disorder control of topological spin texture

Author

Zhang, Hongrui, Shao, Yu-Tsun, Chen, Xiang, Zhang, Binhua, Wang, Tianye, Meng, Fanhao, Xu, Kun, Meisenheimer, Peter, Chen, Xianzhe, Huang, Xiaoxi, Behera, Piush, Husain, Sajid, Zhu, Tiancong, Pan, Hao, Jia, Yanli, Settineri, Nick, Giles-Donovan, Nathan, He, Zehao, Scholl, Andreas, N’Diaye, Alpha, Shafer, Padraic, Raja, Archana, Xu, Changsong, Martin, Lane W, Crommie, Michael F, Yao, Jie, Qiu, Ziqiang, Majumdar, Arun, Bellaiche, Laurent, Muller, David A, Birgeneau, Robert J, and Ramesh, Ramamoorthy

Subjects
Quantum Physics, Physical Sciences, Condensed Matter Physics, MSD-General, MSD-Quantum Materials, MSD-CMOS, MSD-VdW Heterostructures
Abstract

Stabilization of topological spin textures in layered magnets has the potential to drive the development of advanced low-dimensional spintronics devices. However, achieving reliable and flexible manipulation of the topological spin textures beyond skyrmion in a two-dimensional magnet system remains challenging. Here, we demonstrate the introduction of magnetic iron atoms between the van der Waals gap of a layered magnet, Fe3GaTe2, to modify local anisotropic magnetic interactions. Consequently, we present direct observations of the order-disorder skyrmion lattices transition. In addition, non-trivial topological solitons, such as skyrmioniums and skyrmion bags, are realized at room temperature. Our work highlights the influence of random spin control of non-trivial topological spin textures.

Published
2024

15. Superior efficacy of a skin-applied microprojection device for delivering a novel Zika DNA vaccine.

Author

Masavuli, Makutiro, Young, Paul, Gowans, Eric, Grubor-Bauk, Branka, Muller, David, Wijesundara, Danushka, Yeow, Arthur, McMillan, Christopher, Choo, Jovin, Todorovic, Aleksandra, and Mekonnen, Zelalem

Subjects
DNA vaccine, HD-MAP, MT: Delivery Strategies, T cell immunity, Zika, cytotoxic T cells, microneedle, non-structural protein 1, skin patch
Abstract

Zika virus (ZIKV) infections are spreading silently with limited global surveillance in at least 89 countries and territories. There is a pressing need to develop an effective vaccine suitable for equitable distribution globally. Consequently, we previously developed a proprietary DNA vaccine encoding secreted non-structural protein 1 of ZIKV (pVAX-tpaNS1) to elicit rapid protection in a T cell-dependent manner in mice. In the current study, we evaluated the stability, efficacy, and immunogenicity of delivering this DNA vaccine into the skin using a clinically effective and proprietary high-density microarray patch (HD-MAP). Dry-coating of pVAX-tpaNS1 on the HD-MAP device resulted in no loss of vaccine stability at 40°C storage over the course of 28 days. Vaccination of mice (BALB/c) with the HD-MAP-coated pVAX-tpaNS1 elicited a robust anti-NS1 IgG response in both the cervicovaginal mucosa and systemically and afforded protection against live ZIKV challenge. Furthermore, the vaccination elicited a significantly higher magnitude and broader NS1-specific T helper and cytotoxic T cell response in vivo compared with traditional needle and syringe intradermal vaccination. Overall, the study highlights distinctive immunological advantages coupled with an excellent thermostability profile of using the HD-MAP device to deliver a novel ZIKV DNA vaccine.

Published
2023

16. Operando methods: A new era of electrochemistry

Author

Yang, Yao, Feijóo, Julian, Briega-Martos, Valentín, Li, Qihao, Krumov, Mihail, Merkens, Stefan, De Salvo, Giuseppe, Chuvilin, Andrey, Jin, Jianbo, Huang, Haowei, Pollock, Christopher J, Salmeron, Miquel B, Wang, Cheng, Muller, David A, Abruña, Héctor D, and Yang, Peidong

Subjects
Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Operando methods Electrochemical interfaces Electrocatalysis, Energy materials Scanning transmission electron microscopy Syn-chrotron X-rays., Analytical chemistry, Physical chemistry, Nanotechnology
Abstract

One of the grand challenges facing electrochemistry is to directly resolve the complex nature of (electro)catalyst active sites and capture real-time “movies” of reaction dynamics, i.e. “watching chemistry in action”. The need for such fundamental understanding has stimulated the development of operando/in situ methods, which have greatly enhanced our ability to identify activity descriptors of electrocatalysts and establish structure–property relationships of energy materials. This review summarizes the frontiers of operando electrochemical liquid-cell scanning transmission electron microscopy and correlative synchrotron X-ray methods, which are complementary tools to comprehensively investigate reaction dynamics across multiple spatiotemporal scales. In an effort to encourage greater adoption of advanced operando methods by the general electrochemistry community, this review points out the need to benchmark electrochemistry in confined and heterogenous liquid environment with minimal beam-induced damage. We anticipate that multimodal operando methods will become indispensable for understanding interfacial reaction mechanisms for the broad chemistry and energy materials communities.

Published
2023

17. Supercell formation in epitaxial rare-earth ditelluride thin films

Author

Llanos, Adrian, Salmani-Rezaie, Salva, Kim, Jinwoong, Kioussis, Nicholas, Muller, David A., and Falson, Joseph

Subjects
Condensed Matter - Materials Science
Abstract

Square net tellurides host an array of electronic ground states and commonly exhibit charge-density-wave ordering. Here we report the epitaxy of DyTe$_{2-\delta}$ on atomically flat MgO (001) using molecular beam epitaxy. The films are single phase and highly oriented as evidenced by transmission electron microscopy and X-ray diffraction measurements. Epitaxial strain is evident in films and is relieved as the thickness increases up to a value of approximately 20 unit cells. Diffraction features associated with a supercell in the films are resolved which is coupled with Te-deficiency. First principles calculations attribute the formation of this defect lattice to nesting conditions in the Fermi surface, which produce a periodic occupancy of the conducting Te square-net, and opens a band gap at the chemical potential. This work establishes the groundwork for exploring the role of strain in tuning electronic and structural phases of epitaxial square-net tellurides and related compounds.

Published
2023

18. Tuning the Curie temperature of a 2D magnet/topological insulator heterostructure to above room temperature by epitaxial growth

Author

Zhou, Wenyi, Bishop, Alexander J., Zhang, Xiyue S., Robinson, Katherine, Lyalin, Igor, Li, Ziling, Bailey-Crandell, Ryan, Cham, Thow Min Jerald, Cheng, Shuyu, Luo, Yunqiu Kelly, Ralph, Daniel C., Muller, David A., and Kawakami, Roland K.

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

Heterostructures of two-dimensional (2D) van der Waals (vdW) magnets and topological insulators (TI) are of substantial interest as candidate materials for efficient spin-torque switching, quantum anomalous Hall effect, and chiral spin textures. However, since many of the vdW magnets have Curie temperatures below room temperature, we want to understand how materials can be modified to stabilize their magnetic ordering to higher temperatures. In this work, we utilize molecular beam epitaxy to systematically tune the Curie temperature ($T_C$) in thin film Fe$_3$GeTe$_2$/Bi$_2$Te$_3$ from bulk-like values ($\sim$220 K) to above room temperature by increasing the growth temperature from 300 $^\circ$C to 375 $^\circ$C. For samples grown at 375 $^\circ$C, cross-sectional scanning transmission electron microscopy (STEM) reveals the spontaneous formation of different Fe$_m$Ge$_n$Te$_2$ compositions (e.g. Fe$_5$Ge$_2$Te$_2$ and Fe$_7$Ge$_6$Te$_2$) as well as intercalation in the vdW gaps, which are possible origins of the enhanced Curie temperature. This observation paves the way for developing various Fe$_m$Ge$_n$Te$_2$/TI heterostructures with novel properties., Comment: 8 pages, 4 figures

Published
2023
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19. Exchange bias between van der Waals materials: tilted magnetic states and field-free spin-orbit-torque switching

Author

Cham, Thow Min Jerald, Dorrian, Reiley J., Zhang, Xiyue S., Dismukes, Avalon H., Chica, Daniel G., May, Andrew F., Roy, Xavier, Muller, David A., Ralph, Daniel C., and Luo, Yunqiu Kelly

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Magnetic van der Waals heterostructures provide a unique platform to study magnetism and spintronics device concepts in the two-dimensional limit. Here, we report studies of exchange bias from the van der Waals antiferromagnet CrSBr acting on the van der Waals ferromagnet Fe3GeTe2 (FGT). The orientation of the exchange bias is along the in-plane easy axis of CrSBr, perpendicular to the out-of-plane anisotropy of the FGT, inducing a strongly tilted magnetic configuration in the FGT. Furthermore, the in-plane exchange bias provides sufficient symmetry breaking to allow deterministic spin-orbit torque switching of the FGT in CrSBr/FGT/Pt samples at zero applied magnetic field. A minimum thickness of the CrSBr greater than 10 nm is needed to provide a non-zero exchange bias at 30 K.

Published
2023

25. Strain Relaxation in Core-Shell Pt-Co Catalyst Nanoparticles

Author

Padgett, Elliot, Holtz, Megan E., Kongkanand, Anusorn, and Muller, David A.

Subjects
Condensed Matter - Materials Science
Abstract

Surface strain plays a key role in enhancing the activity of Pt-alloy nanoparticle oxygen reduction catalysts. However, the details of strain effects in real fuel cell catalysts are not well-understood, in part due to a lack of strain characterization techniques that are suitable for complex supported nanoparticle catalysts. This work investigates these effects using strain mapping with nanobeam electron diffraction and a continuum elastic model of strain in simple core-shell particles. We find that surface strain is relaxed both by lattice defects at the core-shell interface and by relaxation across particle shells caused by Poisson expansion in the spherical geometry. The continuum elastic model finds that in the absence of lattice dislocations, geometric relaxation results in a surface strain that scales with the average composition of the particle, regardless of the shell thickness. We investigate the impact of these strain effects on catalytic activity for a series of Pt-Co catalysts treated to vary their shell thickness and core-shell lattice mismatch. For catalysts with the thinnest shells, the activity is consistent with an Arrhenius dependence on the surface strain expected for coherent strain in dislocation-free particles, while catalysts with thicker shells showed greater activity losses indicating strain relaxation caused by dislocations as well., Comment: 23 pages,7 figures, includes appendix

Published
2023

26. Excitonic and deep-level emission from N- and Al-polar homoepitaxial AlN grown by molecular beam epitaxy

Author

van Deurzen, Len, Singhal, Jashan, Encomendero, Jimy, Pieczulewski, Naomi, Chang, Celesta, Cho, YongJin, Muller, David Anthony, Xing, Huili Grace, Jena, Debdeep, Brandt, Oliver, and Lähnemann, Jonas

Subjects
Condensed Matter - Materials Science
Abstract

Using low-temperature cathodoluminescence spectroscopy, we study the properties of N- and Al-polar AlN layers grown by molecular beam epitaxy on bulk AlN{0001}. Compared to the bulk AlN substrate, layers of both polarities feature a suppression of deep-level luminescence, a total absence of the prevalent donor with an exciton binding energy of 28 meV, and a much increased intensity of the emission from free excitons. The dominant donor in these layers is characterized by an associated exciton binding energy of 13 meV. The observation of excited exciton states up to the exciton continuum allows us to directly extract the $\Gamma_{5}$ free exciton binding energy of 57 meV.

Published
2023
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27. Thermodynamic route of Nb3Sn nucleation: Role of oxygen

Author

Sun, Zeming, Dare, Darrah K., Baraissov, Zhaslan, Muller, David A., Thompson, Michael O., and Liepe, Matthias U.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity, Physics - Accelerator Physics, Physics - Applied Physics
Abstract

Intermetallic Nb3Sn alloys have long been believed to form through Sn diffusion into Nb. However, our observations of significant oxygen content in Nb3Sn prompted an investigation of alternative formation mechanisms. Through experiments involving different oxide interfaces (clean HF-treated, native oxidized, and anodized), we demonstrate a thermodynamic route that fundamentally challenges the conventional Sn diffusion mechanism for Nb3Sn nucleation. Our results highlight the critical involvement of a SnOx intermediate phase. This new nucleation mechanism identifies the principles for growth optimization and new synthesis of high-quality Nb3Sn superconductors.

Published
2023
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28. Surface oxides, carbides, and impurities on RF superconducting Nb and Nb3Sn: A comprehensive analysis

Author

Sun, Zeming, Baraissov, Zhaslan, Dukes, Catherine A., Dare, Darrah K., Oseroff, Thomas, Thompson, Michael O., Muller, David A., and Liepe, Matthias U.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity, Physics - Applied Physics, Physics - Chemical Physics
Abstract

Surface structures on radio-frequency (RF) superconductors are crucially important in determining their interaction with the RF field. Here we investigate the surface compositions, structural profiles, and valence distributions of oxides, carbides, and impurities on niobium (Nb) and niobium-tin (Nb3Sn) in situ under different processing conditions. We establish the underlying mechanisms of vacuum baking and nitrogen processing in Nb and demonstrate that carbide formation induced during high-temperature baking, regardless of gas environment, determines subsequent oxide formation upon air exposure or low-temperature baking, leading to modifications of the electron population profile. Our findings support the combined contribution of surface oxides and second-phase formation to the outcome of ultra-high vacuum baking (oxygen processing) and nitrogen processing. Also, we observe that vapor-diffused Nb3Sn contains thick metastable oxides, while electrochemically synthesized Nb3Sn only has a thin oxide layer. Our findings reveal fundamental mechanisms of baking and processing Nb and Nb3Sn surface structures for high-performance superconducting RF and quantum applications

Published
2023
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29. Enhanced Critical Field of Superconductivity at an Oxide Interface

Author

Al-Tawhid, Athby H., Poage, Samuel J., Salmani-Rezaie, Salva, Chikara, Shalinee, Muller, David A., Kumah, Divine P., Gastiasoro, Maria N., Lorenzana, Jose, and Ahadi, Kaveh

Subjects
Condensed Matter - Superconductivity
Abstract

The nature of superconductivity and its interplay with strong spin-orbit coupling at the KTaO3(111) interfaces remains a subject of debate. To address this problem, we grew epitaxial LaMnO3/KTaO3(111) heterostructures. We show that superconductivity is robust against the in-plane magnetic field, with the critical field of superconductivity reaching 25 T in optimally doped heterostructures. The superconducting order parameter is highly sensitive to carrier density. We argue that spin-orbit coupling drives the formation of anomalous quasiparticles with vanishing magnetic moment, providing the condensate significant immunity against magnetic fields beyond the Pauli paramagnetic limit. These results offer design opportunities for superconductors with extreme resilience against magnetic field.

Published
2023
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30. Understanding the Structural Evolution of IrFeCoNiCu High-Entropy Alloy Nanoparticles under the Acidic Oxygen Evolution Reaction

Author

Maulana, Arifin Luthfi, Chen, Peng-Cheng, Shi, Zixiao, Yang, Yao, Lizandara-Pueyo, Carlos, Seeler, Fabian, Abruña, Héctor D, Muller, David, Schierle-Arndt, Kerstin, and Yang, Peidong

Subjects
Nanotechnology, Bioengineering, high-entropy alloy, acidic OER, structuralevolution, dissolution, structural evolution, Nanoscience & Nanotechnology
Abstract

High-entropy alloy (HEA) nanoparticles are promising catalyst candidates for the acidic oxygen evolution reaction (OER). Herein, we report the synthesis of IrFeCoNiCu-HEA nanoparticles on a carbon paper substrate via a microwave-assisted shock synthesis method. Under OER conditions in 0.1 M HClO4, the HEA nanoparticles exhibit excellent activity with an overpotential of ∼302 mV measured at 10 mA cm-2 and improved stability over 12 h of operation compared to the monometallic Ir counterpart. Importantly, an active Ir-rich shell layer with nanodomain features was observed to form on the surface of IrFeCoNiCu-HEA nanoparticles immediately after undergoing electrochemical activation, mainly due to the dissolution of the constituent 3d metals. The core of the particles was able to preserve the characteristic homogeneous single-phase HEA structure without significant phase separation or elemental segregation. This work illustrates that under acidic operating conditions, the near-surface structure of HEA nanoparticles is susceptible to a certain degree of structural dynamics.

Published
2023

32. Genome-wide association meta-analysis of spontaneous coronary artery dissection identifies risk variants and genes related to artery integrity and tissue-mediated coagulation.

Author

Adlam, David, Berrandou, Takiy-Eddine, Georges, Adrien, Nelson, Christopher, Giannoulatou, Eleni, Henry, Joséphine, Ma, Lijiang, Blencowe, Montgomery, Turley, Tamiel, Yang, Min-Lee, Chopade, Sandesh, Finan, Chris, Braund, Peter, Sadeg-Sayoud, Ines, Iismaa, Siiri, Kosel, Matthew, Zhou, Xiang, Hamby, Stephen, Cheng, Jenny, Liu, Lu, Tarr, Ingrid, Muller, David, dEscamard, Valentina, King, Annette, Brunham, Liam, Baranowska-Clarke, Ania, Debette, Stéphanie, Amouyel, Philippe, Olin, Jeffrey, Patil, Snehal, Hesselson, Stephanie, Junday, Keerat, Kanoni, Stavroula, Aragam, Krishna, Butterworth, Adam, Tweet, Marysia, Gulati, Rajiv, Combaret, Nicolas, Kadian-Dodov, Daniella, Kalman, Jonathan, Fatkin, Diane, Hingorani, Aroon, Saw, Jacqueline, Webb, Tom, Hayes, Sharonne, Yang, Xia, Ganesh, Santhi, Olson, Timothy, Kovacic, Jason, Graham, Robert, Samani, Nilesh, and Bouatia-Naji, Nabila

Subjects
Humans, Female, Genome-Wide Association Study, Vascular Diseases, Coronary Artery Disease, Myocardial Infarction
Abstract

Spontaneous coronary artery dissection (SCAD) is an understudied cause of myocardial infarction primarily affecting women. It is not known to what extent SCAD is genetically distinct from other cardiovascular diseases, including atherosclerotic coronary artery disease (CAD). Here we present a genome-wide association meta-analysis (1,917 cases and 9,292 controls) identifying 16 risk loci for SCAD. Integrative functional annotations prioritized genes that are likely to be regulated in vascular smooth muscle cells and artery fibroblasts and implicated in extracellular matrix biology. One locus containing the tissue factor gene F3, which is involved in blood coagulation cascade initiation, appears to be specific for SCAD risk. Several associated variants have diametrically opposite associations with CAD, suggesting that shared biological processes contribute to both diseases, but through different mechanisms. We also infer a causal role for high blood pressure in SCAD. Our findings provide novel pathophysiological insights involving arterial integrity and tissue-mediated coagulation in SCAD and set the stage for future specific therapeutics and preventions.

Published
2023

33. Ordering of room-temperature magnetic skyrmions in a polar van der Waals magnet.

Author

Meisenheimer, Peter, Zhang, Hongrui, Raftrey, David, Chen, Xiang, Shao, Yu-Tsun, Chan, Ying-Ting, Yalisove, Reed, Chen, Rui, Yao, Jie, Scott, Mary C, Wu, Weida, Muller, David A, Fischer, Peter, Birgeneau, Robert J, and Ramesh, Ramamoorthy

Subjects
Temperature, Engineering, Physical Phenomena, Magnets, Magnetic Phenomena
Abstract

Control and understanding of ensembles of skyrmions is important for realization of future technologies. In particular, the order-disorder transition associated with the 2D lattice of magnetic skyrmions can have significant implications for transport and other dynamic functionalities. To date, skyrmion ensembles have been primarily studied in bulk crystals, or as isolated skyrmions in thin film devices. Here, we investigate the condensation of the skyrmion phase at room temperature and zero field in a polar, van der Waals magnet. We demonstrate that we can engineer an ordered skyrmion crystal through structural confinement on the μm scale, showing control over this order-disorder transition on scales relevant for device applications.

Published
2023

35. ZrNb(CO) RF superconducting thin film with high critical temperature in the theoretical limit

Author

Sun, Zeming, Oseroff, Thomas, Baraissov, Zhaslan, Dare, Darrah K., Howard, Katrina, Francis, Benjamin, Hire, Ajinkya C., Sitaraman, Nathan, Arias, Tomas A., Transtrum, Mark K., Hennig, Richard, Thompson, Michael O., Muller, David A., and Liepe, Matthias U.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity, Physics - Accelerator Physics, Physics - Applied Physics
Abstract

Superconducting radio-frequency (SRF) resonators are critical components for particle accelerator applications, such as free-electron lasers, and for emerging technologies in quantum computing. Developing advanced materials and their deposition processes to produce RF superconductors that yield nanoohms surface resistances is a key metric for the wider adoption of SRF technology. Here we report ZrNb(CO) RF superconducting films with high critical temperatures (Tc) achieved for the first time under ambient pressure. The attainment of a Tc near the theoretical limit for this material without applied pressure is promising for its use in practical applications. A range of Tc, likely arising from Zr doping variation, may allow a tunable superconducting coherence length that lowers the sensitivity to material defects when an ultra-low surface resistance is required. Our ZrNb(CO) films are synthesized using a low-temperature (100 - 200 C) electrochemical recipe combined with thermal annealing. The phase transformation as a function of annealing temperature and time is optimized by the evaporated Zr-Nb diffusion couples. Through phase control, we avoid hexagonal Zr phases that are equilibrium-stable but degrade Tc. X-ray and electron diffraction combined with photoelectron spectroscopy reveal a system containing cubic ZrNb mixed with rocksalt NbC and low-dielectric-loss ZrO2. We demonstrate proof-of-concept RF performance of ZrNb(CO) on an SRF sample test system. BCS resistance trends lower than reference Nb, while quench fields occur at approximately 35 mT. Our results demonstrate the potential of ZrNb(CO) thin films for particle accelerator and other SRF applications.

Published
2023
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36. Smooth, homogeneous, high-purity Nb3Sn superconducting RF resonant cavity by seed-free electrochemical synthesis

Author

Sun, Zeming, Baraissov, Zhaslan, Porter, Ryan D., Shpani, Liana, Shao, Yu-Tsun, Oseroff, Thomas, Thompson, Michael O., Muller, David A., and Liepe, Matthias U.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Superconductivity, Physics - Accelerator Physics, Physics - Applied Physics
Abstract

Workbench-size particle accelerators, enabled by Nb3Sn-based superconducting radio-frequency (SRF) cavities, hold the potential of driving scientific discovery by offering a widely accessible and affordable source of high-energy electrons and X-rays. Thin-film Nb3Sn RF superconductors with high quality factors, high operation temperatures, and high-field potentials are critical for these devices. However, surface roughness, non-stoichiometry, and impurities in Nb3Sn deposited by conventional Sn-vapor diffusion prevent them from reaching their theoretical capabilities. Here we demonstrate a seed-free electrochemical synthesis that pushes the limit of chemical and physical properties in Nb3Sn. Utilization of electrochemical Sn pre-deposits reduces the roughness of converted Nb3Sn by five times compared to typical vapor-diffused Nb3Sn. Quantitative mappings using chemical and atomic probes confirm improved stoichiometry and minimized impurity concentrations in electrochemically synthesized Nb3Sn. We have successfully applied this Nb3Sn to the large-scale 1.3 GHz SRF cavity and demonstrated ultra-low BCS surface resistances at multiple operation temperatures, notably lower than vapor-diffused cavities. Our smooth, homogeneous, high-purity Nb3Sn provides the route toward high efficiency and high fields for SRF applications under helium-free cryogenic operations.

Published
2023
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38. Molecular Beam Epitaxy of KTaO$_3$

Author

Schwaigert, Tobias, Salmani-Razaie, Salva, Barone, Matthew R., Paik, Hanjong, Ray, Ethan, Williams, Michael D., Muller, David A., Schlom, Darrell G., and Ahadi, Kaveh

Subjects
Condensed Matter - Materials Science
Abstract

Strain-engineering is a powerful means to tune the polar, structural, and electronic instabilities of incipient ferroelectrics. KTaO3 is near a polar instability and shows anisotropic superconductivity in electron-doped samples. Here, we demonstrate growth of high quality KTaO3 thin films by molecular-beam epitaxy. Tantalum was provided by both a suboxide source emanating a TaO2 flux from Ta2O5 contained in a conventional effusion cell as well as an electron-beam-heated tantalum source. Excess potassium and a combination of ozone and oxygen (10 \% O3 + 90 \% O2) were simultaneously supplied with the TaO$_2$ (or tantalum) molecular beams to grow the KTaO$_3$ films. Laue fringes suggest that the films are smooth with an abrupt film/substrate interface. Cross-sectional scanning transmission electron microscopy does not show any extended defects and confirms that the films have an atomically abrupt interface with the substrate. Atomic force microscopy reveals atomic steps at the surface of the grown films. Reciprocal space mapping demonstrates that the films, when sufficiently thin, are coherently strained to the SrTiO$_3$ (001) and GdScO$_3$ (110) substrates.

Published
2022
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39. Size‐Induced Ferroelectricity in Antiferroelectric Oxide Membranes

Author

Xu, Ruijuan, Crust, Kevin J, Harbola, Varun, Arras, Rémi, Patel, Kinnary Y, Prosandeev, Sergey, Cao, Hui, Shao, Yu‐Tsun, Behera, Piush, Caretta, Lucas, Kim, Woo Jin, Khandelwal, Aarushi, Acharya, Megha, Wang, Melody M, Liu, Yin, Barnard, Edward S, Raja, Archana, Martin, Lane W, Gu, X Wendy, Zhou, Hua, Ramesh, Ramamoorthy, Muller, David A, Bellaiche, Laurent, and Hwang, Harold Y

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Engineering, Physical Sciences, Materials Engineering, Affordable and Clean Energy, antiferroelectric materials, membranes, phase transition, size effects, sodium niobate, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Despite extensive studies on size effects in ferroelectrics, how structures and properties evolve in antiferroelectrics with reduced dimensions still remains elusive. Given the enormous potential of utilizing antiferroelectrics for high-energy-density storage applications, understanding their size effects will provide key information for optimizing device performances at small scales. Here, the fundamental intrinsic size dependence of antiferroelectricity in lead-free NaNbO3 membranes is investigated. Via a wide range of experimental and theoretical approaches, an intriguing antiferroelectric-to-ferroelectric transition upon reducing membrane thickness is probed. This size effect leads to a ferroelectric single-phase below 40 nm, as well as a mixed-phase state with ferroelectric and antiferroelectric orders coexisting above this critical thickness. Furthermore, it is shown that the antiferroelectric and ferroelectric orders are electrically switchable. First-principle calculations further reveal that the observed transition is driven by the structural distortion arising from the membrane surface. This work provides direct experimental evidence for intrinsic size-driven scaling in antiferroelectrics and demonstrates enormous potential of utilizing size effects to drive emergent properties in environmentally benign lead-free oxides with the membrane platform.

Published
2023

40. Topological phases in polar oxide nanostructures

Author

Junquera, Javier, Nahas, Yousra, Prokhorenko, Sergei, Bellaiche, Laurent, Íñiguez, Jorge, Schlom, Darrell G, Chen, Long-Qing, Salahuddin, Sayeef, Muller, David A, Martin, Lane W, and Ramesh, R

Subjects
Affordable and Clean Energy, Physical Sciences, Fluids & Plasmas
Abstract

The past decade has witnessed dramatic progress related to various aspects of emergent topological polar textures in oxide nanostructures displaying vortices, skyrmions, merons, hopfions, dipolar waves, or labyrinthine domains, among others. For a long time, these nontrivial structures (the electric counterparts of the exotic spin textures) were not expected due to the high energy cost associated with the dipolar anisotropy: the smooth and continuous evolution of the local polarization to produce topologically protected structures would result in a large elastic energy penalty. However, it was discovered that the delicate balance and intricate interplay between the electric, elastic, and gradient energies can be altered in low-dimensional forms of ferroelectric oxide nanostructures. These can be tuned to manipulate order parameters in ways once considered impossible. This review addresses the historical context that provided the fertile background for the dawning of the polar topological era. This has been possible thanks to a fruitful, positive feedback between theory and experiment: advances in materials synthesis and preparation (with a control at the atomic scale) and characterization have come together with great progress in theoretical modeling of ferroelectrics at larger length and timescales. An in-depth scientific description to formalize and generalize the prediction, observation, and probing of exotic, novel, and emergent states of matter is provided. Extensive discussions of the fundamental physics of such polar textures, a primer explaining the basic topological concepts, an explanation of the modern theoretical and computational methodologies that enable the design and study of such structures, what it takes to achieve deterministic, on-demand control of order-parameter topologies through atomically precise synthesis, the range of characterization methods that are key to probing these structures, and their thermodynamic field-driven (temperature-driven, stress-driven, etc.) susceptibilities are included. The new emergent states of matter join together with exotic functional properties (such as chirality, negative capacitance, and coexistence of phases) that, along with their small size and ultrafast dynamical response, make them potential candidates in multifunctional devices. Finally, some open questions and challenges for the future are presented, underlining the interesting future that is anticipated in this field.

Published
2023

41. Operando Electrochemical Liquid-Cell Scanning Transmission Electron Microscopy (EC-STEM) Studies of Evolving Cu Nanocatalysts for CO2 Electroreduction

Author

Yang, Yao, Shao, Yu-Tsun, Jin, Jianbo, Feijóo, Julian, Roh, Inwhan, Louisia, Sheena, Yu, Sunmoon, Guzman, Maria V Fonseca, Chen, Chubai, Muller, David A, Abruña, Héctor D, and Yang, Peidong

Subjects
Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Affordable and Clean Energy, Operando, EC-STEM, 4D-STEM, CO2RR, Dynamic evolution, Cu nanocatalysts, Analytical Chemistry, Environmental Science and Management, Chemical Engineering, Analytical chemistry, Chemical engineering
Abstract

The design and synthesis of nanocatalysts with well-defined sizes, compositions, and structures have revolutionized our accessibility to tunable catalyst activity and selectivity for a variety of energy-related electrochemical reactions. Nonetheless, establishing structure-(re)activity correlations requires the understanding of the dynamic evolution of pristine nanocatalysts and the identification of their active states under operating conditions. We previously communicated the operando observation of Cu nanocatalysts evolving into active metallic Cu nanograins for CO2 electroreduction (Yang et al. Nature 2023, 614, 262−269 ). Here, we expand our discussion to the technical capabilities and further research applications of operando electrochemical liquid-cell scanning transmission electron microscopy (EC-STEM), which enables quantitative electrochemistry while tracking dynamic structural evolution of sub-10 nm Cu nanocatalysts. The coexistent H2 bubbles, often disruptive to operando spectroscopy, are an effective approach to create a thin-liquid layer that significantly improves spatial resolution while remaining electrochemically accessible to Cu nanocatalysts. Operando four-dimensional (4D) STEM in liquids provides insights into the complex structure of active polycrystalline metallic Cu nanograins. With continuous technical developments, we anticipate that operando EC-STEM will evolve into a powerful electroanalytical method to advance our understanding of a variety of nanoscale electrocatalysts at solid/liquid interfaces.

Published
2023

42. Thermally-generated spin current in the topological insulator Bi$_2$Se$_3$

Author

Jain, Rakshit, Stanley, Max, Bose, Arnab, Richardella, Anthony R., Zhang, Xiyue S., Pillsbury, Timothy, Muller, David A., Samarth, Nitin, and Ralph, Daniel C.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We complete measurements of interconversions among the full triad of thermal gradients, charge currents, and spin currents in the topological insulator Bi$_2$Se$_3$ by quantifying the efficiency with which thermal gradients can generate transverse spin currents. We accomplish this by comparing the spin Nernst magneto-thermopower to the spin Hall magnesistance for bilayers of Bi$_2$Se$_3$/CoFeB. We find that Bi$_2$Se$_3$ does generate substantial thermally-driven spin currents. A lower bound for the ratio of spin current to thermal gradient is $J_s/\nabla_x T$ = (4.9 $\pm$ 0.9) $\times$ 10$^{6}$ ($\hbar/2e$) A m$^{-2}$ / K $\mu$m$^{-1}$, and a lower bound for the magnitude of the spin Nernst ratio is $-$0.61 $\pm$ 0.11. The spin Nernst ratio for Bi$_2$Se$_3$ is the largest among all materials measured to date, 2-3 times larger compared to previous measurements for the heavy metals Pt and W.

Published
2022

45. Theory of Nb-Zr Alloy Superconductivity and First Experimental Demonstration for Superconducting Radio-Frequency Cavity Applications

Author

Sitaraman, Nathan S., Sun, Zeming, Francis, Ben, Hire, Ajinkya C., Oseroff, Thomas, Baraissov, Zhaslan, Arias, Tomás A., Hennig, Richard, Liepe, Matthias U., Muller, David A., and Transtrum, Mark K.

Subjects
Condensed Matter - Superconductivity
Abstract

Niobium-zirconium (Nb-Zr) alloy is an old superconductor that is a promising new candidate for superconducting radio-frequency (SRF) cavity applications. Using density-functional and Eliashberg theories, we show that addition of Zr to a Nb surface in small concentrations increases the critical temperature $T_c$ and improves other superconducting properties. Furthermore, we calculate $T_c$ for Nb-Zr alloys across a broad range of Zr concentrations, showing good agreement with the literature for disordered alloys as well as the potential for significantly higher $T_c$ in ordered alloys near 75%Nb/25%Zr composition. We provide experimental verification on Nb-Zr alloy samples and SRF sample test cavities prepared with either physical vapor or our novel electrochemical deposition recipes. These samples have the highest measured $T_c$ of any Nb-Zr superconductor to date and indicate a reduction in BCS resistance compared to the conventional Nb reference sample; they represent the first steps along a new pathway to greatly enhanced SRF performance. Finally, we use Ginzburg-Landau theory to show that the addition of Zr to a Nb surface increases the superheating field $B_{sh}$, a key figure of merit for SRF which determines the maximum accelerating gradient at which cavities can operate., Comment: 7 pages, 5 figures, submitted to Physical Review Letters

Published
2022

46. Real-time 3D analysis during electron tomography using tomviz

Author

Schwartz, Jonathan, Harris, Chris, Pietryga, Jacob, Kumar, Huihuo Zheng Prashant, Visheratina, Anastasia, Kotor, Nicholas, Major, Brianna, Avery, Patrick, Ercius, Peter, Ayachit, Utmarsch, Geveci, Berk, Muller, David, Genova, Alessandro, Jiang, Yi, Hanwell, Marcus, and Hovden, Robert

Subjects
Condensed Matter - Materials Science
Abstract

The demand for high-throughput electron tomography is rapidly increasing in biological and material sciences. However, this 3D imaging technique is computationally bottlenecked by alignment and reconstruction which runs from hours to days. We demonstrate real-time tomography with dynamic 3D tomographic visualization to enable rapid interpretation of specimen structure immediately as data is collected on an electron microscope. Using geometrically complex chiral nanoparticles, we show volumetric interpretation can begin in less than 10 minutes and a high quality tomogram is available within 30 minutes. Real time tomography is integrated into tomviz, an open source and cross platform 3D analysis tool that contains intuitive graphical user interfaces (GUI) to enable any scientist to characterize biological and material structure in 3D.

Published
2022
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47. Gate-tunable anomalous Hall effect in a 3D topological insulator/2D magnet van der Waals heterostructure

Author

Gupta, Vishakha, Jain, Rakshit, Ren, Yafei, Zhang, Xiyue S., Alnaser, Husain F., Vashist, Amit, Deshpande, Vikram V., Muller, David A., Xiao, Di, Sparks, Taylor D., and Ralph, Daniel C.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We demonstrate advantages of samples made by mechanical stacking of exfoliated van der Waals materials for controlling the topological surface state of a 3-dimensional topological insulator (TI) via interaction with an adjacent magnet layer. We assemble bilayers with pristine interfaces using exfoliated flakes of the TI BiSbTeSe2 and the magnet Cr2Ge2Te6, thereby avoiding problems caused by interdiffusion that can affect interfaces made by top-down deposition methods. The samples exhibit an anomalous Hall effect (AHE) with abrupt hysteretic switching. For the first time in samples composed of a TI and a separate ferromagnetic layer, we demonstrate that the amplitude of the AHE can be tuned via gate voltage with a strong peak near the Dirac point. This is the signature expected for the AHE due to Berry curvature associated with an exchange gap induced by interaction between the topological surface state and an out-of-plane-oriented magnet., Comment: submitted version

Published
2022
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49. Operando studies reveal active Cu nanograins for CO2 electroreduction

Author

Yang, Yao, Louisia, Sheena, Yu, Sunmoon, Jin, Jianbo, Roh, Inwhan, Chen, Chubai, Fonseca Guzman, Maria V, Feijóo, Julian, Chen, Peng-Cheng, Wang, Hongsen, Pollock, Christopher J, Huang, Xin, Shao, Yu-Tsun, Wang, Cheng, Muller, David A, Abruña, Héctor D, and Yang, Peidong

Subjects
Engineering, Materials Engineering, Chemical Sciences, Affordable and Clean Energy, CSD-02-CAT-A, CSD-46-All CSGB, General Science & Technology
Abstract

Carbon dioxide electroreduction facilitates the sustainable synthesis of fuels and chemicals1. Although Cu enables CO2-to-multicarbon product (C2+) conversion, the nature of the active sites under operating conditions remains elusive2. Importantly, identifying active sites of high-performance Cu nanocatalysts necessitates nanoscale, time-resolved operando techniques3-5. Here, we present a comprehensive investigation of the structural dynamics during the life cycle of Cu nanocatalysts. A 7 nm Cu nanoparticle ensemble evolves into metallic Cu nanograins during electrolysis before complete oxidation to single-crystal Cu2O nanocubes following post-electrolysis air exposure. Operando analytical and four-dimensional electrochemical liquid-cell scanning transmission electron microscopy shows the presence of metallic Cu nanograins under CO2 reduction conditions. Correlated high-energy-resolution time-resolved X-ray spectroscopy suggests that metallic Cu, rich in nanograin boundaries, supports undercoordinated active sites for C-C coupling. Quantitative structure-activity correlation shows that a higher fraction of metallic Cu nanograins leads to higher C2+ selectivity. A 7 nm Cu nanoparticle ensemble, with a unity fraction of active Cu nanograins, exhibits sixfold higher C2+ selectivity than the 18 nm counterpart with one-third of active Cu nanograins. The correlation of multimodal operando techniques serves as a powerful platform to advance our fundamental understanding of the complex structural evolution of nanocatalysts under electrochemical conditions.

Published
2023

50. Non-volatile electric-field control of inversion symmetry

Author

Caretta, Lucas, Shao, Yu-Tsun, Yu, Jia, Mei, Antonio B, Grosso, Bastien F, Dai, Cheng, Behera, Piush, Lee, Daehun, McCarter, Margaret, Parsonnet, Eric, K. P, Harikrishnan, Xue, Fei, Guo, Xiangwei, Barnard, Edward S, Ganschow, Steffen, Hong, Zijian, Raja, Archana, Martin, Lane W, Chen, Long-Qing, Fiebig, Manfred, Lai, Keji, Spaldin, Nicola A, Muller, David A, Schlom, Darrell G, and Ramesh, Ramamoorthy

Subjects
Physical Sciences, Condensed Matter Physics, Nanoscience & Nanotechnology
Abstract

Competition between ground states at phase boundaries can lead to significant changes in properties under stimuli, particularly when these ground states have different crystal symmetries. A key challenge is to stabilize and control the coexistence of symmetry-distinct phases. Using BiFeO3 layers confined between layers of dielectric TbScO3 as a model system, we stabilize the mixed-phase coexistence of centrosymmetric and non-centrosymmetric BiFeO3 phases at room temperature with antipolar, insulating and polar semiconducting behaviour, respectively. Application of orthogonal in-plane electric (polar) fields results in reversible non-volatile interconversion between the two phases, hence removing and introducing centrosymmetry. Counterintuitively, we find that an electric field 'erases' polarization, resulting from the anisotropy in octahedral tilts introduced by the interweaving TbScO3 layers. Consequently, this interconversion between centrosymmetric and non-centrosymmetric phases generates changes in the non-linear optical response of over three orders of magnitude, resistivity of over five orders of magnitude and control of microscopic polar order. Our work establishes a platform for cross-functional devices that take advantage of changes in optical, electrical and ferroic responses, and demonstrates octahedral tilts as an important order parameter in materials interface design.

Published
2023

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