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22 results on '"Checa, Marti"'

1. Hierarchical domain structures in buckled ferroelectric free sheets

Author

Pesquera, David, Cordero-Edwards, Kumara, Checa, Marti, Ivanov, Ilia, Casals, Blai, Rosado, Marcos, Caicedo, José Manuel, Casado-Zueras, Laura, Pablo-Navarro, Javier, Magén, César, Santiso, José, Domingo, Neus, Catalan, Gustau, and Sandiumenge, Felip

Subjects
Condensed Matter - Materials Science
Abstract

Flat elastic sheets tend to display wrinkles and folds. From pieces of clothing down to two-dimensional crystals, these corrugations appear in response to strain generated by sheet compression or stretching, thermal or mechanical mismatch with other elastic layers, or surface tension. Extensively studied in metals, polymers and, more recently, in van der Waals exfoliated layers, with the advent of thin single crystal freestanding films of complex oxides, researchers are now paying attention to novel microstructural effects induced by bending ferroelectric-ferroelastics, where polarization is strongly coupled to lattice deformation. Here we show that wrinkle undulations in BaTiO3 sheets bonded to a viscoelastic substrate transform into a buckle delamination geometry when transferred onto a rigid substrate. Using spatially resolved techniques at different scales (Raman, scanning probe and electron microscopy), we show how these delaminations in the free BaTiO3 sheets display a self-organization of ferroelastic domains along the buckle profile that strongly differs from the more studied sinusoidal wrinkle geometry. Moreover, we disclose the hierarchical distribution of a secondary set of domains induced by the misalignment of these folding structures from the preferred in-plane crystallographic orientations. Our results disclose the relevance of the morphology and orientation of buckling instabilities in ferroelectric free sheets, for the stabilization of different domain structures, pointing to new routes for domain engineering of ferroelectrics in flexible oxide sheets.

Published
2024

2. Evolution of ferroelectric properties in SmxBi1-xFeO3 via automated Piezoresponse Force Microscopy across combinatorial spread libraries

Author

Raghavan, Aditya, Pant, Rohit, Takeuchi, Ichiro, Eliseev, Eugene A., Checa, Marti, Morozovska, Anna N., Ziatdinov, Maxim, Kalinin, Sergei V., and Liu, Yongtao

Subjects
Condensed Matter - Materials Science
Abstract

Combinatorial spread libraries offer a unique approach to explore evolution of materials properties over the broad concentration, temperature, and growth parameter spaces. However, the traditional limitation of this approach is the requirement for the read-out of functional properties across the library. Here we demonstrate the application of automated Piezoresponse Force Microscopy (PFM) for the exploration of the physics in the SmxBi1-xFeO3 system with the ferroelectric-antiferroelectric morphotropic phase boundary. This approach relies on the synergy of the quantitative nature of PFM and the implementation of automated experiments that allows PFM-based gird sampling over macroscopic samples. The concentration dependence of pertinent ferroelectric parameters has been determined and used to develop the mathematical framework based on Ginzburg-Landau theory describing the evolution of these properties across the concentration space. We pose that combination of automated scanning probe microscope and combinatorial spread library approach will emerge as an efficient research paradigm to close the characterization gap in the high-throughput materials discovery. We make the data sets open to the community and hope that will stimulate other efforts to interpret and understand the physics of these systems., Comment: 19 pages; 5 figures

Published
2024

3. Synergizing Human Expertise and AI Efficiency with Language Model for Microscopy Operation and Automated Experiment Design

Author

Liu, Yongtao, Checa, Marti, and Vasudevan, Rama K.

Subjects
Computer Science - Human-Computer Interaction, Condensed Matter - Materials Science
Abstract

With the advent of large language models (LLMs), in both the open source and proprietary domains, attention is turning to how to exploit such artificial intelligence (AI) systems in assisting complex scientific tasks, such as material synthesis, characterization, analysis and discovery. Here, we explore the utility of LLM, particularly ChatGPT4, in combination with application program interfaces (APIs) in tasks of experimental design, programming workflows, and data analysis in scanning probe microscopy, using both in-house developed API and API given by a commercial vendor for instrument control. We find that the LLM can be especially useful in converting ideations of experimental workflows to executable code on microscope APIs. Beyond code generation, we find that the GPT4 is capable of analyzing microscopy images in a generic sense. At the same time, we find that GPT4 suffers from inability to extend beyond basic analyses or more in-depth technical experimental design. We argue that a LLM specifically fine-tuned for individual scientific domains can potentially be a better language interface for converting scientific ideations from human experts to executable workflows, such a synergy between human expertise and LLM efficiency in experimentation can open new door for accelerating scientific research, enabling effective experimental protocols archive and sharing in scientific community., Comment: 16 pages; 7 figures

Published
2024

4. AEcroscoPy: A software-hardware framework empowering microscopy toward automated and autonomous experimentation

Author

Liu, Yongtao, Roccapriore, Kevin, Checa, Marti, Valleti, Sai Mani, Yang, Jan-Chi, Jesse, Stephen, and Vasudevan, Rama K.

Subjects
Condensed Matter - Materials Science
Abstract

Microscopy, in particular scanning probe and electron microscopy, has been pivotal in improving our understanding of structure-function relationships at the nanoscale and is by now ubiquitous in most research characterization labs and facilities. However, traditional microscopy operations are still limited largely by a human-centric click-and-go paradigm utilizing vendor-provided software, which necessarily limits the scope, utility, efficiency, effectiveness, and at times reproducibility of microscopy experiments. Here, we develop a coupled hardware-software platform that consists of a field-programmable gate array (FPGA) device, with LabView-built customized acquisition scripts, along with a software package termed AEcroscoPy (short for Automated Experiments in Microscopy driven by Python) that overcome these limitations and provide the necessary abstractions towards full automation of microscopy platforms. The platform works across multiple vendor devices on scanning probe microscopes and scanning transmission electron microscopes. It enables customized scan trajectories, processing functions that can be triggered locally or remotely on processing servers, user-defined excitation waveforms, standardization of data models, and completely seamless operation through simple Python commands to enable a plethora of microscopy experiments to be performed in a reproducible, automated manner. This platform can be readily coupled with existing machine learning libraries as well as simulations, to provide automated decision-making and active theory-experiment optimization loops to turn microscopes from characterization tools to instruments capable of autonomous model refinement and physics discovery., Comment: 19 pages, 9 figures

Published
2023

7. On-demand nanoengineering of in-plane ferroelectric topologies

Author

Checa, Marti, primary, Pant, Bharat, additional, Puretzky, Alexander, additional, Dryzhakov, Bogdan, additional, Vasudevan, Rama, additional, Kavle, Pravin, additional, Dasgupta, Arvind, additional, Martin, Lane, additional, Cao, Ye, additional, Collins, Liam, additional, Jesse, Stephen, additional, Domingo, Neus, additional, and Kelley, Kyle, additional

Published
2024
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8. AEcroscopy: A Software–Hardware Framework Empowering Microscopy Toward Automated and Autonomous Experimentation.

Author

Liu, Yongtao, Roccapriore, Kevin, Checa, Marti, Valleti, Sai Mani, Yang, Jan‐Chi, Jesse, Stephen, and Vasudevan, Rama K.

Subjects
SCANNING transmission electron microscopy, SCANNING probe microscopy, APPLICATION program interfaces, ELECTRON microscopes, INTEGRATED software
Abstract

Microscopy has been pivotal in improving the understanding of structure‐function relationships at the nanoscale and is by now ubiquitous in most characterization labs. However, traditional microscopy operations are still limited largely by a human‐centric click‐and‐go paradigm utilizing vendor‐provided software, which limits the scope, utility, efficiency, effectiveness, and at times reproducibility of microscopy experiments. Here, a coupled software–hardware platform is developed that consists of a software package termed AEcroscopy (short for Automated Experiments in Microscopy), along with a field‐programmable‐gate‐array device with LabView‐built customized acquisition scripts, which overcome these limitations and provide the necessary abstractions toward full automation of microscopy platforms. The platform works across multiple vendor devices on scanning probe microscopes and electron microscopes. It enables customized scan trajectories, processing functions that can be triggered locally or remotely on processing servers, user‐defined excitation waveforms, standardization of data models, and completely seamless operation through simple Python commands to enable a plethora of microscopy experiments to be performed in a reproducible, automated manner. This platform can be readily coupled with existing machine‐learning libraries and simulations, to provide automated decision‐making and active theory‐experiment optimization to turn microscopes from characterization tools to instruments capable of autonomous model refinement and physics discovery. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Evolution of Ferroelectric Properties in SmxBi1–xFeO3via Automated Piezoresponse Force Microscopy across combinatorial spread libraries

Author

Raghavan, Aditya, Pant, Rohit, Takeuchi, Ichiro, Eliseev, Eugene A., Checa, Marti, Morozovska, Anna N., Ziatdinov, Maxim, Kalinin, Sergei V., and Liu, Yongtao

Abstract

Combinatorial spread libraries offer an approach to explore the evolution of material properties over broad concentration, temperature, and growth parameter spaces. However, the traditional limitation of this approach is the requirement for the read-out of functional properties across the library. Here we develop automated piezoresponse force microscopy (PFM) for the exploration of combinatorial spread libraries and demonstrate its application in the SmxBi1–xFeO3system with the ferroelectric–antiferroelectric morphotropic phase boundary. This approach relies on the synergy of the quantitative nature of PFM and the implementation of automated experiments that allow PFM-based sampling of macroscopic samples. The concentration dependence of pertinent ferroelectric parameters was determined and used to develop the mathematical framework based on the Ginzburg–Landau theory describing the evolution of these properties across the concentration space. We pose that a combination of automated scanning probe microscope and combinatorial spread library approach will emerge as an efficient research paradigm to close the characterization gap in high-throughput materials discovery. We make the data sets open to the community, and we hope that this will stimulate other efforts to interpret and understand the physics of these systems.

Published
2024
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10. Armor for Steel: Facile Synthesis of Hexagonal Boron Nitride Films on Various Substrates (Adv. Mater. Interfaces 1/2024)

Author

Vlassiouk, Ivan, primary, Smirnov, Sergei, additional, Puretzky, Alexander, additional, Olunloyo, Olugbenga, additional, Geohegan, David B., additional, Dyck, Ondrej, additional, Lupini, Andrew R., additional, Unocic, Raymond R., additional, Meyer, Harry M., additional, Xiao, Kai, additional, Briggs, Dayrl, additional, Lavrik, Nickolay, additional, Keum, Jong, additional, Cakmak, Ercan, additional, Harris, Sumner B., additional, Checa, Marti, additional, Collins, Liam, additional, Lasseter, John, additional, Emery, Reece, additional, Rayle, John, additional, Rack, Philip D., additional, Stehle, Yijing, additional, Chaturvedi, Pavan, additional, Kidambi, Piran R., additional, Gu, Gong, additional, and Ivanov, Ilia, additional

Published
2024
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11. Enhancing Composite Toughness Through Hierarchical Interphase Formation

Author

Gupta, Sumit, primary, Sohail, Tanvir, additional, Checa, Marti, additional, Rohewal, Sargun S., additional, Toomey, Michael D., additional, Kanbargi, Nihal, additional, Damron, Joshua T., additional, Collins, Liam, additional, Kearney, Logan T., additional, Naskar, Amit K., additional, and Bowland, Christopher C., additional

Published
2023
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12. Armor for Steel: Facile Synthesis of Hexagonal Boron Nitride Films on Various Substrates

Author

Vlassiouk, Ivan, primary, Smirnov, Sergei, additional, Puretzky, Alexander, additional, Olunloyo, Olugbenga, additional, Geohegan, David B., additional, Dyck, Ondrej, additional, Lupini, Andrew R., additional, Unocic, Raymond R., additional, Meyer, Harry M., additional, Xiao, Kai, additional, Briggs, Dayrl, additional, Lavrik, Nickolay, additional, Keum, Jong, additional, Cakmak, Ercan, additional, Harris, Sumner B., additional, Checa, Marti, additional, Collins, Liam, additional, Lasseter, John, additional, Emery, Reece, additional, Rayle, John, additional, Rack, Philip D., additional, Stehle, Yijing, additional, Chaturvedi, Pavan, additional, Kidambi, Piran R., additional, Gu, Gong, additional, and Ivanov, Ilia, additional

Published
2023
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13. Enhancing Composite Toughness Through Hierarchical Interphase Formation.

Author

Gupta, Sumit, Sohail, Tanvir, Checa, Marti, Rohewal, Sargun S., Toomey, Michael D., Kanbargi, Nihal, Damron, Joshua T., Collins, Liam, Kearney, Logan T., Naskar, Amit K., and Bowland, Christopher C.

Subjects
ATOMIC force microscopy, MOLECULAR dynamics, FIBROUS composites, CARBON fibers, SHEAR strength, COVALENT bonds
Abstract

High strength and ductility are highly desired in fiber‐reinforced composites, yet achieving both simultaneously remains elusive. A hierarchical architecture is developed utilizing high aspect ratio chemically transformable thermoplastic nanofibers that form covalent bonding with the matrix to toughen the fiber‐matrix interphase. The nanoscale fibers are electrospun on the micrometer‐scale reinforcing carbon fiber, creating a physically intertwined, randomly oriented scaffold. Unlike conventional covalent bonding of matrix molecules with reinforcing fibers, here, the nanofiber scaffold is utilized ‒ interacting non‐covalently with core fiber but bridging covalently with polymer matrix ‒ to create a high volume fraction of immobilized matrix or interphase around core reinforcing elements. This mechanism enables efficient fiber‐matrix stress transfer and enhances composite toughness. Molecular dynamics simulation reveals enhancement of the fiber‐matrix adhesion facilitated by nanofiber‐aided hierarchical bonding with the matrix. The elastic modulus contours of interphase regions obtained from atomic force microscopy clearly indicate the formation of stiffer interphase. These nanoengineered composites exhibit a ≈60% and ≈100% improved in‐plane shear strength and toughness, respectively. This approach opens a new avenue for manufacturing toughened high‐performance composites. [ABSTRACT FROM AUTHOR]

Published
2024
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17. On-demand nanoengineering of in-plane ferroelectric topologies

Author

Checa, Marti, Pant, Bharat, Puretzky, Alexander, Dryzhakov, Bogdan, Vasudevan, Rama K., Liu, Yongtao, Kavle, Pravin, Dasgupta, Arvind, Martin, Lane W., Cao, Ye, Collins, Liam, Jesse, Stephen, Domingo, Neus, and Kelley, Kyle P.

Abstract

Hierarchical assemblies of ferroelectric nanodomains, so-called super-domains, can exhibit exotic morphologies that lead to distinct behaviours. Controlling these super-domains reliably is critical for realizing states with desired functional properties. Here we reveal the super-switching mechanism by using a biased atomic force microscopy tip, that is, the switching of the in-plane super-domains, of a model ferroelectric Pb0.6Sr0.4TiO3. We demonstrate that the writing process is dominated by a super-domain nucleation and stabilization process. A complex scanning-probe trajectory enables on-demand formation of intricate centre-divergent, centre-convergent and flux-closure polar structures. Correlative piezoresponse force microscopy and optical spectroscopy confirm the topological nature and tunability of the emergent structures. The precise and versatile nanolithography in a ferroic material and the stability of the generated structures, also validated by phase-field modelling, suggests potential for reliable multi-state nanodevice architectures and, thereby, an alternative route for the creation of tunable topological structures for applications in neuromorphic circuits.

Published
2024
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21. Evolution of Ferroelectric Properties in Sm x Bi 1- x FeO 3 via Automated Piezoresponse Force Microscopy across combinatorial spread libraries.

Author

Raghavan A, Pant R, Takeuchi I, Eliseev EA, Checa M, Morozovska AN, Ziatdinov M, Kalinin SV, and Liu Y

Abstract

Combinatorial spread libraries offer an approach to explore the evolution of material properties over broad concentration, temperature, and growth parameter spaces. However, the traditional limitation of this approach is the requirement for the read-out of functional properties across the library. Here we develop automated piezoresponse force microscopy (PFM) for the exploration of combinatorial spread libraries and demonstrate its application in the Sm x Bi 1- x FeO 3 system with the ferroelectric-antiferroelectric morphotropic phase boundary. This approach relies on the synergy of the quantitative nature of PFM and the implementation of automated experiments that allow PFM-based sampling of macroscopic samples. The concentration dependence of pertinent ferroelectric parameters was determined and used to develop the mathematical framework based on the Ginzburg-Landau theory describing the evolution of these properties across the concentration space. We pose that a combination of automated scanning probe microscope and combinatorial spread library approach will emerge as an efficient research paradigm to close the characterization gap in high-throughput materials discovery. We make the data sets open to the community, and we hope that this will stimulate other efforts to interpret and understand the physics of these systems.

Published
2024
Full Text
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22. Revealing Fast Cu-Ion Transport and Enhanced Conductivity at the CuInP 2 S 6 -In 4/3 P 2 S 6 Heterointerface.

Author

Checa M, Jin X, Millan-Solsona R, Neumayer SM, Susner MA, McGuire MA, O'Hara A, Gomila G, Maksymovych P, Pantelides ST, and Collins L

Abstract

Van der Waals layered ferroelectrics, such as CuInP 2 S 6 (CIPS), offer a versatile platform for miniaturization of ferroelectric device technologies. Control of the targeted composition and kinetics of CIPS synthesis enables the formation of stable self-assembled heterostructures of ferroelectric CIPS and nonferroelectric In 4/3 P 2 S 6 (IPS). Here, we use quantitative scanning probe microscopy methods combined with density functional theory (DFT) to explore in detail the nanoscale variability in dynamic functional properties of the CIPS-IPS heterostructure. We report evidence of fast ionic transport which mediates an appreciable out-of-plane electromechanical response of the CIPS surface in the paraelectric phase. Further, we map the nanoscale dielectric and ionic conductivity properties as we thermally stimulate the ferroelectric-paraelectric phase transition, recovering the local dielectric behavior during this phase transition. Finally, aided by DFT, we reveal a substantial and tunable conductivity enhancement at the CIPS/IPS interface, indicating the possibility of engineering its interfacial properties for next generation device applications.

Published
2022
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