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20 results on '"Liang, Qiaohao"'

1. Physics-based Modeling of Pulse and Relaxation of High-rate Li/CF$_{x}$-SVO batteries in Implantable Medical Devices

Author

Liang, Qiaohao, Galuppini, Giacomo, Gomadam, Partha M., Tamirisa, Prabhakar A., Lemmerman, Jeffrey A., Mazack, Michael J. M., Sullivan, Melani G., Braatz, Richard D., and Bazant, Martin Z.

Subjects
Condensed Matter - Materials Science
Abstract

We present a physics-based model that accurately predicts the performance of Medtronic's implantable medical device battery lithium/carbon monofluoride (CF$_x$) - silver vanadium oxide (SVO) under both low-rate background monitoring and high-rate pulsing currents. The distinct properties of multiple active materials are reflected by parameterizing their thermodynamics, kinetics, and mass transport properties separately. Diffusion limitations of Li$^+$ in SVO are used to explain cell voltage transient behavior during pulse and post-pulse relaxation. We also introduce change in cathode electronic conductivity, Li metal anode surface morphology, and film resistance buildup to capture evolution of cell internal resistance throughout multi-year electrical tests. We share our insights on how the Li$^+$ redistribution process between active materials can restore pulse capability of the hybrid electrode, allow CF$_x$ to indirectly contribute to capacity release during pulsing, and affect the operation protocols and design principles of batteries with other hybrid electrodes. We also discuss additional complexities in porous electrode model parameterization and electrochemical characterization techniques due to parallel reactions and solid diffusion pathways across active materials. We hope our models implemented in the Hybrid Multiphase Porous Electrode Theory (Hybrid-MPET) framework can complement future experimental research and accelerate development of multi-active material electrodes with targeted performance., Comment: For code and sample usage, please visit: https://github.com/HarryQL/Hybrid-MPET/tree/medtronic_pulse

Published
2024

2. Hybrid-MPET: an open-source simulation software for hybrid electrode batteries

Author

Liang, Qiaohao and Bazant, Martin Z.

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

As the design of single-component battery electrodes has matured, the battery industry has turned to hybrid electrodes with blends of two or more active materials to enhance battery performance. Leveraging the best properties of each material while mitigating their drawbacks, multi-component hybrid electrodes open a vast new design space that could be most efficiently explored through simulations. In this article, we introduce a mathematical modeling framework and open-source battery simulation software package for Hybrid Multiphase Porous Electrode Theory (Hybrid-MPET), capable of accounting for the parallel reactions, phase transformations and multiscale heterogeneities in hybrid porous electrodes. Hybrid-MPET models can simulate both solid solution and multiphase active materials in hybrid electrodes at intra-particle and inter-particle scales. Its modular design also allows the combination of different active materials at any capacity fraction. To illustrate the novel features of Hybrid-MPET, we present experimentally validated models of silicon-graphite (Si-Gr) anodes used in electric vehicle batteries and carbon monofluoride (CFx) - silver vanadium oxide (SVO) cathodes used in implantable medical device batteries. The results demonstrate the potential of Hybrid-MPET models to accelerate the development of hybrid electrode batteries by providing fast predictions of their performance over a wide range of design parameters and operating protocols., Comment: For code and sample usage, please visit: https://github.com/HarryQL/Hybrid-MPET

Published
2023

3. Benchmarking the Performance of Bayesian Optimization across Multiple Experimental Materials Science Domains

Author

Liang, Qiaohao, Gongora, Aldair E., Ren, Zekun, Tiihonen, Armi, Liu, Zhe, Sun, Shijing, Deneault, James R., Bash, Daniil, Mekki-Berrada, Flore, Khan, Saif A., Hippalgaonkar, Kedar, Maruyama, Benji, Brown, Keith A., Fisher III, John, and Buonassisi, Tonio

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

In the field of machine learning (ML) for materials optimization, active learning algorithms, such as Bayesian Optimization (BO), have been leveraged for guiding autonomous and high-throughput experimentation systems. However, very few studies have evaluated the efficiency of BO as a general optimization algorithm across a broad range of experimental materials science domains. In this work, we evaluate the performance of BO algorithms with a collection of surrogate model and acquisition function pairs across five diverse experimental materials systems, namely carbon nanotube polymer blends, silver nanoparticles, lead-halide perovskites, as well as additively manufactured polymer structures and shapes. By defining acceleration and enhancement metrics for general materials optimization objectives, we find that for surrogate model selection, Gaussian Process (GP) with anisotropic kernels (automatic relevance detection, ARD) and Random Forests (RF) have comparable performance and both outperform the commonly used GP without ARD. We discuss the implicit distributional assumptions of RF and GP, and the benefits of using GP with anisotropic kernels in detail. We provide practical insights for experimentalists on surrogate model selection of BO during materials optimization campaigns.

Published
2021

4. Predicting antimicrobial activity of conjugated oligoelectrolyte molecules via machine learning

Author

Tiihonen, Armi, Cox-Vazquez, Sarah J., Liang, Qiaohao, Ragab, Mohamed, Ren, Zekun, Hartono, Noor Titan Putri, Liu, Zhe, Sun, Shijing, Zhou, Cheng, Incandela, Nathan C., Limwongyut, Jakkarin, Moreland, Alex S., Jayavelu, Senthilnath, Bazan, Guillermo C., and Buonassisi, Tonio

Subjects
Physics - Applied Physics, Physics - Chemical Physics
Abstract

New antibiotics are needed to battle growing antibiotic resistance, but the development process from hit, to lead, and ultimately to a useful drug, takes decades. Although progress in molecular property prediction using machine-learning methods has opened up new pathways for aiding the antibiotics development process, many existing solutions rely on large datasets and finding structural similarities to existing antibiotics. Challenges remain in modelling of unconventional antibiotics classes that are drawing increasing research attention. In response, we developed an antimicrobial activity prediction model for conjugated oligoelectrolyte molecules, a new class of antibiotics that lacks extensive prior structure-activity relationship studies. Our approach enables us to predict minimum inhibitory concentration for E. coli K12, with 21 molecular descriptors selected by recursive elimination from a set of 5,305 descriptors. This predictive model achieves an R2 of 0.65 with no prior knowledge of the underlying mechanism. We find the molecular representation optimum for the domain is the key to good predictions of antimicrobial activity. In the case of conjugated oligoelectrolytes, a representation reflecting the 3-dimensional shape of the molecules is most critical. Although it is demonstrated with a specific example of conjugated oligoelectrolytes, our proposed approach for creating the predictive model can be readily adapted to other novel antibiotic candidate domains.

Published
2021
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5. An invertible crystallographic representation for general inverse design of inorganic crystals with targeted properties

Author

Ren, Zekun, Tian, Siyu Isaac Parker, Noh, Juhwan, Oviedo, Felipe, Xing, Guangzong, Li, Jiali, Liang, Qiaohao, Zhu, Ruiming, Aberle, Armin G., Sun, Shijing, Wang, Xiaonan, Liu, Yi, Li, Qianxiao, Jayavelu, Senthilnath, Hippalgaonkar, Kedar, Jung, Yousung, and Buonassisi, Tonio

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

Realizing general inverse design could greatly accelerate the discovery of new materials with user-defined properties. However, state-of-the-art generative models tend to be limited to a specific composition or crystal structure. Herein, we present a framework capable of general inverse design (not limited to a given set of elements or crystal structures), featuring a generalized invertible representation that encodes crystals in both real and reciprocal space, and a property-structured latent space from a variational autoencoder (VAE). In three design cases, the framework generates 142 new crystals with user-defined formation energies, bandgap, thermoelectric (TE) power factor, and combinations thereof. These generated crystals, absent in the training database, are validated by first-principles calculations. The success rates (number of first-principles-validated target-satisfying crystals/number of designed crystals) ranges between 7.1% and 38.9%. These results represent a significant step toward property-driven general inverse design using generative models, although practical challenges remain when coupled with experimental synthesis.

Published
2020
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6. High-throughput computation and evaluation of raman spectra.

Author

Liang, Qiaohao, Dwaraknath, Shyam, and Persson, Kristin A

Subjects
Bioengineering
Abstract

Raman spectroscopy is used ubiquitously in the characterization of condensed materials, spanning from biomaterials, minerals to polymers, as it provides a unique fingerprint of local bonding and environment. In this work, we design and demonstrate a robust, automatic computational workflow for Raman spectra that employs first-principle calculations based on density functional perturbation theory. A set of computational results are compared to Raman spectra obtained from established experimental databases to estimate the accuracy of the calculated properties across chemical systems and structures. Details regarding the computational methodology and technical validation are presented along with the format of our publicly available data record.

Published
2019

11. An invertible crystallographic representation for general inverse design of inorganic crystals with targeted properties

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Ren, Zekun, Parker Tian, Siyu Isaac, Noh, Juhwan, Oviedo, Felipe, Xing, Guangzong, Li, Jiali, Liang, Qiaohao, Zhu, Ruiming, Aberle, Armin G, Sun, Shijing, Wang, Xiaonan, Liu, Yi, Li, Qianxiao, Jayavelu, Senthilnath, Hippalgaonkar, Kedar, Jung, Yousung, Buonassisi, Tonio, Massachusetts Institute of Technology. Department of Mechanical Engineering, Ren, Zekun, Parker Tian, Siyu Isaac, Noh, Juhwan, Oviedo, Felipe, Xing, Guangzong, Li, Jiali, Liang, Qiaohao, Zhu, Ruiming, Aberle, Armin G, Sun, Shijing, Wang, Xiaonan, Liu, Yi, Li, Qianxiao, Jayavelu, Senthilnath, Hippalgaonkar, Kedar, Jung, Yousung, and Buonassisi, Tonio

Published
2023

12. Predicting Antimicrobial Activity of Conjugated Oligoelectrolyte Molecules via Machine Learning

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Singapore-MIT Alliance in Research and Technology (SMART), Tiihonen, Armi, Cox-Vazquez, Sarah J., Liang, Qiaohao, Ragab, Mohamed, Ren, Zekun, Hartono, Noor Titan Putri, Liu, Zhe, Sun, Shijing, Zhou, Cheng, Incandela, Nathan C., Limwongyut, Jakkarin, Moreland, Alex S., Jayavelu, Senthilnath, Bazan, Guillermo C., Buonassisi, Tonio, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Singapore-MIT Alliance in Research and Technology (SMART), Tiihonen, Armi, Cox-Vazquez, Sarah J., Liang, Qiaohao, Ragab, Mohamed, Ren, Zekun, Hartono, Noor Titan Putri, Liu, Zhe, Sun, Shijing, Zhou, Cheng, Incandela, Nathan C., Limwongyut, Jakkarin, Moreland, Alex S., Jayavelu, Senthilnath, Bazan, Guillermo C., and Buonassisi, Tonio

Abstract

New antibiotics are needed to battle growing antibiotic resistance, but the development process from hit, to lead, and ultimately to a useful drug, takes decades. Although progress in molecular property prediction using machine-learning methods has opened up new pathways for aiding the antibiotics development process, many existing solutions rely on large datasets and finding structural similarities to existing antibiotics. Challenges remain in modelling of unconventional antibiotics classes that are drawing increasing research attention. In response, we developed an antimicrobial activity prediction model for conjugated oligoelectrolyte molecules, a new class of antibiotics that lacks extensive prior structure-activity relationship studies. Our approach enables us to predict minimum inhibitory concentration for E. coli K12, with 21 molecular descriptors selected by recursive elimination from a set of 5,305 descriptors. This predictive model achieves an R2 of 0.65 with no prior knowledge of the underlying mechanism. We find the molecular representation optimum for the domain is the key to good predictions of antimicrobial activity. In the case of conjugated oligoelectrolytes, a representation reflecting the 3-dimensional shape of the molecules is most critical. Although it is demonstrated with a specific example of conjugated oligoelectrolytes, our proposed approach for creating the predictive model can be readily adapted to other novel antibiotic candidate domains.

Published
2022

13. Benchmarking the performance of Bayesian optimization across multiple experimental materials science domains

Author

Liang, Qiaohao, primary, Gongora, Aldair E., additional, Ren, Zekun, additional, Tiihonen, Armi, additional, Liu, Zhe, additional, Sun, Shijing, additional, Deneault, James R., additional, Bash, Daniil, additional, Mekki-Berrada, Flore, additional, Khan, Saif A., additional, Hippalgaonkar, Kedar, additional, Maruyama, Benji, additional, Brown, Keith A., additional, Fisher III, John, additional, and Buonassisi, Tonio, additional

Published
2021
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14. Predicting Antimicrobial Activity of Conjugated Oligoelectrolyte Molecules via Machine Learning

Author

Tiihonen, Armi, primary, Cox-Vazquez, Sarah J., additional, Liang, Qiaohao, additional, Ragab, Mohamed, additional, Ren, Zekun, additional, Hartono, Noor Titan Putri, additional, Liu, Zhe, additional, Sun, Shijing, additional, Zhou, Cheng, additional, Incandela, Nathan C., additional, Limwongyut, Jakkarin, additional, Moreland, Alex S., additional, Jayavelu, Senthilnath, additional, Bazan, Guillermo C., additional, and Buonassisi, Tonio, additional

Published
2021
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15. Benchmarking the performance of Bayesian optimization across multiple experimental materials science domains

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Mechanical Engineering, Singapore-MIT Alliance in Research and Technology (SMART), Liang, Qiaohao, Gongora, Aldair E, Ren, Zekun, Tiihonen, Armi, Liu, Zhe, Sun, Shijing, Deneault, James R, Bash, Daniil, Mekki-Berrada, Flore, Khan, Saif A, Hippalgaonkar, Kedar, Maruyama, Benji, Brown, Keith A, Fisher III, John, Buonassisi, Tonio, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Mechanical Engineering, Singapore-MIT Alliance in Research and Technology (SMART), Liang, Qiaohao, Gongora, Aldair E, Ren, Zekun, Tiihonen, Armi, Liu, Zhe, Sun, Shijing, Deneault, James R, Bash, Daniil, Mekki-Berrada, Flore, Khan, Saif A, Hippalgaonkar, Kedar, Maruyama, Benji, Brown, Keith A, Fisher III, John, and Buonassisi, Tonio

Abstract

AbstractBayesian optimization (BO) has been leveraged for guiding autonomous and high-throughput experiments in materials science. However, few have evaluated the efficiency of BO across a broad range of experimental materials domains. In this work, we quantify the performance of BO with a collection of surrogate model and acquisition function pairs across five diverse experimental materials systems. By defining acceleration and enhancement metrics for materials optimization objectives, we find that surrogate models such as Gaussian Process (GP) with anisotropic kernels and Random Forest (RF) have comparable performance in BO, and both outperform the commonly used GP with isotropic kernels. GP with anisotropic kernels has demonstrated the most robustness, yet RF is a close alternative and warrants more consideration because it is free from distribution assumptions, has smaller time complexity, and requires less effort in initial hyperparameter selection. We also raise awareness about the benefits of using GP with anisotropic kernels in future materials optimization campaigns.

Published
2021

16. An Invertible Crystallographic Representation for General Inverse Design of Inorganic Crystals with Targeted Properties

Author

Ren, Zekun, primary, Tian, Siyu Isaac Parker, additional, Noh, Juhwan, additional, Oviedo, Felipe, additional, Xing, Guangzong, additional, Liang, Qiaohao, additional, Zhu, Ruiming, additional, Aberle, Armin, additional, Sun, Shijing, additional, Wang, Xiaonan, additional, Liu, Yi, additional, Li, Qianxiao, additional, Jayavelu, Senthilnath, additional, Hippalgaonkar, Kedar, additional, Jun, Yousung, additional, and Buonassisi, Tonio, additional

Published
2021
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17. Modeling of pulse and relaxation of high-rate Li/CFx-SVO batteries in implantable medical devices.

Author

Liang, Qiaohao, Galuppini, Giacomo, Gomadam, Partha M., Tamirisa, Prabhakar A., Lemmerman, Jeffrey A., Mazack, Michael J.M., Sullivan, Melani G., Braatz, Richard D., and Bazant, Martin Z.

Subjects
*ARTIFICIAL implants, *MEDICAL equipment, *ELECTRODE performance, *POROUS electrodes, *GRAPHITE fluorides, *LITHIUM cells
Abstract

We present a Hybrid Multiphase Porous Electrode Theory (Hybrid-MPET) model that accurately predicts the performance of Medtronic's implantable medical device battery lithium/carbon monofluoride (C F x) - silver vanadium oxide (SVO) under both low-rate background monitoring and high-rate pulsing currents. The distinct properties of multiple active materials are reflected by parameterizing their thermodynamics, kinetics, and mass transport properties separately. Diffusion limitations of Li + in SVO are used to explain cell voltage transient behavior during pulse and post-pulse relaxation. We also introduce change in cathode electronic conductivity, Li metal anode surface morphology, and film resistance buildup to capture evolution of cell internal resistance throughout multi-year electrical tests. We share our insights on how the Li + redistribution process between active materials can restore pulse capability of the hybrid electrode, allow C F x to indirectly contribute to capacity release during pulsing, and affect the operation protocols and design principles of batteries with other hybrid electrodes. We also discuss additional complexities in porous electrode model parameterization and electrochemical characterization techniques due to parallel reactions and solid diffusion pathways across active materials. We hope our models can complement future experimental research and accelerate development of multi-active material electrodes with targeted performance. • Hybrid-MPET model of Medtronic's high-rate Li/CF x -SVO battery is presented. • Separate material properties, diffusion limitation, and aging are accounted for. • Model prediction accuracy is validated on large battery dataset. • Cell pulse capability restoration is explained by Li+ redistribution across materials. • Li+ redistribution impact on general cell operation and design principles are discussed. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Improving diagnostics and prognostics of implantable cardioverter defibrillator batteries with interpretable machine learning models.

Author

Galuppini, Giacomo, Liang, Qiaohao, Tamirisa, Prabhakar A., Lemmerman, Jeffrey A., Sullivan, Melani G., Mazack, Michael J.M., Gomadam, Partha M., Bazant, Martin Z., and Braatz, Richard D.

Subjects
*MACHINE learning, *IMPLANTABLE cardioverter-defibrillators, *DEFIBRILLATORS, *CARDIAC pacing, *GRAPHITE fluorides, *LITHIUM cells, *VANADIUM oxide
Abstract

Medtronic Implantable Cardioverter Defibrillators (ICDs) and Cardiac Resynchronization Therapy Defibrillators (CRT-Ds) rely on high-energy density, lithium batteries, which are manufactured with a special lithium/carbon monofluoride (C F x)–silver vanadium oxide (SVO) hybrid cathode design. Consistently high battery performance is crucial for this application, since poor performance may result in ineffective patient treatment, whereas early replacement may involve surgery and increase in maintenance costs. To evaluate performance, batteries are tested, both at the time of production and post-production, through periodic sampling carried out over multiple years. This considerable amount of experimental data is exploited for the first time in this work to develop a data-driven, machine learning approach, relying on Generalized Additive Models (GAMs) to predict battery performance, based on production data. GAMs combine prediction accuracy, which enables evaluation of battery performance immediately after production, with model interpretability, which provides clues on how to further improve battery design and production. Model interpretation allows to identify key features from the battery production data that offer physical insights to support future battery development, and foster the development of physics-based model for hybrid cathode batteries. The proposed approach is validated on 21 different datasets, targeting several performance-related features, and delivers consistently high prediction accuracy on test data. • ICD battery reliability is ensured with life-test experiments spanning multiple years. • ML provides accurate prediction of life-test experiments based on production data. • Interpretable ML fosters the development of battery design and physics-based models. • Approach is validated on 21 datasets, analysed for the first time in the literature. [ABSTRACT FROM AUTHOR]

Published
2024
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