Multiscale modeling-enabled design of multifunctional composites

Sumit Gupta; Tanvir Sohail; Amit K. Naskar; Christopher C. Bowland

doi:10.1117/12.3011931

Multiscale modeling-enabled design of multifunctional composites

Sumit Gupta
, Tanvir Sohail
, Amit K. Naskar
, Christopher C. Bowland

Carbon and Composites

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

This study aims to create a comprehensive model that considers multiple scales and physics for predicting the electromechanical behavior of fiber-reinforced composites enhanced with barium titanate (BaTiO3). In our earlier work, we have demonstrated that depositing BaTiO3 microparticles of 200-nm-diameter, on fiber surfaces during fiber-reinforced composite fabrication enhances mechanical strength, passive self-sensing, and energy harvesting properties. The key is to carefully control the microparticle concentration to prevent agglomeration. Since the particles are micron-sized, understanding how agglomeration affects the composites' electromechanical properties is crucial for guiding such multifunctional materials' design. This study introduces a micromechanics-based approach to explore the impact of microparticle dispersion on the bulk composites' electromechanical properties. Insights gained from this investigation are applied in experiments, enabling accurate predictions of mechanical and self-sensing responses in BaTiO3-enhanced fiber-reinforced composites. Micro-level findings from this computational approach can be integrated into larger continuum models to comprehensively capture the electromechanical behavior of the composite structures at bulk scale. The proposed model is validated by comparing predictions with experimental results, accounting for the nonlinear mechanical and electromechanical behaviors of constituent materials. Consequently, this computational model serves as a digital platform for efficiently designing multifunctional composites.

Original language	English
Title of host publication	Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII
Editors	Andrew L. Gyekenyesi, Peter J. Shull, H. Felix Wu, Tzuyang Yu
Publisher	SPIE
ISBN (Electronic)	9781510672062
DOIs	https://doi.org/10.1117/12.3011931
State	Published - 2024
Event	Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII 2024 - Long Beach, United States Duration: Mar 25 2024 → Mar 27 2024

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	12950
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII 2024
Country/Territory	United States
City	Long Beach
Period	03/25/24 → 03/27/24

Funding

This research at Oak Ridge National Laboratory, managed by UT Battelle, LLC for the US Department of Energy (DOE) under Contract No. DE-AC05-00OR22725, was sponsored by the Vehicle Technologies Office (VTO) (Award #: DE-LC- 0000021) within the Office of Energy Efficiency and Renewable Energy (EERE).

Keywords

Barium titanate
computational modeling
energy harvesting
fiber-reinforced composites
micromechanics
self-sensing

Access to Document

10.1117/12.3011931

Cite this

Gupta, S., Sohail, T., Naskar, A. K., & Bowland, C. C. (2024). Multiscale modeling-enabled design of multifunctional composites. In A. L. Gyekenyesi, P. J. Shull, H. F. Wu, & T. Yu (Eds.), Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII Article 129500N (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12950). SPIE. https://doi.org/10.1117/12.3011931

Gupta, Sumit ; Sohail, Tanvir ; Naskar, Amit K. et al. / Multiscale modeling-enabled design of multifunctional composites. Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII. editor / Andrew L. Gyekenyesi ; Peter J. Shull ; H. Felix Wu ; Tzuyang Yu. SPIE, 2024. (Proceedings of SPIE - The International Society for Optical Engineering).

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abstract = "This study aims to create a comprehensive model that considers multiple scales and physics for predicting the electromechanical behavior of fiber-reinforced composites enhanced with barium titanate (BaTiO3). In our earlier work, we have demonstrated that depositing BaTiO3 microparticles of 200-nm-diameter, on fiber surfaces during fiber-reinforced composite fabrication enhances mechanical strength, passive self-sensing, and energy harvesting properties. The key is to carefully control the microparticle concentration to prevent agglomeration. Since the particles are micron-sized, understanding how agglomeration affects the composites' electromechanical properties is crucial for guiding such multifunctional materials' design. This study introduces a micromechanics-based approach to explore the impact of microparticle dispersion on the bulk composites' electromechanical properties. Insights gained from this investigation are applied in experiments, enabling accurate predictions of mechanical and self-sensing responses in BaTiO3-enhanced fiber-reinforced composites. Micro-level findings from this computational approach can be integrated into larger continuum models to comprehensively capture the electromechanical behavior of the composite structures at bulk scale. The proposed model is validated by comparing predictions with experimental results, accounting for the nonlinear mechanical and electromechanical behaviors of constituent materials. Consequently, this computational model serves as a digital platform for efficiently designing multifunctional composites.",

keywords = "Barium titanate, computational modeling, energy harvesting, fiber-reinforced composites, micromechanics, self-sensing",

author = "Sumit Gupta and Tanvir Sohail and Naskar, \{Amit K.\} and Bowland, \{Christopher C.\}",

note = "Publisher Copyright: {\textcopyright} COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.; Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII 2024 ; Conference date: 25-03-2024 Through 27-03-2024",

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language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

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Gupta, S, Sohail, T, Naskar, AK & Bowland, CC 2024, Multiscale modeling-enabled design of multifunctional composites. in AL Gyekenyesi, PJ Shull, HF Wu & T Yu (eds), Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII., 129500N, Proceedings of SPIE - The International Society for Optical Engineering, vol. 12950, SPIE, Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII 2024, Long Beach, United States, 03/25/24. https://doi.org/10.1117/12.3011931

Multiscale modeling-enabled design of multifunctional composites. / Gupta, Sumit; Sohail, Tanvir; Naskar, Amit K. et al.
Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII. ed. / Andrew L. Gyekenyesi; Peter J. Shull; H. Felix Wu; Tzuyang Yu. SPIE, 2024. 129500N (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12950).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Multiscale modeling-enabled design of multifunctional composites

AU - Gupta, Sumit

AU - Sohail, Tanvir

AU - Naskar, Amit K.

AU - Bowland, Christopher C.

N1 - Publisher Copyright: © COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.

PY - 2024

Y1 - 2024

N2 - This study aims to create a comprehensive model that considers multiple scales and physics for predicting the electromechanical behavior of fiber-reinforced composites enhanced with barium titanate (BaTiO3). In our earlier work, we have demonstrated that depositing BaTiO3 microparticles of 200-nm-diameter, on fiber surfaces during fiber-reinforced composite fabrication enhances mechanical strength, passive self-sensing, and energy harvesting properties. The key is to carefully control the microparticle concentration to prevent agglomeration. Since the particles are micron-sized, understanding how agglomeration affects the composites' electromechanical properties is crucial for guiding such multifunctional materials' design. This study introduces a micromechanics-based approach to explore the impact of microparticle dispersion on the bulk composites' electromechanical properties. Insights gained from this investigation are applied in experiments, enabling accurate predictions of mechanical and self-sensing responses in BaTiO3-enhanced fiber-reinforced composites. Micro-level findings from this computational approach can be integrated into larger continuum models to comprehensively capture the electromechanical behavior of the composite structures at bulk scale. The proposed model is validated by comparing predictions with experimental results, accounting for the nonlinear mechanical and electromechanical behaviors of constituent materials. Consequently, this computational model serves as a digital platform for efficiently designing multifunctional composites.

AB - This study aims to create a comprehensive model that considers multiple scales and physics for predicting the electromechanical behavior of fiber-reinforced composites enhanced with barium titanate (BaTiO3). In our earlier work, we have demonstrated that depositing BaTiO3 microparticles of 200-nm-diameter, on fiber surfaces during fiber-reinforced composite fabrication enhances mechanical strength, passive self-sensing, and energy harvesting properties. The key is to carefully control the microparticle concentration to prevent agglomeration. Since the particles are micron-sized, understanding how agglomeration affects the composites' electromechanical properties is crucial for guiding such multifunctional materials' design. This study introduces a micromechanics-based approach to explore the impact of microparticle dispersion on the bulk composites' electromechanical properties. Insights gained from this investigation are applied in experiments, enabling accurate predictions of mechanical and self-sensing responses in BaTiO3-enhanced fiber-reinforced composites. Micro-level findings from this computational approach can be integrated into larger continuum models to comprehensively capture the electromechanical behavior of the composite structures at bulk scale. The proposed model is validated by comparing predictions with experimental results, accounting for the nonlinear mechanical and electromechanical behaviors of constituent materials. Consequently, this computational model serves as a digital platform for efficiently designing multifunctional composites.

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KW - computational modeling

KW - energy harvesting

KW - fiber-reinforced composites

KW - micromechanics

KW - self-sensing

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DO - 10.1117/12.3011931

M3 - Conference contribution

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T3 - Proceedings of SPIE - The International Society for Optical Engineering

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A2 - Shull, Peter J.

A2 - Wu, H. Felix

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PB - SPIE

T2 - Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII 2024

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Gupta S, Sohail T, Naskar AK , Bowland CC. Multiscale modeling-enabled design of multifunctional composites. In Gyekenyesi AL, Shull PJ, Wu HF, Yu T, editors, Nondestructive Characterization and Monitoring of Advanced Materials, Aerospace, Civil Infrastructure, and Transportation XVIII. SPIE. 2024. 129500N. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.3011931

Multiscale modeling-enabled design of multifunctional composites

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