Determination of Stresses in Incrementally Deposited Films From Wafer-Curvature Measurements

Rao, Zhaoxia; Jin, Hanxun; Engwall, A. M.; Chason, E.; Kim, Kyung-Suk

doi:10.1115/1.4047572

Cited by 3 publications

(2 citation statements)

References 16 publications

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“…32 By incorporating speckle information into the incremental formulation, we anticipate improvements in convergence speed and applicability to more complex sample structures. In addition to the identification of the materials parameters for constitutive models, the current PINNs framework integrating with DIC data and loading history curves can be applied to extract other material properties, such as cohesive zone parameters, 17,57 residual stress in thin films, 58,59 and the flow resistance. 60…”

Section: Discussionmentioning

confidence: 99%

Identifying constitutive parameters for complex hyperelastic materials using physics-informed neural networks

Song,

Jin

2024

Soft Matter

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Section: Discussionmentioning

confidence: 99%

Identifying constitutive parameters for complex hyperelastic materials using physics-informed neural networks

Song,

Jin

2024

Soft Matter

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“…The emerging development of nanotechnology and biotechnology in recent several decades continuously requires a new understanding of micro-and nano-scale material behaviors. For example, much research has been conducted on understanding the mechanical properties of thin films [177,178,179,180,181,182,183,184,185], nanos-tructured metals [186,187,188,189,190], sub-micron-sized sensors [191], crystalline nanowires [192,193,194,195,196,197], 2D materials [198,199,200,201,202], origami [203], nanolattice metamaterials [204,205,206], and copolymers with nanoscale features [53,207,208,209]. Conducting precise experiments to characterize these materials with small-scale features is essential to understand their properties, underlining mechanisms, and develop constitutive models.…”

Section: Micro and Nano-mechanicsmentioning

confidence: 99%

Recent Advances and Applications of Machine Learning in Experimental Solid Mechanics: A Review

Jin¹,

Zhang²,

Espinosa³

2023

Preprint

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For many decades, experimental solid mechanics has played a crucial role in characterizing and understanding the mechanical properties of natural and novel materials. Recent advances in machine learning (ML) provide new opportunities for the field, including experimental design, data analysis, uncertainty quantification, and inverse problems. As the number of papers published in recent years in this emerging field is exploding, it is timely to conduct a comprehensive and up-to-date review of recent ML applications in experimental solid mechanics. Here, we first provide an overview of common ML algorithms and terminologies that are pertinent to this review, with emphasis placed on physics-informed and physics-based ML methods. Then, we provide thorough coverage of recent ML applications in traditional and emerging areas of experimental mechanics, including fracture mechanics, biomechanics, nano-and micro-mechanics, architected materials, and 2D material. Finally, we highlight some current challenges of applying ML to multi-modality and multi-fidelity experimental datasets and propose several future research directions. This review aims to provide valuable insights into the use of ML methods as well as a variety of examples for researchers in solid mechanics to integrate into their experiments.

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Sputter-deposited low-stress boron carbide films

Engwall

Aji

Shin

et al. 2020

Journal of Applied Physics

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Significant challenges have been faced in the manufacturing of low-stress B4C films. Here, we demonstrate a set of process parameters for direct-current magnetron sputter deposition of smooth, high-purity, amorphous B4C films with near-zero total residual stress and with thicknesses up to 10 μm. Films are characterized by a combination of high-energy ion scattering, x-ray diffraction, electron microscopy, and stress measurements based on substrate curvature. In order to facilitate the process transfer to other sputtering geometries, the favorable deposition conditions are correlated with distributions of landing energies and incident angles of depositing species estimated by Monte Carlo simulations of ballistic collisions and gas phase atomic transport. Based on such simulations, a decrease in compressive stress with increasing Ar working gas pressure is attributed to the corresponding broadening of the angular distribution of depositing species and associated atomic shadowing effects.

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Determination of Stresses in Incrementally Deposited Films From Wafer-Curvature Measurements

Cited by 3 publications

References 16 publications

Identifying constitutive parameters for complex hyperelastic materials using physics-informed neural networks

Identifying constitutive parameters for complex hyperelastic materials using physics-informed neural networks

Recent Advances and Applications of Machine Learning in Experimental Solid Mechanics: A Review

Sputter-deposited low-stress boron carbide films

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