Simulation of flow field in silicon single-crystal growth using physics-informed neural network with spatial information

Shi, Shuyan; Liu, Ding; Huo, Zhiran

doi:10.1063/5.0123811

Physics of Fluids

2022

DOI: 10.1063/5.0123811

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Simulation of flow field in silicon single-crystal growth using physics-informed neural network with spatial information

Shuyan Shi

Ding Liu

Zhiran Huo

Abstract: Melt convection plays a crucial role in the growth of silicon single crystals. In particular, melt flow transfers mass and heat, and it may strongly affect the crystal growth conditions. Understanding and controlling convection remains a significant challenge in industrial crystal production. Currently, the numerical methods such as the finite element method and the finite volume method are mainly used to simulate melt convection in the crystal growth process. However, these methods are not suitable for most a… Show more

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Cited by 5 publications

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“…incorporate physical laws and their ability to provide a flexible structure for the solution PDEs, they have been extensively utilized for the multiphysics modeling of systems in the field of chemical engineering. For example, PINNs have been adopted to model the systems related to heat transfer [10][11][12], compressible and incompressible flows [13][14][15][16][17][18], convection, reaction, and advection-diffusion systems [19][20][21][22][23][24][25]. The applications of the PINN method have also been extended to study of environmental and materials engineering systems, such as, mitigation of carbon emissions [26][27][28][29], and prediction of materials properties [30][31][32].…”

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confidence: 99%

Sequencing Initial Conditions in Physics-Informed Neural Networks

Hooshyar,

Elahi

2024

JCE

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The scientific machine learning (SciML) field has introduced a new class of models called physics-informed neural networks (PINNs). These models incorporate domain-specific knowledge as soft constraints on a loss function and use machine learning techniques to train the model. Although PINN models have shown promising results for simple problems, they are prone to failure when moderate level of complexities are added to the problems. We demonstrate that the existing baseline models, in particular PINN and evolutionary sampling (Evo), are unable to capture the solution to differential equations with convection, reaction, and diffusion operators when the imposed initial condition is non-trivial. We then propose a promising solution to address these types of failure modes. This approach involves coupling Curriculum learning with the baseline models, where the network first trains on PDEs with simple initial conditions and is progressively exposed to more complex initial conditions. Our results show that we can reduce the error by 1 – 2 orders of magnitude with our proposed method compared to regular PINN and Evo.

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confidence: 99%

Sequencing Initial Conditions in Physics-Informed Neural Networks

Hooshyar,

Elahi

2024

JCE

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Enhanced framework for solving general energy equations based on metropolis-hasting Markov chain Monte Carlo

Zhu,

Gao,

Niu

et al. 2024

International Journal of Heat and Mass Transfer

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Simulation of thermal-fluid coupling in silicon single crystal growth based on gradient normalized physics-informed neural network

Shi,

Liu,

Huo

2024

Physics of Fluids

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The thermal-fluid coupling phenomenon of silicon melt is significant in the growth process of silicon single crystals. Complex convection affects the temperature and concentration distribution of the silicon melt. Therefore, establishing and solving the thermal-fluid coupling model of silicon melts is crucial to optimizing the crystal growth process and improving crystal quality. Traditional numerical simulation methods have limitations in regard to optimization, control, and real-time monitoring. Physics-Informed Neural Network (PINN) does not require model discretization, after training, it can make predictions quickly, showing potential for industrial applications. However, when solving practical industrial coupling models, PINN often struggles to converge due to large parameter values and significant gaps between solution variables. Moreover, solving the thermal-fluid coupling model with PINN can be treated as a multitask problem, where the gradients of different equations interfere with each other, leading to gradient confusion, slow convergence, or even divergence. Therefore, this paper proposes a gradient normalized PINN (GNPINN) for solving the thermal-fluid coupling model of silicon melt. GNPINN balances the contribution of each task, ensuring a more equitable training speed between different tasks to stabilize the training process of the coupling model. This paper considers the thermal-fluid coupling model of silicon melt under different rotation conditions. GNPINN can accurately and comprehensively capture the complex temperature, velocity, and pressure distribution of silicon melt compared with other methods. Additionally, the experimental results uncover the flow and heat transfer properties of silicon melt, validating the effectiveness and industrial applicability of GNPINN.

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Simulation of flow field in silicon single-crystal growth using physics-informed neural network with spatial information

Cited by 5 publications

References 48 publications

Sequencing Initial Conditions in Physics-Informed Neural Networks

Sequencing Initial Conditions in Physics-Informed Neural Networks

Enhanced framework for solving general energy equations based on metropolis-hasting Markov chain Monte Carlo

Simulation of thermal-fluid coupling in silicon single crystal growth based on gradient normalized physics-informed neural network

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