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Main Authors: Hassan, Sheikh Md Shakeel, Zou, Xianwei, Dhruv, Akash, Ganesan, Vishwanath, Chandramowlishwaran, Aparna
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.21244
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author Hassan, Sheikh Md Shakeel
Zou, Xianwei
Dhruv, Akash
Ganesan, Vishwanath
Chandramowlishwaran, Aparna
author_facet Hassan, Sheikh Md Shakeel
Zou, Xianwei
Dhruv, Akash
Ganesan, Vishwanath
Chandramowlishwaran, Aparna
contents Modeling boiling (an inherently chaotic, multiphase process central to energy and thermal systems) remains a significant challenge for neural PDE surrogates. Existing models require future input (e.g., bubble positions) during inference because they fail to learn nucleation from past states, limiting their ability to autonomously forecast boiling dynamics. They also fail to model flow boiling velocity fields, where sharp interface-momentum coupling demands long-range and directional inductive biases. We introduce Bubbleformer, a transformer-based spatiotemporal model that forecasts stable and long-range boiling dynamics including nucleation, interface evolution, and heat transfer without dependence on simulation data during inference. Bubbleformer integrates factorized axial attention, frequency-aware scaling, and conditions on thermophysical parameters to generalize across fluids, geometries, and operating conditions. To evaluate physical fidelity in chaotic systems, we propose interpretable physics-based metrics that evaluate heat-flux consistency, interface geometry, and mass conservation. We also release BubbleML 2.0, a high-fidelity dataset that spans diverse working fluids (cryogens, refrigerants, dielectrics), boiling configurations (pool and flow boiling), flow regimes (bubbly, slug, annular), and boundary conditions. Bubbleformer sets new benchmark results in both prediction and forecasting of two-phase boiling flows.
format Preprint
id arxiv_https___arxiv_org_abs_2507_21244
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Bubbleformer: Forecasting Boiling with Transformers
Hassan, Sheikh Md Shakeel
Zou, Xianwei
Dhruv, Akash
Ganesan, Vishwanath
Chandramowlishwaran, Aparna
Machine Learning
Artificial Intelligence
Computational Engineering, Finance, and Science
Modeling boiling (an inherently chaotic, multiphase process central to energy and thermal systems) remains a significant challenge for neural PDE surrogates. Existing models require future input (e.g., bubble positions) during inference because they fail to learn nucleation from past states, limiting their ability to autonomously forecast boiling dynamics. They also fail to model flow boiling velocity fields, where sharp interface-momentum coupling demands long-range and directional inductive biases. We introduce Bubbleformer, a transformer-based spatiotemporal model that forecasts stable and long-range boiling dynamics including nucleation, interface evolution, and heat transfer without dependence on simulation data during inference. Bubbleformer integrates factorized axial attention, frequency-aware scaling, and conditions on thermophysical parameters to generalize across fluids, geometries, and operating conditions. To evaluate physical fidelity in chaotic systems, we propose interpretable physics-based metrics that evaluate heat-flux consistency, interface geometry, and mass conservation. We also release BubbleML 2.0, a high-fidelity dataset that spans diverse working fluids (cryogens, refrigerants, dielectrics), boiling configurations (pool and flow boiling), flow regimes (bubbly, slug, annular), and boundary conditions. Bubbleformer sets new benchmark results in both prediction and forecasting of two-phase boiling flows.
title Bubbleformer: Forecasting Boiling with Transformers
topic Machine Learning
Artificial Intelligence
Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2507.21244