An Efficient Instance Segmentation Approach for Studying Fission Gas Bubbles in Irradiated Metallic Nuclear Fuel

Abstract: Gaseous fission products from nuclear fission reactions tend to form fission gas bubbles of various shapes and sizes inside nuclear fuel. The behavior of fission gas bubbles dictates nuclear fuel performances, such as fission gas release, grain growth, swelling, and fuel cladding mechanical interaction. A mechanical understanding of fission gas bubble evolution behavior is a prerequisite for fuel development and qualification. Historical characterization of fission gas bubbles in irradiated nuclear fuel relied… Show more

“…[14][15][16][17] Recently, Sun et al performed a study where a multi-task deep learning (DL) network was employed for instance segmentation to elucidate fission gas bubbles within nuclear fuel. 18 Anderson et al utilized DL to autonomously identify helium bubbles in irradiated micrographs and to extract their radii and cumulative volumes. The model exhibited a high accuracy, achieving a 93% success rate in the detection of bubbles on high-magnification micrographs, and maintained robust performance in analyzing lower magnification samples.…”

Deep learning-enhanced characterization of bubble dynamics in proton exchange membrane water electrolyzers

“…[14][15][16][17] Recently, Sun et al performed a study where a multi-task deep learning (DL) network was employed for instance segmentation to elucidate fission gas bubbles within nuclear fuel. 18 Anderson et al utilized DL to autonomously identify helium bubbles in irradiated micrographs and to extract their radii and cumulative volumes. The model exhibited a high accuracy, achieving a 93% success rate in the detection of bubbles on high-magnification micrographs, and maintained robust performance in analyzing lower magnification samples.…”

Deep learning-enhanced characterization of bubble dynamics in proton exchange membrane water electrolyzers