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Word cloudA word cloud is a visual representation of the most frequently used words in a text or a set of texts. The words appear in different sizes, with the size of each word being proportional to its frequency of occurrence in the text. The more frequently a word is used, the larger it appears in the word cloud. This technique allows for a quick visualization of the most important themes and concepts in a text.
In the context of this page, the word cloud was generated from the publications of the author {}. The words in this cloud come from the titles, abstracts, and keywords of the author's articles and research papers. By analyzing this word cloud, you can get an overview of the most recurring and significant topics and research areas in the author's work.
The word cloud is a useful tool for identifying trends and main themes in a corpus of texts, thus facilitating the understanding and analysis of content in a visual and intuitive way.
Chakraborty, A., Tangestani, R., Esmati, K., Sabiston, T., Yuan, L., & Martin, É. (2023). Mitigating inherent micro-cracking in laser additively manufactured RENE 108 thin-wall components. Thin-Walled Structures, 184, 110514 (11 pages). External link
Chakraborty, A., Tangestani, R., Sabiston, T., Krutz, N., Yuan, L., & Martin, É. (2022, February). Effect of Build Height on Micro-cracking of Additively Manufactured Superalloy RENÉ 108 Thin-Wall Components [Paper]. 151st TMS Meeting & Exhibition - Supplemental Proceedings (TMS 2022), Anaheim, California, USA. External link
Chakraborty, A., Tangestani, R., Batmaz, R., Muhammad, W., Plamondon, P., Wessman, A., Yuan, L., & Martin, É. (2022). In-process failure analysis of thin-wall structures made by laser powder bed fusion additive manufacturing. Journal of Materials Science and Technology, 98, 233-243. External link
Deldar Masrour, P., Tangestani, R., Farrahi, G., Martin, É., Yuan, L., & Zhang, T. (2023). Track-scale anisotropic thermal material model as a viable substitution in selective laser melting. Journal of Design Against Fatiguq, 1(3), 19-33. External link
Tangestani, R., Chakraborty, A., Sabiston, T., Yuan, L., Ghasri-Khouzani, M., & Martin, É. (2023). Multi-Scale Model to Simulate Stress Directionality in Laser Powder Bed Fusion: Application to Thin-Wall Part Failure. Materials & Design, 232, 112147 (17 pages). Available
Tangestani, R., Chakraborty, A., Sabiston, T., Yuan, L., & Martin, É. (2023). Buckling mechanism simulation for thin-wall components made by laser powder bed fusion. Key Engineering Materials, 964, 6 pages. External link
Tangestani, R., Sabiston, T., Chakraborty, A., Yuan, L., Krutz, N., & Martin, É. (2021). An Efficient Track-Scale Model for Laser Powder Bed Fusion Additive Manufacturing: Part 2-Mechanical Model. Frontiers in Materials, 8, 759669 (14 pages). External link
