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Grant support

We acknowledge the support from the MAD2D-CM project on Twodimensional disruptive materials funded by the Community of Madrid, the Recovery, Transformation and Resilience Plan, Spain, and NextGenerationEU from the European Union. Additionally, M.G. was supported by the U.S. National Science Foundation Division of Material Research, Spain (Grant No. DMR2153316) through the International Research Experience for Students (IRES) program.

Analysis of institutional authors

Özdemir, BurcuAuthor

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Toward 3D printability prediction for thermoplastic polymer nanocomposites: Insights from extrusion printing of PLA-based systems

Publicated to:Additive Manufacturing. 95 104533- - 2024-09-05 95(), DOI: 10.1016/j.addma.2024.104533

Authors: Ozdemir, B; Hernández-del-Valle, M; Gaunt, M; Schenk, C; Echevarría-Pastrana, L; Fernández-Blázquez, JP; Wang, DY; Haranczyk, M

Affiliations

IMDEA Mat Inst, C-Er Kandel 2, Getafe 28906, Madrid, Spain - Author
Michigan State Univ, E Lansing, MI 48824 USA - Author
Univ Carlos III Madrid, Leganes 28911, Madrid, Spain - Author
Univ Politecn Madrid, Madrid 28040, Spain - Author

Abstract

The development of new thermoplastic-based nanocomposites for, as well as using, 3D printing requires extensive experimental testing. One typically goes through many failed, or otherwise sub-optimal, iterations before finding acceptable solutions (e.g. compositions, 3D printing parameters). It is desirable to reduce the number of such iterations as well as exclude failed experiments that often require laborious disassembly and cleaning of the 3D printer. This issue could be addressed if we were able to understand, and ultimately predict ahead of experiments if a given material can be 3D printed successfully. Herein, we report on our investigations into forecasting the printing and resultant properties of polymer nanocomposites while encompassing both material properties and printing parameters, enabling the model to generalize across various thermoplastics and additives. To do so, nanocomposites of two different commercially available bio-based PLAs with varying concentrations of nanoclay (NC) and graphene nanoplatelets (GNP) were prepared using a twin-screw extruder. The thermal and rheological properties of the nanocomposites were analyzed. These materials were printed at varying temperature and flow using a pellet printer. The quality of the printing was evaluated by measuring weight fluctuation, internal diameter of cylindrical specimen, and surface uniformity. The interactions between material properties and printing parameters are complex but captured effectively by a machine learning model, specifically we demonstrate such a predictive model to forecast printability and, printing quality utilizing a Random Forest algorithm. Printability was predicted by developing a classification model with constraints based on the weight fluctuation (Delta W) of the printed sample w.r.t. the optimal print; defining "not printable" for -1.0 = -0.8. The classification model for predicting printability, performed well with an accuracy of 92.8% and identified flow index and complex viscosity, contributing 52% to the model's importance. Another model to predict Delta W of the only on successful prints also showed strong performance, emphasizing the importance of viscoelastic properties, thermal stability, and printing temperature. For diameter change (Delta D-i), the Random Forest model identified flow consistency index, complex viscosity, and thermal stability as influential parameters, with crystallization enthalpy gaining increased importance, reflecting its role in crystallization and shrinkage. In contrast, the surface roughness average (RA) model had lower performance, yet revealed remarkable insights regarding the feature importance with crystallization enthalpy and complex viscosity being most significant.

Keywords

Machine learninMachine learningNanocompositesPellet 3d printerPrintabilityRheologyThermoplastics

Quality index

Bibliometric impact. Analysis of the contribution and dissemination channel

The work has been published in the journal Additive Manufacturing due to its progression and the good impact it has achieved in recent years, according to the agency WoS (JCR), it has become a reference in its field. In the year of publication of the work, 2024 there are still no calculated indicators, but in 2023, it was in position 51/439, thus managing to position itself as a Q1 (Primer Cuartil), in the category Materials Science, Multidisciplinary.

Independientemente del impacto esperado determinado por el canal de difusión, es importante destacar el impacto real observado de la propia aportación.

Según las diferentes agencias de indexación, el número de citas acumuladas por esta publicación hasta la fecha 2025-06-09:

  • Scopus: 2

Impact and social visibility

From the perspective of influence or social adoption, and based on metrics associated with mentions and interactions provided by agencies specializing in calculating the so-called "Alternative or Social Metrics," we can highlight as of 2025-06-09:

  • The use of this contribution in bookmarks, code forks, additions to favorite lists for recurrent reading, as well as general views, indicates that someone is using the publication as a basis for their current work. This may be a notable indicator of future more formal and academic citations. This claim is supported by the result of the "Capture" indicator, which yields a total of: 10 (PlumX).

Leadership analysis of institutional authors

This work has been carried out with international collaboration, specifically with researchers from: United States of America.

There is a significant leadership presence as some of the institution’s authors appear as the first or last signer, detailed as follows: First Author (ÖZDEMIR, BURCU) .