Update papers.bib

_bibliography/papers.bib

@@ -117,21 +117,19 @@ @article{lengPredictingMechanicalProperties2021
 
 
 
-@article{tacMicromechanicalModellingCarbon2019,
-  title = {Micromechanical Modelling of Carbon Nanotube Reinforced Composite Materials with a Functionally Graded Interphase},
-  author = {Taç, Vahidullah and G{\"u}rses, Ercan},
-  abstract = {This paper introduces a new method of determining the mechanical properties of carbon nanotube-polymer composites using a multi-inclusion micromechanical model with functionally graded phases. The nanocomposite was divided into four regions of distinct mechanical properties; the carbon nanotube, the interface, the interphase and bulk polymer. The carbon nanotube and the interface were later combined into one effective fiber using a finite element model. The interphase was modelled in a functionally graded manner to reflect the true nature of the portion of the polymer surrounding the carbon nanotube. The three phases of effective fiber, interphase and bulk polymer were then used in the micromechanical model to arrive at the mechanical properties of the nanocomposite. An orientation averaging integration was then applied on the results to better reflect macroscopic response of nanocomposites with randomly oriented nanotubes. The results were compared to other numerical and experimental findings in the literature.},
-  year = {2019},
-  month = dec,
-  journal = {Journal of Composite Materials},
-  volume = {53},
-  number = {28-30},
-  pages = {4337--4348},
-  issn = {0021-9983, 1530-793X},
-  doi = {10.1177/0021998319857126},
-  langid = {english},
-  bibtex_show={true},
-  url = {http://journals.sagepub.com/doi/10.1177/0021998319857126},
+@article{COSTAS2020103966,
+title = {Testing and simulation of additively manufactured AlSi10Mg components under quasi-static loading},
+journal = {European Journal of Mechanics - A/Solids},
+volume = {81},
+pages = {103966},
+year = {2020},
+issn = {0997-7538},
+doi = {https://doi.org/10.1016/j.euromechsol.2020.103966},
+url = {https://www.sciencedirect.com/science/article/pii/S0997753819306758},
+author = {Miguel Costas and David Morin and Mario {de Lucio} and Magnus Langseth},
+keywords = {Additive manufacturing, AlSi10Mg, 3D-printed aluminium, Lateral crushing, Finite elements},
+abstract = {An experimental and numerical study on the quasi-static loading of AlSi10Mg square boxes produced by selective laser melting (SLM) was carried out. The goal was to evaluate the applicability of common finite element modelling techniques to 3D-printed parts at material and component scales, under large deformations and fracture. Uniaxial tensile specimens were extracted and tested at different orientations, and a hypo-elastic–plastic model with Voce hardening and Cockcroft–Latham’s fracture criterion was calibrated against the experimental results. The boxes were crushed laterally until failure using a spherical actuator. The considered material and finite element models were proved well suited for the prediction of the structural response of the additively manufactured components in the studied scenario.},
+bibtex_show={true},
 }