Your search keyword '"Fernandes, Auguste"' showing total 2 results

1. Reversible imine crosslinking in waterborne self-healing polymer coatings

Author

Martins, Tiago D., Viciosa, M. Teresa, Oliveira, Mariana B., Fernandes, Auguste, Mano, João F., Baleizão, Carlos, and Farinha, José Paulo S.

Subjects

Polymer nanoparticles, Dynamic covalent bonds, Waterborne polymer coatings, Imine bond formation, General Chemical Engineering, Organic Chemistry, Self-healing, Materials Chemistry, Surfaces, Coatings and Films

Abstract

Waterborne polymer coatings have the potential to address the environmental concerns associated with solvent based systems. To improve their performance without using volatile organic compounds, we propose a new approach based on reconfigurable covalent crosslinking that provides mechanical resistance and self-healing properties. The new waterborne polymer coatings are based on mixtures of aldehyde- and amine-functionalized polymer nanoparticles (PNPs) that take advantage of the reversibility of imine bonds in the presence of water. Different degrees of functional monomer incorporation (10 % to 40 %) allowed us to balance crosslinking and interdiffusion during film formation, to obtain mechanically robust and solvent resistant films. A clear structure-properties relation was assessed by following the formation of water resulting from amine-aldehyde condensation crosslinking, measured by differential scanning calorimetry. The resulting polymer coatings further show self-healing properties at room temperature, triggered with residual amounts of water and featuring high recovery rates of the mechanical properties. Our mechanically robust waterborne polymer coatings based in imine reversible crosslinking, featuring self-healing in mild conditions, offer excellent prospects for application in smart coating materials. published

Published

2023

2. A novel approach for preparation of nanocomposites with an excellent rigidity/deformability balance based on reinforced HDPE with halloysite

Author

Cecílio, Duarte M., Cerrada, Maria L., Pérez, Ernesto, Fernandes, Auguste, Lourenço, João P., McKenna, Timothy F. L., Ribeiro, M. Rosário, Fundação para a Ciência e a Tecnologia (Portugal), Agencia Estatal de Investigación (España), and Universidade do Algarve (Portugal)

Subjects

Mechanical response, Polymers and Plastics, Polyethylene, Organic Chemistry, Keywords: Halloysite Polyethylene In-situ catalyst support Mechanical response, Materials Chemistry, General Physics and Astronomy, Halloysite, In-situ catalyst support

Abstract

An innovative approach, designated as supported activator (SA), allows preparation of high density polyethylene (HDPE)-based highly performant hybrid materials. This procedure makes use of a nano-sized supported methylaluminoxane (MAO)-activator, based on halloysite natural nanotubes (HNT), combined with an in situ supporting concept. The new protocol when compared with a more conventional approach gives rise to higher polymerization activities as well as ultimate materials with better morphological features, greater crystallinity, thicker crystals, and highly increased stiffness. Moreover, a remarkable synergy between rigidity and toughness is attained. The Young's modulus of a film obtained from the nanocomposite with the highest HNT content increases more than 70 % relatively to a pristine HDPE film, while retaining the limit stretching ability of pristine HDPE (more than 800%). A beneficial impact of using a high aspect ratio support such as HNT in the mechanical properties is also observed, when compared to similar HDPE hybrid materials derived from dendrimer-like silica (DS) nanospheres. Interestingly, polymerization activity, polymer features and derived properties found in the ultimate materials are less impacted by support/filler nature than by preparation method. This fact highlights the crucial role of the synthetic methodology used and corroborates the high potential of the SA route for the preparation of high-performance polyethylene-based nanocomposites with an excellent balance between stiffness and deformability., The authors gratefully acknowledge the funding of this work by Fundação para a Ciência e Tecnologia (Project UIDB/00100/2020, Project UIDP/00100/2020 and Project LA/P/0056/2020), the FCT-CATSUS program and PAUILF (Project TC 04/17). D. M. Cecílio’s PhD scholarship (PD/BD/114580/2016) provided by FCT is gratefully acknowledged. A. Fernandes thanks FCT for law DL/57 contract. This work was also supported by the Agencia Estatal de Investigación (AEI, Spain) (Grant No PID2020-114930 GB-I00).

Published

2023