Your search keyword '"Forchetti Casarino, Agustín"' showing total 6 results

1. Novel polybenzoxazine and polybenzoxazine/epoxy thermosetting copolymers containing polysilsesquioxane nanostructures for high-performance thermal protection systems

Author

Forchetti Casarino, Agustín, Bortolato, Santiago Andrés, Casis, Natalia, Estenoz, Diana Alejandra, and Spontón, Marisa Elisabet

Published

2023

2. Development of quinoline-based heteroatom polybenzoxazines reinforced graphitic carbon nitride (GCN) carbonisation composites for emerging supercapacitor applications

Author

Selvaraj, Kumar, primary, Spontón, Marisa Elisabet, additional, Estenoz, Diana Alejandra, additional, Forchetti Casarino, Agustín, additional, Veerasamy, Uma Shankar, additional, Kumar, Manimaran, additional, Al-Mohaimeed, Amal M., additional, Al-onazi, Wedad A., additional, and Kannaiyan, Dinakaran, additional

Published

2024

3. Lignosulfonate/silica hybrid nanoparticles as a novel biobased filler in polybenzoxazine matrix.

Author

Candia, Adriana, Taverna, María Eugenia, Forchetti Casarino, Agustín, Busatto, Carlos, Casis, Natalia, Spontón, Marisa Elisabet, La Scala, John, and Estenoz, Diana

Subjects

SILICA nanoparticles, BENZOXAZINES, THERMOSETTING composites, TRANSMISSION electron microscopy, THERMAL stability, THERMAL properties

Abstract

Lignin is an abundant and sustainable resource that exhibits numerous attractive functional properties as a reinforcing agent for benzoxazine‐based composites, due to its stiffness, thermal stability, and high carbon content. However, the low quality of lignin particles dispersions associated with the weak particles‐matrix interactions reduces the reinforcement capability. In this work, hybrid lignin/silica (NaLS/SiO2) nanoparticles were obtained from sodium lignosulfonate (NaLS) and tetraethylorthosilicate (TEOS) under basic conditions. The particles were characterized by transmission electron microscopy (TEM) confirming their spherical morphology and narrow nanometric‐size distributions. The hybrid particles were incorporated into conventional benzoxazine (BA‐a) and a difuran biobased benzoxazine (SA‐dfda) to prepare nanocomposites with different mass compositions (3, 5, and 10 wt%). Morphological, mechanical, dynamo‐mechanical, and thermal properties of the obtained composites were assessed. All the materials exhibited a homogenous filler dispersion that contributed to improve the reinforcement properties. Hybrid nanoparticles proved to be an interesting alternative as a filler in the benzoxazine matrix to prepare high‐performance thermosetting composites. [ABSTRACT FROM AUTHOR]

Published

2024

4. Tailoring thermal and thermomechanical properties of biobased blends by hybridization of difuran benzoxazine with polysiloxane‐based benzoxazine and epoxy monomers

Author

Forchetti Casarino, Agustín, primary, Taverna, María Eugenia, additional, Candia, Adriana, additional, Spontón, Marisa Elisabet, additional, Palmese, Giuseppe Raffaello, additional, La Scala, John, additional, and Estenoz, Diana Alejandra, additional

Published

2022

5. Development of high-performance and low environmental impact thermosetting systems based on hybrid polybenzoxazines

Author

Forchetti Casarino, Agustín, Spontón, Marisa Elisabet, Martinelli, Marisa, Tomba, Juan Pablo, Inalbon, Cristina, and Estenoz, Diana Alejandra

Subjects

Environmental impact, Morphology, High performance, Benzoxazinas, Impacto ambiental, Morfología, Retardancia a la llama, Termoestables, Thermosets, Alta performance, Benzoxazines, Flame resistance

Abstract

Fil: Forchetti Casarino, Agustín. Universidad Nacional del Litoral. Facultad de Ingeniería Química; Argentina. Durante la tesis se investigaron aspectos novedosos asociados a la química de las benzoxazinas híbridas y su aplicación a la preparación de sistemas poliméricos termoestables de altas prestaciones y bajo impacto ambiental. En primer lugar, se sintetizó un monómero basado en alcoxisilanos (BA-3aptms) a partir de bisfenol A, 3-trimetoxisililpropilamina y paraformaldehído. Posteriormente se obtuvo el precursor híbrido Pr(BA-3aptms) a partir del proceso sol-gel. Se obtuvo un material híbrido polibenzoxazina/polisilsesquioxano con elevada Tg; buena resistencia térmica; y morfología basada en nanodominios de polisilsesquioxanos con alta orientación laminar. Como siguiente etapa, se presentó la incorporación de nanopartículas de sílice al precursor híbrido Pr(BA-3aptms) y se investigó la influencia de las mismas sobre la morfología, propiedades térmicas, de retardancia a la llama y mecánicas del material. Adicionalmente, se propuso la copolimerización del precursor híbrido [Pr(BA-3aptms)] con la resina epoxi (DGEBA) y benzoxazina (BA-a) basadas en bisfenol A como estrategia para preparar copolímeros benzoxazina/epoxi y benzoxazina/benzoxazina con diferentes cantidades de polisilsesquioxanos en su estructura química. Se analizó el efecto de la composición de los copolímeros sobre las propiedades de interés mencionadas. Por otra parte, se exploró el desarrollo de una benzoxazina parcialmente renovable basada en furano (SA-dfda) y su copolimerización con DGEBA, BA-a y Pr(BA-3aptms). Se investigó el efecto de la fracción renovable en los materiales y el contenido de siloxano en las mezclas correspondientes. Finalmente, se sintetizaron benzoxazinas multi-oxazina basadas en grupos fenólicos y aminas renovables a través de una nueva estrategia de síntesis, mediante la esterificación con haluros orgánicos asistida por 1,1,3,3-tetrametil-guanidina. In this work, the synthesis and development of novel hybrid thermoset polymers based on benzoxazines was investigated. First, an alcoxysilane-based monomer (BA-3aptms) was synthesized from bisphenol A, 3-aminopropyl trimethoxysilane and paraformaldehyde. Next, a hybrid precursor [Pr(BA-3aptms)] based on polysilsesquioxanes was obtained from the sol-gel process of the respective monomer. A hybrid polybenzoxazine/polysilsesquioxane-based material was obtained, which showed high Tg, good thermal resistance and a nano-laminar morphology. As a next step, the incorporation of silica nanoparticles to the hybrid precursor was studied as a strategy for enhancing the mentioned properties. The influence of the nanoparticles on the morphlogy, thermal properties, flame resistance and mechanical behavior was studied. Additionally, the copolymerization of this precursor with conventional benzoxazine (BA-a) and epoxy (DGEBA) resins was presented, in order to obtain benzoxazine/benzoxazine and epoxy/benzoxazine copolymers with different concentration of polysilsesquioxanes. In this case, the effect of the composition on the mentioned properties was studied. On the other hand, the development of novel partially- or fully-biobased benzoxazines was explored. In order to achieve this, a novel furan-based benzoxazine was synthesized and copolymerized with the previously mentioned resins. The effect of the presence of polysilsesquioxanes on the crosslinked copolymers was studied. Finally, a novel route for the synthesis of multifunctional benzoxazines was presented, mainly based on the esterification of carboxylic acid-based benzoxazines and organic halides, assisted by 1,1,3,3-tetramethyl guanidine. Consejo Nacional de Investigaciones Científicas y Técnicas Universidad Nacional del Litoral Fundación Carolina

Published

2022

6. Tailoring thermal and thermomechanical properties of biobased blends by hybridization of difuran benzoxazine with polysiloxane‐based benzoxazine and epoxy monomers.

Author

Forchetti Casarino, Agustín, Taverna, María Eugenia, Candia, Adriana, Spontón, Marisa Elisabet, Palmese, Giuseppe Raffaello, La Scala, John, and Estenoz, Diana Alejandra

Subjects

BENZOXAZINES, THERMOMECHANICAL properties of metals, THERMAL properties, MONOMERS, MECHANICAL behavior of materials, EPOXY resins

Abstract

A difuran bio‐based benzoxazine (SA‐dfda) was synthesized by a three‐stage process from difurandiamine (DFDA) and 2‐hydroxybenzaldehyde with a final yield of 90%. Three copolymer systems were prepared by blending the difuran bio‐resin with epoxy resin (DGEBA), conventional benzoxazine (BA‐a), and polysiloxane‐based benzoxazine precursor [Pr(BA‐3aptms)] at different ratios. In order to study the effect of the renewable content on the main characteristics of the materials, thermal, thermomechanical, and morphological analyses were performed. The bio‐based benzoxazine/epoxy systems exhibited the lowest polymerization temperature with enhanced processability. However, the incorporation of epoxy slightly decreased the mechanical properties of materials. Bio‐based copolymers containing 5 wt%. of polysilsesquioxane precursor showed the highest glass transition temperatures, thermal stability, and char yields. All the copolymers exhibited good flame retardant properties as it was observed by their limiting oxygen index values (>21) and UL‐94 tests (V‐0 or V‐1). The copolymerization of bio‐based benzoxazines with different thermoset resins such as epoxy or benzoxazines can be used as a strategy to develop novel materials with tailor‐made properties. [ABSTRACT FROM AUTHOR]

Published

2023