Your search keyword '"Martone, Alfonso"' showing total 28 results

1. Genetic factors and symptom dimensions associated with antidepressant treatment outcomes: clues for new potential therapeutic targets?

Author

Martone, Alfonso, Possidente, Chiara, Fanelli, Giuseppe, Fabbri, Chiara, and Serretti, Alessandro

Published

2024

2. Lightweight 3D-printed heaters: design and applicative versatility

Author

Aliberti, Francesca, Sorrentino, Andrea, Palmieri, Barbara, Vertuccio, Luigi, De Tommaso, Giuseppe, Pantani, Roberto, Guadagno, Liberata, and Martone, Alfonso

Published

2024

3. Polygenic scores of subcortical brain volumes as possible modulators of treatment response in depression

Author

Potier, Marie-Claude, van Westrhenen, Roos, Rybakowski, Filip, Mehta, Divya, Dierssen, Mara, Janzing, Joost G.E., Liò, Pietro, Oliva, Vincenzo, Martone, Alfonso, Fanelli, Giuseppe, Domschke, Katharina, Minelli, Alessandra, Gennarelli, Massimo, Martini, Paolo, Bortolomasi, Marco, Maron, Eduard, Squassina, Alessio, Pisanu, Claudia, Kasper, Siegfried, Zohar, Joseph, Souery, Daniel, Montgomery, Stuart, Albani, Diego, Forloni, Gianluigi, Ferentinos, Panagiotis, Rujescu, Dan, Mendlewicz, Julien, De Ronchi, Diana, Baune, Bernhard T., Serretti, Alessandro, and Fabbri, Chiara

Published

2024

4. Graphene NanoPlatelet-based coating as thermal protection from high-power radiative fluxes

Author

Cilento, Fabrizia, Leone, Claudio., Genna, Silvio, Giordano, Michele, and Martone, Alfonso

Published

2023

5. Flash sintering in metallic ceramics: finite element analysis of thermal runaway in tungsten carbide green bodies

Author

Mazo, Isacco, Palmieri, Barbara, Martone, Alfonso, Giordano, Michele, and Sglavo, Vincenzo M.

Published

2023

6. Effect of microneedles shape on skin penetration and transdermal drug administration

Author

De Martino, Selene, Battisti, Mario, Napolitano, Francesco, Palladino, Antonio, Serpico, Luigia, Amendola, Eugenio, Martone, Alfonso, De Girolamo, Paolo, Squillace, Antonino, Dardano, Principia, De Stefano, Luca, and Dello Iacono, Stefania

Published

2022

7. Effect of graphite nanoplatelets percentage on the in plane thermal diffusivity of ultra-thin graphene based (nanostructured) composite

Author

Leone, Claudio, Di Siena, Mario, Genna, Silvio, and Martone, Alfonso

Published

2022

8. Nacre-like GNP/Epoxy composites: Reinforcement efficiency vis-à-vis graphene content

Author

Cilento, Fabrizia, Martone, Alfonso, Pastore Carbone, Maria Giovanna, Galiotis, Costas, and Giordano, Michele

Published

2021

9. Recent Advances in Graphene Adaptive Thermal Camouflage Devices.

Author

Sansone, Lucia, Loffredo, Fausta, Cilento, Fabrizia, Miscioscia, Riccardo, Martone, Alfonso, Barrella, Nicola, Paulillo, Bruno, Bassano, Alessio, Villani, Fulvia, and Giordano, Michele

Subjects

MILITARY supplies, OPTICAL properties, EMISSIVITY, INFRARED equipment, ELECTRIC fields

Abstract

Thermal camouflage is a highly coveted technology aimed at enhancing the survivability of military equipment against infrared (IR) detectors. Recently, two-dimensional (2D) nanomaterials have shown low IR emissivity, widely tunable opto-electronic properties, and compatibility with stealth applications. Among these, graphene and graphene-like materials are the most appealing 2D materials for thermal camouflage applications. In multilayer graphene (MLG), charge density can be effectively tuned through sufficiently intense electric fields or through electrolytic gating. Therefore, MLG's optical properties, like infrared emissivity and absorbance, can be controlled in a wide range by voltage bias. The large emissivity modulation achievable with this material makes it suitable in the design of thermal dynamic camouflage devices. Generally, the emissivity modulation in the multilayered graphene medium is governed by an intercalation process of non-volatile ionic liquids under a voltage bias. The electrically driven reduction of emissivity lowers the apparent temperature of a surface, aligning it with the background temperature to achieve thermal camouflage. This characteristic is shared by other graphene-based materials. In this review, we focus on recent advancements in the thermal camouflage properties of graphene in composite films and aerogel structures. We provide a summary of the current understanding of how thermal camouflage materials work, their present limitations, and future opportunities for development. [ABSTRACT FROM AUTHOR]

Published

2024

10. Reinforcing Efficiency of Recycled Carbon Fiber PLA Filament Suitable for Additive Manufacturing.

Author

Tammaro, Loredana, Martone, Alfonso, Palmieri, Barbara, Borriello, Carmela, Portofino, Sabrina, Iovane, Pierpaolo, Cilento, Fabrizia, Giordano, Michele, and Galvagno, Sergio

Subjects

*FIBROUS composites, *CARBON fibers, *THERMOPLASTIC composites, *RAW materials, *THREE-dimensional printing, *POLYLACTIC acid

Abstract

The use of 3D printing technology for manufacturing new products based on sustainable materials enables one to take advantage of secondary raw materials derived from recycling. This work investigates the structural performances of 3D printing composite filaments based on polylactic acid (PLA), as a matrix, reinforced by recycled carbon fiber (rCF). Carbon fibers were recovered from industrial scraps by a patented thermal process and used to produce thermoplastic composite filaments for additive manufacturing without any additional treatment and additives. The influence of the recovered carbon fiber (rCF) content on the thermal properties, mechanical properties and microstructure of the composites was studied in the range of 3–20 wt%. The recorded TGA curves exhibited a one-stage weight loss within the temperature range 290–380 °C for all samples and the residual rCF content was in good agreement with the theoretical fiber loading. The Young modulus of the extruded filaments strongly increased below a critical content (5 wt%), while at higher content the improvement was reduced. An increase in the storage modulus of 54% compared to neat PLA 3D printed sample resulted in a printed specimen with a higher rCF content. SEM images highlighted a strong rCF prevailing alignment in the direction of the extrusion flow, creating almost unidirectional reinforcement inside the filament. These findings suggest that homogeneous composite filaments reinforced with well-dispersed recycled CF without additional chemical modification and additives are suitable materials for additive manufacturing. The effect of rCF topological distribution within the material on the mechanical performances has been discussed, highlighting that the isolated fibers could efficiently transfer loads with respect to the percolated 3D network and have been correlated with the microstructure. [ABSTRACT FROM AUTHOR]

Published

2024

11. Manufacturing and Properties of Biomimetic Graphite Nanoplatelets Foils

Author

Ricciardi, Maria R., Cristiano, Francesco, Bertocchi, Francesco, Martone, Alfonso, and Giordano, Michele

Subjects

Biomimetics, Acetone, Graphite, Epoxy resins, Technology, Microscopy, Composite materials, Laminates, Electron microscopy, Production management, Engineering and manufacturing industries, Science and technology

Abstract

Among the various architectures developed for composite materials, nanolaminated architecture is a promising candidate for the design of new materials for structural and functional applications. Nanolaminates mimic the natural occurring architecture of nacre and it is formed by highly oriented nanolaminae connected by a very low amount of matrix. Due to their architecture, inherently impermeable to fluid, such kind of materials is difficult to manufacture unless using layer-by-layer processes. Here, we describe the fabrication of films with nanolaminated architecture containing very high content (>80% w/w) of graphite nanoplatelets (GNPs) within an uncured epoxy matrix (prepregs), suitable for the conventional prepregs manufacturing technologies: film stacking and consolidation under temperature under pressure. Nanolaminated prepregs have been manufactured through the deposition of a paste of GNPs in epoxy enriched acetone solvent. Mainly, scanning electron microscopy has investigated the nanolaminated architecture of the prepregs. Stress-strain behavior of nanolaminated prepregs has been investigated as a function of their composition and consolidation pressure. Finally, a laminate made of six nanolaminated prepregs (about 0.3 mm thick) has been manufactured by hot pressing revealing interesting mechanical properties: a tensile modulus of 30 GPa and a damping coefficient, tan [delta], of 0.03., INTRODUCTION Nanolaminates, consisting of the assemblies of highly oriented nanometric thin laminae, are an emerging class of nanocomposite materials at a very high percentage of reinforcing phase >70% that represent [...]

Published

2019

12. Effect of moisture on elastic and viscoelastic properties of epoxy and epoxy-based carbon fibre reinforced plastic filled with multiwall carbon nanotubes

Author

Glaskova-Kuzmina, Tatiana, Aniskevich, Andrey, Martone, Alfonso, Giordano, Michele, and Zarrelli, Mauro

Published

2016

13. Graphite Nanoplatelets Nanostructured Films as Multifunctional Protective Layer in Kevlar/Nomex Sandwich Composites.

Author

Cilento, Fabrizia, Palmieri, Barbara, Giusto, Giovangiuseppe, Volponi, Ruggiero, Bruno, Giovanni, Tartaglia, Carmine Carandente, Toscano, Cinzia, Giordano, Michele, and Martone, Alfonso

Subjects

NANOPARTICLES, FIBROUS composites, GRAPHITE, PROTECTIVE coatings, POLYPHENYLENETEREPHTHALAMIDE, SANDWICH construction (Materials), STRENGTH of materials

Abstract

Featured Application: Multifunctional protective layer for fiber reinforced composites. In the aerospace sector, structural and non-structural composite components are usually subjected to a wide range of environmental conditions. Among all, moisture can seriously damage these materials' performance, reducing their mechanical, thermal, electrical, and physical properties as well as their service time. Lightweight protective barrier coatings capable of reducing the diffusion of gases and/or liquids in a material can improve the material's resistance in humid environments. In this work, nanolamellar nanocomposites characterized by a high in-plane orientation of nanoplatelets have been employed as protective coatings for Kevlar sandwich panels, reproducing the construction of a nacelle engine. The effectiveness of the protection against water uptake of nanocomposites reinforced with graphite nanoplatelets (GNPs) at high filler contents (70, 80 and 90 wt%) has been investigated using moisture uptake and Ground-Air-Ground (GAG) tests in an environmental chamber. GNP coatings effectively work as barrier by generating highly tortuous paths for molecule diffusion. Results showed a dependence of the absorption on the coating composition and inner structure. Films @70 wt% GNPs showed the best protection against moisture uptake by delaying the phenomenon and reducing the absorption by −80% after 3 days and −35% after 41 days. [ABSTRACT FROM AUTHOR]

Published

2023

14. Effect of sepiolite filler on mechanical behaviour of a bisphenol A-based epoxy system

Author

Zotti, Aldobenedetto, Borriello, Anna, Martone, Alfonso, Antonucci, Vincenza, Giordano, Michele, and Zarrelli, Mauro

Published

2014

15. Effect of filler on the creep characteristics of epoxy and epoxy-based CFRPs containing multi-walled carbon nanotubes

Author

Glaskova-Kuzmina, Tatiana, Aniskevich, Andrey, Zarrelli, Mauro, Martone, Alfonso, and Giordano, Michele

Published

2014

16. Influence of Catalyst Content and Epoxy/Carboxylate Ratio on Isothermal Creep of Epoxy Vitrimers.

Author

Palmieri, Barbara, Cilento, Fabrizia, Amendola, Eugenio, Valente, Teodoro, Dello Iacono, Stefania, Giordano, Michele, and Martone, Alfonso

Subjects

COMPRESSION molding, DYNAMIC viscosity, CATALYSTS, TERTIARY amines, ZINC acetate, EXCHANGE reactions

Abstract

In the present work, a commercial epoxy based on epoxy anhydride and tertiary amine was modified by a metallic catalyst (Zn2+) to induce vitrimeric behavior by promoting the transesterification reaction. The effect of two different epoxy/acid ratios (1 and 0.6) at two different zinc acetate amounts (Zn(Ac)2) on the thermomechanical and viscoelastic performances of the epoxy vitrimers were investigated. Creep experiments showed an increase in molecular mobility above the critical "Vitrimeric" temperature (Tv) of 170 °C proportionally to the amount of Zn(Ac)2. A procedure based on Burger's model was set up to investigate the effect of catalyst content on the vitrimer ability to flow as the effect of the dynamic exchange reaction. The analysis showed that in the case of a balanced epoxy/acid formulation, the amount of catalyst needed for promoting molecular mobility is 5%. This system showed a value of elastic modulus and dynamic viscosity at 170 °C of 9.50 MPa and 2.23 GPas, respectively. The material was easily thermoformed in compression molding, paving the way for the recyclability and weldability of the thermoset system. [ABSTRACT FROM AUTHOR]

Published

2023

17. An Investigation of the Healing Efficiency of Epoxy Vitrimer Composites Based on Zn 2+ Catalyst.

Author

Palmieri, Barbara, Cilento, Fabrizia, Amendola, Eugenio, Valente, Teodoro, Dello Iacono, Stefania, Giordano, Michele, and Martone, Alfonso

Subjects

SELF-healing materials, EPOXY resins, METAL catalysts, FIBROUS composites, HEALING, CARBON composites, ZINC catalysts

Abstract

The need to recycle carbon-fibre-reinforced composite polymers (CFRP) has grown significantly to reduce the environmental impact generated by their production. To meet this need, thermoreversible epoxy matrices have been developed in recent years. This study investigates the performance of an epoxy vitrimer made by introducing a metal catalyst (Zn2+) and its carbon fibre composites, focusing on the healing capability of the system. The dynamic crosslinking networks endow vitrimers with interesting rheological behaviour; the capability of the formulated resin (AV-5) has been assessed by creep tests. The analysis showed increased molecular mobility above a topology freezing temperature (Tv). However, the reinforcement phase inhibits the flow capability, reducing the flow. The fracture behaviour of CFRP made with the vitrimeric resin has been investigated by Mode I and Mode II tests and compared with the conventional system. The repairability of the vitrimeric CFRP has been investigated by attempting to recover the delaminated samples, which yielded unsatisfactory results. Moreover, the healing efficiency of the modified epoxy composites has been assessed using the vitrimer as an adhesive layer. The joints were able to recover about 84% of the lap shear strength of the pristine system. [ABSTRACT FROM AUTHOR]

Published

2023

18. Mechanical and Viscoelastic Properties of Carbon Fibre Epoxy Composites with Interleaved Graphite Nanoplatelet Layer.

Author

Palmieri, Barbara, Siviello, Ciro, Petriccione, Angelo, Espresso, Manuela, Giordano, Michele, Martone, Alfonso, and Cilento, Fabrizia

Subjects

FIBROUS composites, GRAPHITE composites, DAMPING capacity, VISCOELASTIC materials, FRACTURE toughness, LAMINATED materials, GRAPHITE

Abstract

The use of interleaving material with viscoelastic properties is one of the most effective solutions to improve the damping capacity of carbon fibre-reinforced polymer (CFRP) laminates. Improving composite damping without threatening mechanical performance is challenging and the use of nanomaterials should lead to the target. In this paper, the effect of a nanostructured interlayer based on graphite nanoplatelets (GNPs) on the damping capacity and fracture toughness of CFRP laminates has been investigated. High-content GNP/epoxy (70 wt/30 wt) coating was sprayed on the surface of CF/epoxy prepregs at two different contents (10 and 40 g/m2) and incorporated at the middle plane of a CFRP laminate. The effect of the GNP areal weights on the viscoelastic and mechanical behaviour of the laminates is investigated. Coupons with low GNP content showed a 25% increase in damping capacity with a trivial reduction in the storage modulus. Moreover, a reduction in interlaminar shear strength (ILSS) and fracture toughness (both mode I and mode II) was observed. The GNP alignment and degree of compaction reached during the process were found to be key parameters on material performances. By increasing the GNP content and compaction, a mitigation on the fracture drop was achieved (−15%). [ABSTRACT FROM AUTHOR]

Published

2023

19. PVB Nanocomposites as Energy Directors in Ultrasonic Welding of Epoxy Composites.

Author

Cilento, Fabrizia, Bassano, Alessio, Sorrentino, Luigi, Martone, Alfonso, Giordano, Michele, and Palmieri, Barbara

Subjects

ULTRASONIC welding, CARBON fiber-reinforced plastics, THERMOSETTING composites, WELDED joints, EPOXY resins, NANOCOMPOSITE materials, POLYMERIC nanocomposites

Abstract

Ultrasonic welding (UW) is a well-established technique for joining thermoplastic composites and has recently been utilized in the aerospace and automotive industries. In the case of thermoset composites (TSCs), a polymer-based material placed at the welding interface called an energy director (ED) is required. The choice of the coupling layer material is linked to several requirements, such as processing temperature, high adhesion to the thermoset composites (TSCs) adherend and mechanical strength of the resulting welded joints. In this work, the authors investigated the possibility of using Poly-vinyl-butyral (PVB) reinforced with graphite nanoplatelets (GNPs) as a coupling layer in the UW of TSC adherents. The effect of GNPs aspect ratio and content on the weldability of carbon fiber-reinforced plastics (CFRP) has been investigated. PVB/GNPs nanocomposites with different filler contents (from 0.5 wt% to 2 wt%) and different aspect ratios (100 and 2100) have been fabricated. The influence of the viscoelastic properties of the flat EDs on weldability has been assessed. Finally, an improvement of lap shear strength (LSS) of 80% was found for nanocomposites with 0.5 wt% of high-aspect-ratio GNPs with respect to neat PVB. The use of high damping nanocomposites as coupling materials for TSCs paves the way for a new generation of EDs in UW. [ABSTRACT FROM AUTHOR]

Published

2023

20. Thermally Mendable Self-Healing Epoxy Coating for Corrosion Protection in Marine Environments.

Author

Amendola, Eugenio, Palmieri, Barbara, Dello Iacono, Stefania, and Martone, Alfonso

Subjects

EPOXY coatings, METALLIC films, MARINE resources conservation, ENVIRONMENTAL protection, SEAWATER corrosion, METAL coating

Abstract

Polymeric coatings represent a well-established protection system that provides a barrier between a metallic substrate and the environment. The development of a smart organic coating for the protection of metallic structures in marine and offshore applications is a challenge. In the present study, we investigated the use of self-healing epoxy as an organic coating suitable for metallic substrates. The self-healing epoxy was obtained by mixing Diels–Alder (D–A) adducts with a commercial diglycidyl ether of bisphenol-A (DGEBA) monomer. The resin recovery feature was assessed through morphological observation, spectroscopic analysis, and mechanical and nanoindentation tests. Barrier properties and anti-corrosion performance were evaluated through electrochemical impedance spectroscopy (EIS). The film on a metallic substrate was scratched and subsequently repaired using proper thermal treatment. The morphological and structural analysis confirmed that the coating restored its pristine properties. In the EIS analysis, the repaired coating exhibited diffusive properties similar to the pristine material, with a diffusivity coefficient of 1.6 × 10−6 cm2/s (undamaged system 3.1 × 10−6 cm2/s), confirming the restoration of the polymeric structure. These results reveal that a good morphological and mechanical recovery was achieved, suggesting very promising applications in the field of corrosion-resistant protective coatings and adhesives. [ABSTRACT FROM AUTHOR]

Published

2023

21. Mitigation of Heat Propagation in a Battery Pack by Interstitial Graphite Nanoplatelet Layer: Coupled Electrochemical-Heat Transfer Model.

Author

Palmieri, Barbara, Cilento, Fabrizia, Siviello, Ciro, Bertocchi, Francesco, Giordano, Michele, and Martone, Alfonso

Subjects

GRAPHITE, CARBON films, FINITE element method, THERMAL conductivity, HEAT transfer

Abstract

The use of high thermal conductive materials for heat transfer is gaining attention as a suitable treatment for improving battery performance. Thermal runaway is a relevant issue for maintaining safety and for proficient employment of accumulators; therefore, new solutions for thermal management are mandatory. For this purpose, a hierarchical nanomaterial made of graphite nanoplatelet has been considered as an interface material. High-content graphite nanoplatelet films have very high thermal conductivity and might improve heat dissipation. This study investigates the effect of a thermally conductive material as a method for safety enhancement for a battery module. A numerical model based on the finite element method has been developed to predict the heat generation during a battery pack's charge and discharge cycle, using the Multiphysics software Comsol. The lumped battery interface generates appropriate heat sources coupled to the Heat Transfer Interface in 3D geometry. Simulation results show that the protection of neighbouring cells from the interleaved layer is fundamental for avoiding heat propagation and an uncontrollable heating rise of the entire battery pack. The use of graphite nanocomposite sheets could effectively help to uniform the temperature and delay the TR propagation. [ABSTRACT FROM AUTHOR]

Published

2022

22. Effect of Graphite Nanoplatelets Content and Distribution on the Electromagnetic Shielding Attenuation Mechanisms in 2D Nanocomposites.

Author

Cilento, Fabrizia, Curcio, Claudio, Martone, Alfonso, Liseno, Angelo, Capozzoli, Amedeo, and Giordano, Michele

Subjects

NANOPARTICLES, GRAPHITE, ELECTROMAGNETIC shielding, AIRFRAMES, NANOSTRUCTURED materials, ELECTROMAGNETIC interference, ATTENUATION (Physics), NANOCOMPOSITE materials

Abstract

Bidimensional nanomaterials, such as graphene, respond to the rising demand for electromagnetic interference (EMI) shielding materials, followed by the advancements in wireless technology and increased signal sensitivity in electronic devices, especially for the safety of aircraft and other structures. Lightweight nanocomposites reinforced with 2D carbonaceous nanofillers can replace metals thanks to their ability to attenuate electromagnetic waves and low susceptibility to corrosion. In this work, the EMI shielding properties in the X band (8–12 GHz) of high content graphene nanoplatelets (GNPs) nanocomposites have been investigated. Both the effect of filler content and the nanoarchitecture have been studied. For this purpose, two different configurations have been considered, compact and porous, varying the filler content (from 10 wt% to 90 wt%) and the thickness of the samples. Specifically, four different systems have been tested: thin (i) and thick (ii) compact laminates and thin (iii) and thick (iv) porous coatings. The morphology of the material significantly influences its electromagnetic response in terms of reflection and absorption capacity. Maximum effective absorption of 80% was found for disordered structures, while a maximum reflection of about 90% was found for system highly aligned structures. [ABSTRACT FROM AUTHOR]

Published

2022

23. Insights on Shear Transfer Efficiency in "Brick-and-Mortar" Composites Made of 2D Carbon Nanoparticles.

Author

Cilento, Fabrizia, Martone, Alfonso, and Giordano, Michele

Subjects

*TRANSFER matrix, *NANOPARTICLES, *ATOMIC interactions, *CARBON, *MOTHER-of-pearl

Abstract

Achieving high mechanical performances in nanocomposites reinforced with lamellar fillers has been a great challenge in the last decade. Many efforts have been made to fabricate synthetic materials whose properties resemble those of the reinforcement. To achieve this, special architectures have been considered mimicking existing materials, such as nacre. However, achieving the desired performances is challenging since the mechanical response of the material is influenced by many factors, such as the filler content, the matrix molecular mobility and the compatibility between the two phases. Most importantly, the properties of a macroscopic bulk material strongly depend on the interaction at atomic levels and on their synergetic effect. In particular, the formation of highly-ordered brick-and-mortar structures depends on the interaction forces between the two phases. Consequently, poor mechanical performances of the material are associated with interface issues and low stress transfer from the matrix to the nanoparticles. Therefore, improvement of the interface at the chemical level enhances the mechanical response of the material. The purpose of this review is to give insight into the stress transfer mechanism in high filler content composites reinforced with 2D carbon nanoparticles and to describe the parameters that influence the efficiency of stress transfer and the strategies to improve it. [ABSTRACT FROM AUTHOR]

Published

2022

24. An Efficient Thermal Cure Profile for Thick Parts Made by Reactive Processing of Acrylic Thermoplastic Composites.

Author

Palmieri, Barbara, Petriccione, Angelo, De Tommaso, Giuseppe, Giordano, Michele, and Martone, Alfonso

Subjects

THERMOPLASTIC composites, RESIDUAL stresses, DIFFERENTIAL scanning calorimetry, POLYMERIZATION, HEAT exchangers

Abstract

The process of curing of large thick composite parts needs attention regarding the formation of residual stresses. Similarly, novel reactive thermoplastics need investigating to produce an efficient thermal cure profile that decreases the risk of warpage and residual stress. In this work, the polymerization kinetics of the Elium resin system is investigated by differential scanning calorimetry (DSC) tests, the analysis of thermo-grams, and the parameters of Kamal and Sourour's semi-empirical model. A numerical model based on finite elements was set up to reproduce the temperature fields during part consolidation. Several processing conditions were investigated (dwell temperature, environment, heat exchange) in order to predict the thermal gradient within the part. The optimal cure profile was identified as a function of process parameters with the aim of minimizing the thermal gradient within the composite element. The analysis revealed that, for the reactive thermoplastic Elium, the consolidation in facilities with high thermal exchange may increase the risk of residual stresses within the parts, erasing the advantage of short cure cycles. [ABSTRACT FROM AUTHOR]

Published

2021

25. High performance dynamic covalent crosslinked polyacylsemicarbazide composites with self-healing and recycling capabilities.

Author

Wang, Shuo, Fu, Daihua, Wang, Xiaorong, Pu, Wuli, Martone, Alfonso, Lu, Xili, Lavorgna, Marino, Wang, Zhanhua, Amendola, Eugenio, and Xia, Hesheng

Abstract

Self-healing and recycling of fiber reinforced polymer (FRP) composites are of great significance towards pursuing a sustainable and circular economy, but remain a huge challenge due to the infusible and insoluble properties of thermoset polymers. The newly developed dynamic covalent polymers provide a great opportunity to resolve this issue for FRPs. Here we developed a novel type of dynamic covalently cross-linked polyacylsemicarbazide exhibiting a high modulus and self-healing/recycling capability due to the reversible properties of the dynamic acylsemicarbazide (ASC) moieties. Introducing different ASC moieties composed of different dihydrazides into the polymer can dramatically tune the mechanical, self-healing and reprocessing properties. An optimized polyacylsemicarbazide with a Young's modulus of ∼2.84 GPa, a stress at break of ∼100 MPa and a glass transition temperature of ∼123 °C exhibits a self-healing efficiency of ∼94.4% and great reprocessing properties. Furthermore, using this newly developed PASC material as the matrix resin, the carbon fiber reinforced polymer composite was successfully prepared through solution impregnation and thermal pressing. The composite exhibits an interlaminar shear strength of 40 MPa and a healing efficiency of 76.2%. The great dynamic reversible properties of ASC moieties enables the recycling of the carbon fiber and matrix resin, respectively, from the composites by a solvolysis method. [ABSTRACT FROM AUTHOR]

Published

2021

26. Mechanical Behavior of Hybrid Fiber-Reinforced Composites Manufactured by Pulse Infusion.

Author

Ricciardi, Maria Rosaria, Martone, Alfonso, Borriello, Anna, Zarrelli, Mauro, Giordano, Michele, Langella, Antonio, and Antonucci, Vincenza

Subjects

*FIBROUS composites, *CARBON fibers, *EPOXY resins, *CARBON nanotubes, *SHEAR strength

Abstract

Epoxy/carbon fiber composites have been manufactured by Pulse Infusion. Pulse Infusion allows to control the pressure of the vacuum bag on the dry fiber reinforcement by using a proper designed pressure distributor that induces a pulsed transverse action and promotes the through thickness resin flow. The adopted one-component commercial epoxy resin has been preliminary modified by adding 0.05% (w/w) of multiwalled carbon nanotubes, in order to take advantage of carbon nanotubes at low concentration. Both neat and hybrid realized composite panels have been mechanically characterized by performing experimental tests to evaluate tensile, interlaminar, and fracture properties in order to investigate the effect of Pulse Infusion and carbon nanotubes on the mechanical and fracture behavior of composites. Results demonstrated an improvement of 36.2% for the interlaminar shear strength, of 35% for the fracture energy at the crack initiation and of 14% for the fracture toughness in mode II. [ABSTRACT FROM AUTHOR]

Published

2017

27. BMI‐Based Coupling Agent to Improve Adhesion in Self‐Healing Composites.

Author

Iacono, Stefania Dello, Amendola, Eugenio, and Martone, Alfonso

Subjects

SELF-healing materials, ADHESION, CONTACT angle, FIBROUS composites, COMMERCIAL products

Abstract

Recently, the availability of thermo‐reversible epoxies is interesting for research and industry due to its implication in the implementation of the next generation of advanced materials. However, fiber‐reinforced composites made with self‐healing epoxies have lower performances than commercial products. Therefore, the availability of a suitable treatment to improve the adhesion between fiber and matrix will compensate the lack of performances experienced in thermo‐reversible composites. Here, a route for decorating dry commercial preform with bismaleimide (BMI) is presented in order to promote the adhesion between matrix and reinforcement. The grafting of BMI on the glass support is measured by means of contact angle. The interfacial strength between fiber and resin is measured by micro‐droplet pull‐out test. The BMI‐based coupling agent leads to a 92% increase in interfacial strength for a self‐healing system. [ABSTRACT FROM AUTHOR]

Published

2020

28. Treating eating disorders in the LGBTQIA+ adult population: A scoping review.

Author

Tempia Valenta, Silvia, Marcolini, Federica, Martone, Alfonso, De Ronchi, Diana, and Atti, Anna Rita

Abstract

AbstractIntroductionMethodsResultsConclusionsThe lesbian, gay, bisexual, transgender, queer/questioning, intersex, and asexual/aromantic/agender (LGBTQIA+) community faces a significantly higher risk of eating disorders (EDs). This review’s primary objective is to explore ED treatments for this population.We searched PubMed/MEDLINE and PsycINFO using the keywords “ED,” “LGBTQIA+,” and “therapy,” following the Preferred Reporting Items for Systematic Review and Meta-Analysis Extension for Scoping Reviews 2018 Checklist.Out of 363 publications, we identified 14 articles and inductively categorized them into two key macro-themes. The primary macro-theme “conventional treatments applied to the LGBTQIA+ population” encompassed both treatment outcomes, which demonstrated overall effectiveness, and self-reported treatment evaluations, which consistently indicated negative experiences. The secondary macro-theme, “specific treatments for the LGBTQIA+ population,” centered on population-targeted treatments, which, while currently limited, displayed promising results, including improvements in ED psychopathology through gender transition.The existing literature indicates that conventional treatments are effective in symptom relief but occur within a context marked by perceived discrimination based on gender identity and sexual orientation. Concurrently, population-specific interventions hold promise in reducing ED symptoms, with gender transition emerging as a valuable treatment. Further research is needed to develop tailored treatments and address the challenges faced by the LGBTQIA+ community. [ABSTRACT FROM AUTHOR]

Published

2024