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2024 | Buch

Materials for Sustainable Environmental, Energy, and Bioresource Applications

Proceedings from the International Conference on M2EBA 2023

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Über dieses Buch

This proceedings book showcases the latest research and developments in materials sciences and their applications for solving environmental and energy-related challenges. The book features insightful contributions from leading researchers, academics, professionals, and students in the field, who share their expertise, experiences, and perspectives on the key issues and innovations in materials sciences and engineering. The book is helpful to those interested in environmental sustainability, energy efficiency, or bioresource utilization.

Inhaltsverzeichnis

Frontmatter
Chapter 1. Synergistic Effects Between Plasma and Photocatalysis at Different Scales: Removal of Mixtures of Pollutants in Air
Abstract
The elimination of isovaleraldehyde in air was experimentally studied in a tubular reactor that combines plasma barrier discharge (DBD) and photocatalysis. The influence of key parameters on the degree of pollution was tested. The study of the effect of residence time shows that when this parameter decreases, the elimination efficiency also decreases. When the residence time is reduced by five times, the removal efficiency drops from 83 to 59%. The influence of relative humidity shows that when this parameter increases, the CO2 selectivity’s are greater. The by-products identified and analyzed are classified into three groups: intermediate products, carbon monoxide, carbon dioxide and ozone. Regarding the org. components, we find that as the energy of the input plasma increases, this leads to a higher mineralization of the pollutant, i.e. the intermediate products formed decrease and the carbon dioxide increases. The mass balance of carbon products is reached at approximately 100%. The formation of ozone is favored by the increase in the input energy. It is interesting to note the existence of the synergy effect for a cocktail of pollutants such as the case of two aldehydes.
Amin Aymen Assadi
Chapter 2. Effect of Whey Protein Isolate and Carnauba Wax Bilayer Coatings on the Barrier Properties of Cellulose-Based Materials for Food Packaging Application
Abstract
Paper-based food packaging materials offer the advantages of renewability and biodegradability. However, their inherent porous structure and the hydrophilic nature of cellulose limit their resistance to water, water vapor, gas, and grease. This study presents a novel solution: a bio-based bilayer coating using whey protein isolate (WPI) and carnauba wax (CW), successfully applied to standard paper substrates using a rod coater. We investigated the effects of WPI and CW to determine their impact on the barrier and mechanical properties of the coated paper. Results demonstrated a significant improvement in grease/oil resistance, as measured by a 99.7% increase in hydrophobicity. Additionally, water vapor permeability was reduced by an impressive 97.7%, and air permeability reached 0 mL/min. To enhance flexibility, glycerol was added as a plasticizer within the WPI formulation, resulting in improved elongation at break values for the coated papers. The viscosities of both the WPI and CW coating solutions exhibited good processability, suggesting potential suitability for scaling up to industrial processes. Finally, scanning electron microscopy and contact angle measurements confirmed the uniformity of the paper’s coated layer and strong interlayer adhesion, which are crucial factors for effective barrier performance.
Claire Stuppa, Julien Bley, Thi Thanh Ha Pham, Chenni Abdenour, Balázs Tolnai, Guy Njamen, Phuong Nguyen-Tri, Simon Barnabé, Bruno Chabot
Chapter 3. Using Fly Ash to Enhance the Mechanical Properties, Alkali Resistance and Waterproofing of Wall Primer Coating
Abstract
This work aims to use fly ash waste as a reinforcing filler for alkali-resistant wall primer. The fly ash surface was treated with an alkaline solution. The results of color analysis, mechanical properties, and FESEM analysis show that fly ash slightly reduces the brightness of the coating, increases its washout resistance and alkali resistance, and reduces its water permeability. Usable fly ash content is from 10 to 30%, the surface coating has few defects, only a few fly ash particles appear on the surface, and fly ash particles tend to distribute inside. The coating creates a tight structure. At these concentrations, the primer has technical specifications that meet and exceed the requirements of wall primer coating, according to TCVN 8652:2012. In particular, the washout durability, alkali resistance, and waterproofing of the coating have been enhanced. Paint formulations containing fly ash can be applied and commercialized.
Thi Huong Thuy Hoang, Thi Ngoc Nguyen, Hong Nam Vu, Thi Nga Nguyen, Truc Vy Do, Phuong Nguyen-Tri, Thien Vuong Nguyen
Chapter 4. Synthesis of Antimicrobial and Biodegradable Polyhydroxybutyrate Films Embedded with Zinc Oxide NPs by Casting Method
Abstract
This study explores the development of novel biodegradable and antimicrobial materials for personal protective equipment (PPE), focusing on environmental sustainability and biological resistance. The research introduces an innovative approach using biodegradable polyhydroxybutyrate (PHB) polymer, combined with Zinc Oxide (ZnO) NPs to enhance antibacterial properties. The report categorizes various antibacterial materials, emphasizing the unique qualities of PHB as a biodegradable alternative to petrochemical-sourced plastics. Additionally, it delves into the mechanisms of antibacterial action of ZnO NPs, highlighting their effectiveness in generating reactive oxygen species (ROS) and Zn2+ ions to combat bacterial threats. The study concludes with the successful synthesis of PHB films embedded with ZnO NPs, demonstrating their potential as a sustainable and effective solution for PPE in response to the increasing demand for environmentally friendly and biologically resistant materials.
Juliette Vallée-Bastien, Bich Van Tran, Safa Ladhari, Nhu-Nang Vu, Phuong Nguyen-Tri
Chapter 5. Preparation of Cotton Coated with ZnO-Ag Hybrid NPs for Photocatalytic Inactivation of Bacteria Under LED Light
Abstract
The use of effective antimicrobial surfaces could reduce both healthcare-associated infections and the proliferation of antibiotic-resistant bacterial strains. This paper introduced a new method of embedding ZnO-Ag hybrid NPs into cotton using a simple two-step synthesis. The effect of the concentration of the Ag nitrate solution, the hydrophobicity of the samples, their morphology, and the quantity of NPs on the samples were determined. The amount of ZnO in the samples ranged from 0.049 to 0.27 mg/cm2, and the amount of Ag varied between 0.0108 and 0.022 mg/cm2. The antibacterial activity of the samples was tested against Gram-negative E. coli bacteria in the dark and under LED light. The samples exhibited up to 100% antibacterial efficiency under LED light in just a few tens of minutes. From these results, a mechanism of photocatalytic inhibition under LED light of bacterial growth was proposed. Together, these results demonstrate that cotton coated with ZnO-Ag hybrid NPs prepared in this study is a promising material for the creation of antimicrobial textiles.
Cédrik Boisvert, Nhu-Nang Vu, Safa Ladhari, Marcos Antonio Polinarski, François Brouillette, Phuong Nguyen-Tri
Chapter 6. Innovations in Textile Technology Against Pathogenic Threats: A Review of the Recent Literature
Abstract
The current work offers an insightful literature review on the intersection of pathogenic agents and textile technology. It begins by classifying and discussing the characteristics of pathogens, such as bacteria and viruses, alongside their transmission methods and risks. The review progresses to explore the strategies for mitigating these risks, focusing on the adhesion of pathogens to surfaces and innovative solutions like Reactive Oxygen Species (ROS) generation and surface modifications. A significant emphasis is placed on the advancements in textile technology, including the exploration of antimicrobial agents like metallic NPs and natural products, as well as the development of self-cleaning textiles through techniques like the sol–gel process. This chapter encapsulates the critical role of textile innovation in addressing pathogenic challenges, highlighting the importance of ongoing research and development in this dynamic field.
Camille Venne, Nhu-Nang Vu, Safa Ladhari, Phuong Nguyen-Tri
Chapter 7. Synthesis of an Ecological Material for the Photocatalytic Degradation of Bisphenol A
Abstract
This study presents a novel photocatalytic method for Bisphenol A (BPA) degradation using graphitic carbon nitride (g-C3N4) coupled with carbon quantum dots (CQDs) as a co-catalyst. Addressing the challenge of plastic pollution, particularly in marine ecosystems, the research focuses on enhancing the efficiency of BPA degradation through photocatalysis. The composite material synthesized using urea and CQDs and exposed to LED light demonstrated significant improvement in BPA degradation. UV–visible spectrometry confirmed a 100% degradation rate within 6 h using 0.1% CQDs, surpassing typical environmental degradation rates. The study highlights the potential of this photocatalytic method as an effective, environmentally friendly solution for mitigating plastic pollution, with future work aimed at optimizing the method’s efficiency and structure.
Corentin Bianquis, Nhu-Nang Vu, Houssam-Eddine Nemamcha, Phuong Nguyen-Tri
Chapter 8. Water-Based Acrylic polymer/TiO2 Coatings: Influence of the Size of TiO2 Particles (Micro- and Nano-) on Mechanical Characteristics and Weathering Resistance
Abstract
This work aims to clarify the difference between the influence of TiO2 particles at micrometer and nanometer sizes on the mechanical properties and weathering durability of water-based acrylic coatings. Micro-R-TiO2 and nano R-TiO2 particles with 2 wt% content were dispersed in the emulsion acrylic polymer by ultrasonic vibration to prepare coatings. The coatings without TiO2 particles, with 2 wt% micro R-TiO2 and with 2 wt% nano R-TiO2 were tested for abrasion resistance, weathering aging in UV/CON accelerated weathering chamber. Weathering aging was assessed by IR quantitative analysis, as well as the weight loss of the coating. The results showed that the micro R-TiO2 with the 2 wt% content simultaneously enhanced the abrasion resistance and weathering durability of water-based acrylic coatings but not as effectively as nano R-TiO2. The incorporation of 2 wt% micro-R-TiO2 slightly increased the abrasion resistance of coating from 78.4 to 98.9 lite/mil (26% increase) while with addition of nano-R-TiO2 at the same content, the abrasion resistance was significantly improved from 78.4 to 129.3 lite/mil (65% increase). After 48 aging cycles, the alkane CH groups and weight of the coatings without R-TiO2 particles, containing 2 wt% micro-R-TiO2, containing nano-R-TiO2 lost 34.2% and 17.4%; 23.8% and 13%; 13.7% and 13%, respectively.
Thu Ha Hoang, Thi Huong Thuy Hoang, Tuan Anh Nguyen, Phuong Nguyen-Tri, Thien Vuong Nguyen
Chapter 9. Conversion of Residual Biomass to 2D Materials for Energy and Environmental Applications
Abstract
Water pollution is a critical global issue exacerbated by the release of domestic and industrial wastewater into the environment. This wastewater often contains harmful contaminants like heavy metals (e.g., Pb, As, Hg, Zn, Ni) and synthetic organic dyes (e.g., methylene blue, congo red, crystal violet), posing threats to human health and ecosystems. Adsorption using carbonaceous adsorbents offers a cost-effective, efficient, and environmentally sound solution to remove these pollutants, making it ideal for developing countries. Biomass-derived, graphene-like materials show promise as eco-friendly adsorbents with superior contaminant removal capabilities. Salix, a rapidly growing willow tree common in Canada, provides a potential source for graphene-like carbon materials through pyrolysis. This study explores a two-stage thermal pyrolysis process of Salix with NaCl addition to synthesize graphene-like materials tailored for wastewater treatment. Extensive characterization methods analyze the surface area, morphology, and crystallinity of the resulting carbon materials. The adsorption efficiency is tested by varying parameters like adsorbent dosage (0.25–1.25 g/L), contact time (0–180 min), and initial MB dye concentration (80–180 ppm). Results indicate pseudo-first-order adsorption kinetics. The synthesized carbon materials demonstrate an impressive maximum adsorption capacity of 195.4 mg/g at room temperature.
Quang Thanh Dinh, Nhu-Nang Vu, Phuong Nguyen-Tri
Chapter 10. Efficiency of Activated Carbon from Date Palm Leaf Sheath in Removing of Methylene Blue from Aqueous Solution: Pyrolysis Optimisation
Abstract
Pyrolysis is a solution using thermochemical processes to recover solid waste. The conditions for pyrolysis of activated carbon from palm leaf sheath have been optimized. The best results in terms of Methylene Blue removal efficiency were obtained for chemical activation in sulfuric acid (H2SO4) 96% for a period of 2 h at room temperature (30 °C), and a ratio 1:3. Carbonization was carried out by conventional heating at different temperatures (from 350 to 450 °C) and for different durations of 1.5–2.5 h. The best dye removal efficiency (87.8%) was observed for pyrolysis carried out at 450 °C and 2.5 h. The effects of temperature and duration of pyrolysis were studied using an experimental design. The final removal efficiency after activation was modeled as a first-order polynomial model:
$$Yield = 32.435 + 0.074 \times Temperature + 4.803 \times time$$
Karim Kriaa
Chapter 11. Optimization of Initial Cutting Parameters for a Turning Process Based on the Response Surface Methodology
Abstract
Assessing tool wear is crucial for determining the machinability of cutting operations, with the initial cutting conditions having a significant impact on both tool wear and longevity. This study examines how starting cutting parameters affect tool wear during the machining of TiMMC. Findings indicate a rapid increase in initial wear alongside rises in cutting force and speed. The peak cutting force is reached within approximately 5 s, coinciding with the period where initial wear stabilizes across all tested cutting conditions. Notably, the early stage of tool wear, which unfolds in a brief timeframe, contributes to as much as 39% of total wear across both initial and steady wear phases. The primary mechanisms of wear in this phase are identified as adhesion and diffusion. To optimize the initial cutting conditions with the goal of reducing early tool wear, this research employs response surface methodology (RSM) and central composite design (CCD). Further, an analysis of variance (ANOVA) is utilized to evaluate the regression model of the cutting process, enabling the optimization of cutting parameters through empirical response equations and the development of a 3D model to visualize the effects.
Xuan Truong Duong, Phuong Nguyen-Tri, J. R. R. Mayer, Cong Hieu Luong, Marek Balazinski
Chapter 12. Identification of the Elements of an Industrial Rubber of Unknown Formulation
Abstract
This work deals with the identification of organic and inorganic elements of a rubber supplied by an industrial partner. The rubber formulation is not known. For this purpose, a methodology based on reverse engineering was followed to identify the rubber composition. Information on the material composition and rubber formulation was obtained using several characterization techniques such as acetone extraction, TGA and DSC thermal analysis, infrared spectroscopy, GC-MS and X-ray fluorescence. The interpretation of the results showed that industrial rubber is mainly composed of styrene-butadiene polymer, additives such as BHT and carbon black. Also, mineral elements like zinc, silica, aluminum and magnesium.
Rachid Amrhar, Mostafa Eesaee, Phuong Nguyen-Tri
Chapter 13. Elastomer Service Life: The Role of Thermal and Mechanical Test Data in Predictive Analysis
Abstract
This study discusses the predictive analysis of elastomer service life, emphasizing the importance of thermal and mechanical testing data. It explores the responses of various elastomer types to environmental stressors and their implications for durability and application. The research highlights the need for refined testing methodologies to enhance predictive accuracy and discusses future directions, including the integration of advanced technologies like AI and nanotechnology. The findings offer significant insights into the sustainable development and efficient use of elastomers in diverse industrial applications.
Imen Hamouda, Mostafa Eesaee, Phuong Nguyen-Tri
Chapter 14. Mathematical Modeling for Identifying the Unknown Thermal Properties of Material in Phase Change Memory
Abstract
The fundamental principle of two techniques, namely the 3-omega (contact) and Modulated photothermal radiometry (contactless) have been described. Models for identifying the thermal properties of thin film structures have been presented with a specific focus on a multi-layer thin film (IST/SiO2/Si) configuration featuring a phase change chalcogenide material known as InSbTe (IST) on top. This IST thin film is used as the active layer in Phage Change Memory (PCM), an emerging technology for non-volatile storage. Despite the difference in the shape of the heat flux distribution, the heat transfer model shows similarities for both techniques. Finally, by using a protocol, the thermal conductivity k and related thermal boundary resistances (TBRs) of layer of interest can be estimated.
Huu Tan Nguyen, Phuong Nguyen-Tri
Chapter 15. Modeling and Optimization of the Adsorption Process of Pharmaceutical Residues in Aqueous Solution by the Experimental Design Method
Abstract
The presence of pharmaceutical compounds in hospital and domestic effluents poses a serious environmental problem, hence the need to treat them before discharging into nature. Among the treatment methods, the activated carbon (AC) adsorption process is the method of choice for its simplicity and ease of implementation. However, the high regeneration cost of AC has prompted the scientific community to search for new adsorbents. Our study involves testing a polymer made of cyclodextrins cross-linked with citric acid. The adsorption capacity of this polymer is evaluated against the ibuprofen molecule. To study the effect of certain parameters on the adsorption process, we used the experimental design method, which allows us, with a minimum of experimental trials, to draw a maximum of information on the process under study. The results of the experiments conducted, following a five-level central composite design and respecting the rotatability criterion, are used to find a relationship between the adsorption rate y (%) and the three considered and deemed influential parameters, namely the initial ibuprofen concentration [IB]0, the flow rate of the solution (W), and the mass of the adsorbent (mads). The statistical model that fits our experimental data well is a second-degree model without any interaction between the three factors. A maximum adsorption rate of 78.5% is obtained under the following optimal conditions: [IB]0 = 16.3 mg/L, W = 16.4 rpm, and mads = 147.5 mg. The plotting of iso-response curves allows locating the optimum in the plan of two chosen factors.
Fadila Oughlis-Hammache, Lamia Moulahcene, Ounissa Senhadji-Kebiche, Nacera Moussi, Hakima Meziani, Mohamed Benamor, Mohamed Skiba, Malika Lahiani-Skiba
Metadaten
Titel
Materials for Sustainable Environmental, Energy, and Bioresource Applications
herausgegeben von
Phuong Nguyen-Tri
Copyright-Jahr
2024
Electronic ISBN
978-3-031-60255-9
Print ISBN
978-3-031-60254-2
DOI
https://doi.org/10.1007/978-3-031-60255-9