SOUAD Talhi
طلحي سعاد
souad.talhi@univ-msila.dz
0559862612
- Departement of Chemistry
- Faculty of Sciences
- Grade PHd
About Me
Sciences de la Matière
Filiere
Chimie
Location
Msila, Msila
Msila, ALGERIA
Code RFIDE- 1997-05-07 00:00:00
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SOUAD Talhi birthday
- 2024-12-18
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2024-12-18
Water treatment use the Hydroxide Double Layer: Synthesis of NiFeCO3 by co-precipitation method.
The presence of various organic pollutants in wastewater, surface water, and groundwater can be attributed to sources such as contaminated soil, agricultural runoff, industrial wastewater, and leaks from the storage of hazardous compounds. These pollutants, which include dyes, volatile phenols, benzene, and benzene derivatives, are highly toxic and difficult to biodegrade. Conventional treatment methods, such as biological processes, may not be effective in removing these substances. Therefore, advanced treatment techniques are necessary to enhance water quality by eliminating dyes. Layered Double Hydroxides (HDLs), particularly NiFeCO3 HDLs, also known as nickel-iron carbonate, are complex mineral compounds that have attracted considerable interest in materials science, energy storage, and wastewater treatment. Composed of nickel, iron, and carbonate ions, these compounds possess unique structures and properties. In this study, NiFeCO3 HDL was synthesized using a co precipitation method. The physicochemical characterization was conducted through various analytical techniques, including X-ray diffraction (XRD), differential thermal analysis (DTA), Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), and surface characterization using BET analysis. The physicochemical analysis, alongside assessments of the material's electrochemical and catalytic properties, demonstrated that NiFeCO3 HDLs possess significant potential as anode materials for lithium-ion batteries. They exhibit high capacity, excellent rate capability, and remarkable cycling stability. Additionally, the inclusion of iron in the structure enhances the material's catalytic properties. The combination of nickel and iron within the HDL structure results in unique activity, making it suitable for applications in water purification.
Citation
Souad TALHI , ACHOUR Dakhouche , Abderrahmane hiri , gha.radji@univ-adrar.edu.dz, ,(2024-12-18), Water treatment use the Hydroxide Double Layer: Synthesis of NiFeCO3 by co-precipitation method.,2ÈME SÉMINAIRE NATIONAL Matériaux pour l’Environnement et le Développement Durable (MEDD) (webinaire),Université de Relizane
- 2024-12-16
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2024-12-16
Treatment of Water By Hydroxide Double Layer: Synthesis, Cracterization and Application.
Water is essential for life, yet many aquatic environments face imperilment by noxious contaminants. Valuable waterways are compromised by an array of pollutants stemming from human activities and waste disposal. A wealth of recent scientific work has focused on the potency of layered double hydroxides to sequester an alarming group of toxic chemicals commonly found in effluent. These alkaline compounds show aptitude for withdrawing harmful dyes, pharmaceutical residues, and additional man-made toxins that jeopardize the purity of rivers and oceans. Further research on maximizing the adsorptive properties of LDHs may help safeguard water quality and supply. Suitable remediation tactics are urgently needed to curb the accumulation of destructive pollutants in crucial water sources. Double layer hydroxides showcase a laminated architecture composed of sheets displaying alternating planes containing divalent and trivalent cations. Numerous techniques have been created for synthesizing the HDL phase with the aim of improving certain characteristics, such as crystallite dimensions (which can fluctuate from a handful of nanometers to several microns), morphology, specific surface region, and crystallinity. Of these approaches, three are generally utilized: co-precipitation, anion substitution, and reformation. Heavy metals and dyes are highly hazardous industrial pollutants that pose significant risks both to the environment as well as to human health. Therefore, there is aurgent need for remediation methods that are simple, cost-effective as well as scalable. Layered double hydroxides, also known as LDHs, have emerged as very promising candidates due to their unique blend of characteristics. These include structures that can be easily adjusted, synthesis procedures that are straightforward to execute, as well as stability, large surface areas and the capability to form various nanocomposites. Due to their adjustable structures, large surface areas and ability to form nanocomposites, LDHs are particularly potent in adsorbing an extensive assortment of pollutants from wastewater. This article will focus on the diverse synthesis techniques employed for generating LDH-based materials, examining their structural features thoroughly, outlining techniques for thorough physicochemical characterization, and exploring their diverse applications in eco-friendly pollutant remediation.
Citation
Souad TALHI , ACHOUR Dakhouche , gha.radji@univ-adrar.edu.dz, ,(2024-12-16), Treatment of Water By Hydroxide Double Layer: Synthesis, Cracterization and Application.,Seminaire international sur Risques naturels, gestion des territoires urbains et outils d'analyse "les atouts de l'intelligence artificielle",Université Mohamed Boudiaf -M'sila
- 2024-12-11
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2024-12-11
Wastwatet treatment by nickel-iron layered double hydroxide (LDH).
Water is a scarce resource and is considered a fundamental pillar of sustainable development. The modern development of society requires more and more drinking water. For this cleaner wastewater, treatments are key factors. Among those that exist, Layered Double Hydroxides (HDLs). NiFeCO3 HDLs, also known as nickel iron carbonate, is a complex mineral compound that has gained significant attention in the fields of materials science and energy storage and wastewater treatments. This compound is composed of nickel, iron, and carbonate ions, and its unique structure and properties have made The synthesis of NiFeCO3 HDLs has been extensively studied, and various methods have been employed, such as co precipitation, hydrothermal, and sol-gel techniques. In this work, NiFeCO3 HDL was synthesized using co-Wastewater Treatment by nickel–iron layered double hydroxide (LDH). precipitation method. Physicochemical characterization was carried out using analytical methods: X-ray diffraction (DRX), differential thermal analysis (ATG), Scanning electron microscopy (SEM).
Citation
Souad TALHI , ACHOUR Dakhouche , Abderrahmane hiri , gha.radji@univ-adrar.edu.dz, ,(2024-12-11), Wastwatet treatment by nickel-iron layered double hydroxide (LDH).,1st National Conference on Sustainable Management of Waste, Effluents and Emissions (CSMWEE-2024),ENSET–Skikda
- 2024-12-10
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2024-12-10
Layered double hydroxides: Nanomaterials for application in waste treatment water
Freshwater resources are being threatened by the activities of a growing population and the escalating rate of overuse. Water pollution, caused by effluents from industrial, agricultural, and domestic sources, is detrimental to the environment. Consequently, reducing pollution through the adoption of eco-friendly technologies has become extremely important. Synthetic dyes, commonly utilized in various industries such as textiles, leather tanning, printing, and food processing, are one of the harmful effluents that need to be addressed. The treatment of effluents from textile industries typically involves using physico-chemical techniques and biological methods to remove organic matter, nitrogen, phosphorus, and metals. However, these traditional approaches have been found to be inefficient. Currently, there is a high priority among the scientific community to develop environmentally-friendly and cost-effective technologies for removing dyes from textile effluents. Layered double hydroxides (LDH) with adsorption properties have been found to be promising in water treatment due to their ease of adsorption and recyclability. The LDH, also known as hydrotalcite like compounds or anionic clays, are 2-D nano-materialsthat can be used as storage matrix (hosting), and control the release of different anionic species, LDH present a great number of properties due to their varied compositions and methods of synthesis. In this study, the preparation and characterization of LDHs will be discussed through the following methods and techniques: DRX, MEB, ATG, BET. Layered double hydroxides (LDHs) have proven to be good candidates for removing anionic dyes from aqueous solutions and waste treatment in water. These materials, which are endowed with high anionic exchange capacity and good adsorptive ability.
Citation
Souad TALHI , ACHOUR Dakhouche , Abderrahmane hiri , gha.radji@univ-adrar.edu.dz, ,(2024-12-10), Layered double hydroxides: Nanomaterials for application in waste treatment water,1ST National Conference: Water, Environment and Renewable Energies SN3ER’24,University Mohamed Boudiaf of M’sila
- 2024-12-09
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2024-12-09
Séparation et élimination efficaces des polluants des eaux usées par des hydroxydes doubles synthétisés par la méthode de co-précipitation et leur caractérisation.
L'eau est une ressource rare et un pilier essentiel du développement durable. La croissance de la société moderne exige un approvisionnement croissant en eau potable. Le traitement des eaux usées joue un rôle essentiel pour relever ce défi. Parmi les diverses méthodes de traitement disponibles, les hydroxydes doubles stratifiés sont étudiés en tant que solution durable. L'objectif principal de ce manuscrit est de présenter les avancées scientifiques dans ce domaine. Les hydroxydes doubles (HDL) ont une structure bidimensionnelle composée de couches alternées de lamelles contenant des cations divalents et trivalents. Diverses méthodes de synthèse de la phase HDL ont été mises au point pour améliorer des propriétés spécifiques, notamment la taille des cristallites (qui peut varier de quelques nanomatériaux à plusieurs microns), la morphologie, la surface spécifique et la cristallinité. Parmi ces méthodes, trois sont les plus couramment employées : la co-précipitation,échange ;anions et la reconstruction. Les métaux lourds et les colorants sont des polluants industriels très dangereux qui présentent des risques significatifs pour ;environnement et la santé humaine. Il est donc urgent de trouver des méthodes assainissement simples et rentables. Les hydroxydes doubles stratifiés (LDH) sont apparus comme des candidats prometteurs en raison de leurs caractéristiques uniques, notamment leurs structures ajustables, leurs procédures de synthèse simples, leur stabilité, leurs grandes surfaces et leur capacité à former divers nanocomposites. Ces propriétés rendent les LDH particulièrement efficaces pour adsorber une large gamme de polluants dans les eaux usées. Cet article se concentre sur les méthodes de synthèse des matériaux à base de LDH, leurs caractéristiques structurelles, les techniques de caractérisation physicochimique et leurs applications dans la remédiation des polluants. Les Ni-Fe HDL constituent une option fiable pour les applications de traitement de l'eau, car ils présentent une bonne stabilité dans diverses conditions environnementales, telles que le pH et la température.
Citation
Souad TALHI , ACHOUR Dakhouche , gha.radji@univ-adrar.edu.dz, ,(2024-12-09), Séparation et élimination efficaces des polluants des eaux usées par des hydroxydes doubles synthétisés par la méthode de co-précipitation et leur caractérisation.,The First International Conference on Civil Engineering and Materials Innovation 1st ICCEMI’24 (Hybrid Conference),Université de Mascara
- 2024-12-09
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2024-12-09
Using layered double hydroxides (LDHs) to remove color and organics from water.
Industrialization is the primary cause of water and environmental pollution. The release of various pollutants, such as heavy metals, anions, dyes, organic compounds, pharmaceutical drugs, and pesticides, into the water has detrimental effects on the environment, human health, and wildlife. Therefore, it is crucial to develop technologies that can effectively remove toxic pollutants from water and wastewater in order to ensure its safety for human consumption. Many efforts have been made to remove dissolved organic dyes from wastewater, culminating in the development of materials such as double layer hydroxide (HDL). Hydrotalcite materials (HDL) are a type of layered compounds that are easily synthesized, non-toxic, and inexpensive. They also have a wide range of physical and chemical properties. Layered compounds are a class of compounds with a lamellar structure, allowing for ion exchange between the layers and possessing cationic characteristics. In this article, we will focus on the synthesis methods of LDH-based materials, their structural features, techniques for physicochemical characterization, and their applications in pollutant remediation. Layered double hydroxides (LDHs) have emerged as promising candidates due to their unique characteristics, such as adjustable structure, straight forward synthesis procedures, stability, large surface area, and the ability to form various nano-composites. These properties make LDHs highly effective in adsorbing a wide range of pollutants from wastewater.
Citation
Souad TALHI , ACHOUR Dakhouche , Abderrahmane hiri , gha.radji@univ-adrar.edu.dz, ,(2024-12-09), Using layered double hydroxides (LDHs) to remove color and organics from water.,The 3rd National Environment & Sustainable Management Seminar,Mostaganem - Algeria
- 2024-11-27
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2024-11-27
Application Of Layered Double Hydroxides NIFECO3 Nanomaterials In Biotechnology
Novel materials are designed by exploring the nano scale properties of the matter. Nano and biomaterials can be combined together and further used as efficient tools in engineering, biomedicine, electronics and biotechnology. Layered Double Hydroxides (LDHs) are an important class of inorganic lamellar nanomaterials that have attracted considerable interest in life science applications due to their controllable synthesis and excellent biocompatibility. Layered double hydroxides, also known as anionic clays, are a type of hydrotalcite nanocomposite that holds significant potential for applications in nanotechnology and biotechnology. Layered double hydroxides (LDHs) have attracted considerable attention in biomedical applications because of their outstanding properties, such as excellent biocompatibility, degradability, interlayer ion exchangeability, high loading capacity, pH-responsive release, and a large specific surface area. Additionally, their structural composition is flexible, and surface modification is straightforward, allowing for the creation of specifically functionalized LDHs designed to address the diverse needs of various applications. The aim of this study was to synthesise NiFeCO3 nanoparticles using the co-precipitation method, characterise them and determine their effectiveness in the biomedical and biotechnological fields. These materials are studied for their unique properties and technological significance in various fields, including catalysis, drug delivery, medical science, cosmetics, biosensing, and nanocomposite material engineering. This paper provides an overview of the most recent applications of layered double hydroxides (LDHs) in biomedicine and biosensing.
Citation
Souad TALHI , ACHOUR Dakhouche , gha.radji@univ-adrar.edu.dz, ,(2024-11-27), Application Of Layered Double Hydroxides NIFECO3 Nanomaterials In Biotechnology,International Seminar On Beekeeping-Plant And Innovative Technology November 27th- 28th,2024,University Khemis Miliana
- 2024-11-20
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2024-11-20
CO-PRECIPITATION SYNTHESIS, CHARACTERIZATION AND APPLICATIONS OF SPINEL FERRITE NANOPARTICLES.
The synthesis of spinel ferrite nanoparticles is rapidly gaining popularity as a research field, driven by technological interests and their appealing magnetic properties. Spinel ferrites have the general formula MFe2O4, with M representing a divalent metal ion. These compounds exhibit a cubic structure and are utilized across a variety of technological applications. Over the past decade, ferrite nanoparticles have attracted considerable interest due to their high permeability, electrical resistivity, and advantageous electromagnetic properties. Consequently, they are well-suited for numerous applications, including magnetic storage, microwave devices, biosensors, drug delivery, disease diagnosis, gas sensors, energy conversion, photocatalysis, and magnetic separation. Several studies have been conducted on the preparation of this type of ferrite using various chemical methods. In this study, NiFe2O4 spinel nickel ferrite was synthesized using the coprecipitation method. The physicochemical properties were characterized through various analytical techniques, including X-ray diffraction (XRD), differential thermal analysis (DTA), scanning electron microscopy (SEM), and Fourier transform infrared spectroscopy (FTIR). Nickel ferrite (NiFe2O4) is a significant soft ferrite utilized in various industries, appreciated for its qualities that make it ideal for soft magnetic core materials in power transformers and as a photocatalyst. It possesses low coercivity and high electrochemical stability. Ferrites produced using this method display smaller particle sizes, smooth surfaces, stability, and a homogeneous structure.
Citation
Souad TALHI , ACHOUR Dakhouche , Abderrahmane hiri , gha.radji@univ-adrar.edu.dz, ,(2024-11-20), CO-PRECIPITATION SYNTHESIS, CHARACTERIZATION AND APPLICATIONS OF SPINEL FERRITE NANOPARTICLES.,3ed ICMM 2024 INTERNATIONAL CONFERENCE ON MATERIALS AND MECHANICS 20-21 November, Boumerdes University – Algeria,Boumerdes University – Algeria
- 2024-11-18
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2024-11-18
Eco-Friendly Synthesis of ZnO Nanoparticles and Their Photocatalytic Performance
Water contamination by dyes is an important environmental issue due to their negative effect on the ecosystem and human health. Dyes are widely used in various industries; because of their complex structure and chemical stability, it is difficult to degrade them by conventional treatment methods. Moreover, these methods can be expensive and produce by-products, which cause secondary pollution that needs additional attention. The potential application of nanoparticles in wastewater treatment has attracted a lot of attention. They can be synthesized through various physicochemical processes. Recently, scientific research has focused on the biosynthesis of nanoparticles from plant extracts due to its many benefits, including simple implementation, plentiful raw material availability, and special characteristics that these extracts can contribute to the nanoparticles. The current research is an in-depth investigation and characterization of ZnO nanoparticles using various techniques (XRD, SEM, and TGA) and their application in the treatment of water contaminated by dyes. The results of the parametric study revealed that a system containing 30 ppm of dye and 30 mg of ZnO exhibited high photocatalytic activity with an elimination rate of 71% after 60 minutes. In conclusion, this study has demonstrated that ZnO nanoparticles have potential qualities for treating water. The optimization of operating conditions has significantly improved the yields of decolorization.
Citation
Meriem Imane KHALED , Abdelhakim KHENICHE , Souad TALHI , Serine ARIS , kadi imed eddine, Trari mohammed, ,(2024-11-18), Eco-Friendly Synthesis of ZnO Nanoparticles and Their Photocatalytic Performance,1 st National Conference on Sustainable Management of Waste, Effluents and Emissions (CSMWEE-2024),L'École normale supérieure d'enseignement technologique (ENSET) de skikda,
- 2024-10-30
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2024-10-30
Élaboration et application des nanoparticules
Ce travail présente une analyse approfondie sur la synthèse des nanoparticules à base d'un extrait aqueux d'une plante médicinale, leurs caractérisations structurales et l'évaluation de leur potentiel dans le traitement des eaux contaminées par un colorant alimentaire par photo dégradation. De nos jours, les nanomatériaux attirent un intérêt considérable en raison de leur fort potentiel dans divers domaine [1]. Différents procédés physicochimiques peuvent être utilisés pour leur synthèse [2], mais récemment, la recherche scientifique s'est orientée vers la biosynthèse des nanoparticules à base des plantes [3]. Cette méthode présente de nombreux avantages, tels que la simplicité de la mise en œuvre et la disponibilité abondante de la matière première [4]. En raison de leur complexité structurelle et de leur stabilité chimique, l'impact écologique de la libération des colorants dans l'environnement est devenu de plus en plus préoccupant, ce qui a entraîné le développement de nouvelles techniques de purification des eaux plus performantes [5]. L'intégration de la photo dégradation des nanoparticules dans les systèmes de traitement des eaux offre un très grand potentiel du fait qu'elle contribue à la préservation de notre environnement et à la protection de notre santé [6].
Citation
Meriem Imane KHALED , Abdelhakim KHENICHE , Souad TALHI , Trari Mohammed, ,(2024-10-30), Élaboration et application des nanoparticules,1ère Conférence internationale sur les applications technologiques des matériaux (ICTAM'2024),Université Ferhat Abbas, Sétif1
- 2024-10-30
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2024-10-30
Synthesis and application of layered double hydroxide: Nanomaterial for applications in water treatment.
In recent years, nanostructured magnetic nanocomposites have received increasing attention due to their unique chemical and physical properties and their inexpensive nature and their wide range of applications in several fields such as pharmaceuticals, energy, water treatment and catalysts. Many nanomaterials have been prepared and the most effective is the layered double hydroxide (LDH) recognized as anionic clays or brucite-like compounds, these two subclasses are significant types of ionic layered materials. The primary components of LDHs are the charged layers, which offer a variety of chemical compounds with versatile applications, such as biocompatibility, adsorption, intercalation, and ion exchange, these are the foundations of the diverse technological applications of LDHs across various fields, including medicine, polymer industries, electrochemistry, food, catalysis, and drug delivery. Compared to other drug delivery mechanisms, which often suffer from low circulation stability, poor bioavailability, and drug degradation, LDHs serve as exceptional drug nano-carriers. They are relatively cost-effective, exhibit low toxicity to cells, and demonstrate good biocompatibility. In this study, NiFeCO3 HDL was synthesized using the coprecipitation method. The physicochemical characterization was performed with various analytical techniques, including X- ray diffraction (XRD), differential thermal analysis (DTA), Fourier transform infrared spectroscoy (FTIR), scanning electron microscopy (SEM), and surface characterization using the BET method. Using physicochemical analysis methods and evaluating the electrochemical and catalytic properties of the material,. The integration of nickel and iron into the HDL structure provides unique activity, making it suitable for applications in water purification (specifically for eliminating colorants through advanced oxidation processes), energy conversion, and electrocatalysis.
Citation
Souad TALHI , Abderrahmane hiri , ACHOUR Dakhouche , gha.radji@univ-adrar.edu.dz, ,(2024-10-30), Synthesis and application of layered double hydroxide: Nanomaterial for applications in water treatment.,The 1st International Conference on Technological Applications of Materials (ICTAM'24),Setif 1 University, Algeria
- 2024-10-27
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2024-10-27
Green synthesis and characterization of ZNO nanoparticles: photocatalytic activity
Nanoscience and nanotechnology are the most recent growing areas, with substantial advances in physics, chemistry, biology, molecular engineering, and other fields. Nanomaterials are widely used in the pharmaceutical, cosmetic, textile and even electrical and electronic industries. Scientists are investigating the use of plants and microorganisms (bacteria, fungus, yeasts, etc.) as bioreactors for the synthesis of nanoparticles due to the potential applications of these materials in a wide range of sectors. The biosynthesis of nanoparticles using plant extracts is particularly appealing because of its simplicity and the unique properties conferred by the extracts. This present work provides a thorough investigation into the bio production and the application of ZnO nanoparticles in wastewater treatment. Zinc oxide nanoparticles (ZnO NPs) were successfully synthesized using Capparis Spinosa leaf extract and have been examined for their potential photocatalytic properties. Structural, compositional, and morphological characteristics were thoroughly studied. XRD examination revealed wurtzite's hexagonal structure, with an average particle size of 42 nm, while FTIR analysis identified biomolecules and functional compounds in leaf extract that are responsible for nanoparticle stabilization. SEM analysis indicated a uniform distribution of particles. A band gap of 3.27 eV was determined by UV-Vis spectroscopy. The effectiveness of dye degradation has been optimized through a parametric study demonstrated that a system with 30 mg/L of dye and 30 mg of ZnO exhibited significant photocatalytic activity after 75 minutes, achieving a degradation rate of 74.17%. In conclusion, zinc oxide nanoparticles have been successfully prepared and characterized, proving their efficacy and viability as an environmentally eco-friendly method for water treatment.
Citation
Meriem Imane KHALED , Souad TALHI , Abdelhakim KHENICHE , Kadi imed eddine, Trari Mohamed, ,(2024-10-27), Green synthesis and characterization of ZNO nanoparticles: photocatalytic activity,International Seminar on Materials and Engineering Structures (ISMES’2024),University of Relizane
- 2024-10-15
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2024-10-15
Synthèse verte et application des nanoparticules ZnO pour le traitement des eaux.
La pollution des eaux par les colorants est une préoccupation environnementale majeure en raison de leur impact négatif sur l'écosystème et la santé humaine. Les colorants sont largement utilisés dans diverses industries et présentent une complexité structurelle et une stabilité chimique qui les rend difficiles à se dégrader par les procédés de traitement conventionnels. De plus, ces méthodes peuvent être coûteuses et générèrent des sous-produits, créant ainsi une pollution secondaire qui nécessite une attention supplémentaire. Les nanoparticules sont largement étudiées en raison de leur rôle potentiel dans divers domaines, notamment les sciences biomédicales, l'industrie chimique et électronique… Les nanoparticules suscitent un intérêt considérable dans la dépollution des eaux usées. Leur synthèse peut être réalisée par divers procédés physicochimiques, mais récemment, la communauté scientifique se tourne plutôt vers l'utilisation d'organismes vivants (bactéries, champignons, plantes, levures…) L’intérêt de la biosynthèse de ses nanomatériaux à base des extraits des plantes présente plusieurs avantages, tels que la simplicité de mise en œuvre, la disponibilité abondante des matières premières et les propriétés spécifiques que ces extraits peuvent conférer aux nanoparticules. Ce travail présente une analyse détaillée et caractérisation approfondie par différentes techniques (DRX, MEB et ATG) et l'application des nanoparticules ZnO dans le traitement des eaux contaminées par les colorants. Les résultats de l"étude paramétrique ont révélé qu'un système contenant 30 ppm de colorant et 30 mg de ZnO présentait une activité photo catalytique élevée avec un taux de décoloration de 74,17 % après 75 minutes. En conclusion, cette étude a démontré que les nanoparticules de ZnO possèdent des propriétés prometteuses pour le traitement des eaux. L'optimisation des conditions opératoires a permis d'améliorer significativement les rendements de la décoloration.
Citation
Meriem Imane KHALED , Souad TALHI , Abdelhakim KHENICHE , Kadi Imed eddine, Trari mohemed, ,(2024-10-15), Synthèse verte et application des nanoparticules ZnO pour le traitement des eaux.,Mediterranean Conference on Environment, Risks and Health (MCERH),University of Mohamed Cherif Messaadia, (Souk-Ahras)