Spelling suggestions: "subject:"nano zero valent ion""
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Treatment of persistent organic pollutants in wastewater with combined advanced oxidationBadmus, Kassim Olasunkanmi January 2019 (has links)
Philosophiae Doctor - PhD / Persistent organic pollutants (POPs) are very tenacious wastewater contaminants with negative
impact on the ecosystem. The two major sources of POPs are wastewater from textile industries
and pharmaceutical industries. They are known for their recalcitrance and circumvention of
nearly all the known wastewater treatment procedures. However, the wastewater treatment
methods which applied advanced oxidation processes (AOPs) are documented for their
successful remediation of POPs. AOPs are a group of water treatment technologies which is
centered on the generation of OH radicals for the purpose of oxidizing recalcitrant organic
contaminants content of wastewater to their inert end products. Circumvention of the reported
demerits of AOPs such as low degradation efficiency, generation of toxic intermediates, massive
sludge production, high energy expenditure and operational cost can be done through the
application of the combined AOPs in the wastewater treatment procedure. The resultant
mineralisation of the POPs content of wastewater is due to the synergistic effect of the OH
radicals produced in the combined AOPs.
Hydrodynamic cavitation is the application of the pressure variation in a liquid flowing through
the venturi or orifice plates. This results in generation, growth, implosion and subsequent
production of OH radicals in the liquid matrix. The generated OH radical in the jet loop
hydrodynamic cavitation was applied as a form of advanced oxidation process in combination
with hydrogen peroxide, iron (II) oxides or the synthesized green nano zero valent iron (gnZVI)
for the treatment of simulated textile and pharmaceutical wastewater.
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Plating of nano zero-valent iron (nZVI) on activated carbon : a fast delivery method of iron for source remediation?Busch, Jan, Meißner, Tobias, Potthoff, Annegret, Oswald, Sascha January 2011 (has links)
The use of nano zerovalent iron (nZVI) for environmental remediation is a promising new technique for in situ remediation. Due to its high surface area and high reactivity, nZVI is able to dechlorinate organic contaminants and render them harmless. Limited mobility, due to fast aggregation and sedimentation of nZVI, limits the capability for source and plume remediation. Carbo-Iron is a newly developed material consisting of activated carbon particles (d50 = 0,8 µm) that are plated with nZVI particles. These particles combine the mobility of activated carbon and the reactivity of nZVI. This paper presents the rst results of the transport experiments. / Der Einsatz von elementarem Nanoeisen ist eine vielversprechende Technik zur Sanierung von Altlastenschadensfällen. Aufgrund der hohen Oberäche und der hohen Reaktivität kannn ZVI chlororganische Schadstoffe dechlorieren und zu harmlosen Substanzen umwandeln. Der Einsatz von Nanoeisen zur Quellen- und Fahnensanierung wird jedoch durch mangelnde Mobilität im Boden im eingeschränkt. Carbo-Iron ist ein neu entwickeltes Material, das aus Aktivkohlepartikeln (d50 = 0,8 µm) und nZVI besteht. Diese Partikel kombinieren die Mobilit ät von Aktivkohle mit der Reaktivität von nZVI. Dieser Artikel beschreibt erste Ergebnisse von Transportuntersuchungen.
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Potencijal primene stabilisanog i „zelenom“ sintezom produkovanog nano gvožđa (0) za remedijaciju sedimenta kontaminiranog metalima / Potential application of stabilized and "green" produced nano zero -valent iron for remediation of sediment contaminated with metalsSlijepčević Nataša 02 October 2020 (has links)
<p>Ekološki problem svetskih razmera predstavlja zagađenost sedimenta teškim metalima, usled negativnih ekoloških efekata metala na životnu sredinu. Mnoge zemlje i regioni, kao i naša zemlja suočavaju se sa ovom problematikom, koja je vrlo rasprostranjena usled sve brže urbanizacije i industrijalizacije, a sa sve većom nebrigom usled ispuštanja otpadnih voda bez prethodnog prečišćavanja u vodotokove. Prilikom promene uslova vodenog ekosistema, može doći do izluživanja metala i štetnih efekata na životnu sredinu kao i na zdravlje ljudi. Stoga je remedijacija sedimenata zagađenih metalima ključna aktivnost u okviru procesa potpune sanacije vodenog ekosistema, a ekonomične, efikasne i ekološki prihvatljive tehnike remedijacije su hitno potrebne i rado primenljive u tretmanu na velikoj skali. Pre primene remedijacione tehnike na velikoj skali, neophodna su ispitivanja pri laboratorijskim uslovima i pilot skali. Na kraju svakog uspešnog laboratorijskog ispitivanja nalaze se pilot istraživanja. Pomoću njih se dobija p ravi odgovor u smislu izbora optimalne tehnologije imajući u vidu investicione i operativne troškove,<br />postignuti rezultat i krajnje ciljeve u pogledu upravljanja postrojenjem i otpadom. U ovom radu ispitan je potencijal primene stabilisanog i zelenom sinte zom produkovanog nano Fe(0) zaremedijaciju sedimenta zagađenog teškim metalima. Kao remedijaciona tehnika odabrana je stabilizacija/solidifikacija, koja podrazumeva dodavanje agenasa za imobilizaciju metala u sedimentu sprečavajući time potencijalni rizik od izluživanja metala u životnu sredinu. Konvencionalni materijali poput letećeg pepela, cementa, gline se već odavno koriste u ovu svrhu. Kako u današnje vreme raste potražnja za novim, lako dostupnim agensima za stabilizaciju<br />sedimenta, došlo se na ideju o primeni nanomaterijala na bazi gvožđa, tj. nano Fe(0) stabilisanog nativnom glinom i produkovanog redukcijom pomoću organskih molekula prirodno prisutnih u ekstraktu lišća hrasta i crnog duda. Nanomaterijali su sintetisani i karakterisani različitim metodama i tehnikama. U nastavaku, u cilju efikasnosti njihove primene za stabilizaciju sedimenta, sprovedeni su ekstrakcioni i dinamički laboratorijski testovi izluživanja. Odabrane su smeše sedimenta i nanomaterijala koje su pokazale najbolju efikasnost tr etmana. Nakon toga se ispitivanje nastavilo na pilot skali, gde se pratilo ponašanje nanomaterijala u zavisnosti od konvencionalnih materijala koji su već u literaturi dokumentovani kao efikasni imobilizacioni agensi. Dodatna potvrda uspešnosti tretmana data je analizom i karakterizacijom s/s smeša nakon pilot ispitivanja Na osnovu dobijenih rezultata proces se uspešno pokazao pri laboratorijskim uslovima, a takođe i prilikom pilot tretmana, odnosno nakon pilot tretmana nije došlo do povećanih koncentracija izluživanja metala iz s/s smeša, kao ni degradacije smeša nakon procesa ovlaživanja tokom šest meseci. Na osnovu toga, ovako tertirani sediment se može bezbedno odlagati na deponije, ili pak iskoristiti za „kontrolisanu“ upotrebu, izgradnju puteva,kamenoloma, pomoćnih objekata i slično. Rezultati su doprineli u cilju trajnijeg rešavanja pitanja odlaganja zagađenog (izmuljenog) rečnog sedimenta, pri čemu se u procesu stabilizacije/solidifikacije dobijaju proizvodi sa dodatom vrednošću neumanjenog kvaliteta .Nanomaterijali sintetisani u ovom radu na bazi ekstrakta lišća biljaka doprinose kako očuvanju životne sredine, tako i ekonomičnosti primene remedijacione tehnike. Zahvaljujući velikoj specifičnoj površini, malim dimenzijama čestica i velikom kapacitetu za imobilizaciju teških<br />metala predstavljaju efikasnu alternativu komercijalno dostupnim materijalima, što ih čini veoma atraktivnim i obećavajućim u budućnosti pri tretmanu rečnog sedimenta zagađenog teškim metalima.</p> / <p>The pollution of sediment by heavy metals represents a large environmental problem all<br />over the world. A lot of countries in the region as well as our country deal with this problem, which is widespread because of the fast urbanization and industrialization. There is more and more carelessness about wastewater discharge into water flows without previous purification. When the conditions of the aquatic ecosystem change, metal leaching and harmful effects on the environment and human health can occur. Therefore, remediation of metal-contaminated sediments is crucial activity in the process of the complete ecosystem remediation. Cost effective, efficient and environmentally friendly remediation techniques are urgently needed and readily applicable in large-scale treatment. Before applying remediation techniques on the largescale, both laboratory and pilot tests are necessary. There are pilot studies at the end of each successful laboratory test. Those studies provide the right answer in terms of choosing the optimal technology, taking into account the investment and operating costs, the achieved resultand the ultimate goals in terms of plant and waste management. In this study, the application<br />potential of stabilized and green - synthesized nano Fe(0) for the remediation of heavy metal -contaminated sediment was investigated. Stabilization / solidification technique was chosen as remediation technique which involves the addition of metal immobilizing agents in the sediment thus preventing the potential risk of metal leaching into the environment. Conventional materials such as fly ash, cement and clay have long been used for this purpose. Nowadays there is need for new, easily accessible agents for the sediment stabilization. Therefore it came up with the idea of using iron-based nanomaterials, ie. nano Fe(0) stabilized by native cla y and produced by reduction using organic molecules naturally present in oak and black mulberry leaf extract. Nanomaterials have been synthesized and characterized by different methods and techniques. In order to be effective in their application for sediment stabilization, extraction and dynamic laboratory leaching tests were performed. Mixtures of sediment and nanomaterials were selected that showed the best treatment efficiency. After that, the examination was continued on a pilot scale, where the behavior of nanomaterials was monitored, depending on conventional materials which have already been documented in the literature as effective immobilizing agents.Additional confirmation of treatment success was given by analysis and characterization of s / s mixtures after pilot testing. According to obtained results, the process was successfully demonstrated under laboratory conditions, and also during the pilot treatment. After the pilot treatment there were no increased concentrations of metal leaching from s/s mixtures, nor mixture degradation after the wetting process for six months. Based on that, the sediment treated in this way can be safely disposed of in landfills, or used for "controlled" use, construction of<br />roads, quarries, auxiliary facilities and etc. The results have contributed to the goal of a more permanent solution to the issue of disposal of polluted (slugged) river sediment, whereby in the process of stabilization/solidification, products with added value of undiminished quality are obtained. The nanomaterials synthesized in this paper on the basis of plant leaf extract contribute to both the preservation of the environment and the economy of remediation techniques. Thanks to their large specific surface area, small particle size and large ca pacity for immobilization of heavy metals, they represent an effective alternative to commercially available materials. It makes them very attractive and promising in the future in the treatment of river sediment contaminated with heavy metals.</p>
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Ispitivanje mogućnosti primene Fenton-procesa u tretmanu obojenih otpadnih voda grafičke industrije / Investigation of Fenton-process application in the treatment of dye wastewater in printing industryGvoić Vesna 27 September 2019 (has links)
<p>Predmet izučavanja ove disertacije je ispitivanje mogućnosti primene homogenog, heterogenog i Fentonsličnog procesa u tretmanu obojenih otpadnih voda grafičke industrije. Kao Fenton katalizatori korišćeni su sintetisani gvožđe(III)-molibdat i nano nula valentno gvožđe, kao i komercijalni gvožđe(II)-sulfat. Istraživanja su sprovedena u četiri faze. U prvoj fazi je izvršena sinteza i karakterizacija Fenton katalizatora, pri čemu su ustanovljene njihove osnovne morfološke karakteristike. Nano nula valentno gvožđe je sintetisano iz ekstrakta lišća hrasta, dok je gvožđe(III)-molibdat sintetisan putem tzv. vlažnog hemijskog postupka. U drugoj fazi je izvršena optimizacija Fenton procesa u tretmanu sintetičkih rastvora grafičkih boja primenom nove statističke metode, <em> definitive screening design</em>. U cilju postizanja maksimalnog stepena obezbojavanja i mineralizacije tretiranog uzorka ispitan je uticaj sledećih procesnih parametara: inicijalne koncentracije boje, koncentracije gvožđa, pH vrednosti i koncentracije vodonik-peroksida. Nakon ustanovljenih optimalnih uslova i izvršene verifikacije predloženog optimuma, sproveden je tretman realnog efluenta. Stepen mineralizacije tretiranog efluenta ustanovljen je na osnovu vrednosti sadržaja ukupnog organskog ugljenika i hemijske potrošnje kiseonika. U cilju razumevanja mehanizma degradacije grafičkih boja u Fenton procesu, kao i identifikacije prirode degradacionih produkata, izvršena je kvalitativna gasno-hromatografska/maseno spektrometrijska analiza. Kinetika obezbojavanja realnog efluenta najbolje je opisana primenom Behnajady - Modirshahla -Ghanbary modela, koji definiše inicijanu brzinu i oksidacioni kapacitet posmatranog procesa. Rezultati su ukazali na moguću primenu Fenton procesa u tretmanu CMYK boja usled postizanja visokih efikasnosti obezbojavanja i mineralizacije tretiranih efluenata. Nedostatak primenjene metode se ogleda u činjenici da je većina uzoraka okarakterisana kao visoko toksična, a ujedno i izrazito kisela, budući da je ustanovljena optimalna pH vrednost Fenton tretmana 2 - 3. Stoga je u okviru treće faze istraživanja primenjen dodatni tretman realnog efluenta, adsorpcija na aktivnom uglju sintetisanom iz koštica divlje šljive. Adsorpcioni tretman je rezultovao smanjenjem toksičnosti kod svih tretiranih uzoraka, koji se karakterišu kao nisko do umereno toksični, te je sa tog aspekta moguće njihovo bezbedno ispuštanje u recipijent. Ujedno je ustanovljena i povećana mineralizacija uzoraka, kao posledica degradacije jedinjenja koja su inicijalno doprinela povećanoj toksičnosti. U četvrtoj fazi rada primenjena je metoda ocenjivanja životnog ciklusa sinteze Fenton katalizatora. Rezultati LCA su utvrdili da sinteza heterogenog Fenton katalizatora, gvožđe(III)-molibdata, ostvaruje najveće opterećenje životne sredine, dok bi se proces sinteze nano nula valentnog gvožđa mogao unaprediti modifikovanjem ekstrakcione faze uz korišćenje alternativnih materijala i obnovljivih izvora energije. Značaj predstavljenih rezultata se ogleda u činjenici da su uzorci obojenih otpadnih voda grafičke industrije prvi put podvrgnuti Fenton tretmanu koji je rezultovao visokim stepenom efikasnosti.</p> / <p>The subject of this thesis is exploring the possibility of homogeneous, heterogeneous and Fenton-like process application in the treatment of dye wastewater in printing industry. Synthesized iron(III)-molybdate and nano zero valent iron, as well as commercial iron(II)-sulfate were used as a Fenton catalyst. The research was carried out in four phases. In the first phase, the catalyst synthesis and their characterization were performed, whereby the morphological characteristics were established. Nano zero valent iron was synthesized from oak leaf extract and iron(III)-molybdate was synthesized by wet chemical process. In the second phase, the optimization of Fenton process was performed within the treatment of synthetic printing dye solution using a new statistical method, a definitive screening design. In order to achieve maximum decolorization and mineralization of the treated sample, the influence of following process parameters was conducted: initial dye concentration, iron concentration, pH value and hydrogen peroxide concentration. The treatment of printing effluent was performed after establishing optimal conditions and verifying the proposed optimum values. Mineralization degree of treated effluent was determined based on the results of total organic carbon and chemical oxygen demand. In order to understand the dye degradation mechanism in Fenton process, as well as to identify degradation products, a qualitative gaschromatographic/mass spectrometric analysis was carried out. The kinetic studies of the printing effluent were best described by using the Behnajady- Modirshahla-Ghanbary model, which defines the initial speed and oxidation capacity of the process. The results indicated the possible application of the Fenton process in the treatment of CMYK dyes due to the high decolorization and mineralization efficiency of treated effluent. Disadvantage of the applied method is reflected in the fact that most of the samples are characterized as highly toxic and, at the same time, extremely acidic since the optimum pH value of Fenton treatment is 2 - 3. Therefore, in the third phase of the study, adsorption process on functionalized biochar prepared from wild plum kernels was applied on real printing effluent. Adsorption treatment resulted in toxicity reduction in all treated samples, characterized as low to moderately toxic. Therefore, from this aspect, treated effluent can be safely released into the recipient. At the same time, increased mineralization of the samples was established as a result of the compounds degradation that initially contributed to high toxicity. In the fourth phase, a life cycle assessment method of Fenton catalyst was applied. The results of the LCA indicated that the synthesis of the heterogeneous Fenton catalyst, iron(III) molybdate, achieved the highest environmental burden, while the synthesis of nano zero valent iron could be improved by modifying the extraction phase using alternative materials and renewable energy sources. The significance of the obtained results is high decolorization efficiency achieved by Fenton treatment of printing dye wastewater, which was used for the first time.</p>
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Synthesis of Catalytic Membrane Surface Composites for Remediating Azo Dyes in SolutionSutherland, Alexander January 2019 (has links)
In the past 30 years zero-valent iron (ZVI) has become an increasingly popular reducing agent technology for remediating environmental contaminants prone to chemical degradation. Azo dyes and chlorinated organic compounds (COCs) are two classes of such contaminants, both of which include toxic compounds with known carcinogenic potential. ZVI has been successfully applied to the surfaces of permeable reactive barriers, as well as grown into nanoscale particles (nZVI) and applied in-situ to chemically reduce these contaminants into more environmentally benign compounds. However, the reactivity of ZVI and nZVI in these technologies is limited by their finite supply of electrons for facilitating chemical reduction, and the tendency of nZVI particles to homo-aggregate in solution and form colloids with reduced surface area to volume ratio, and thus reduced reactivity. The goal of this project was to combine reactive nanoparticle and membrane technologies to create an electro-catalytic permeable reactive barrier that overcomes the weaknesses of nZVI for the enhanced electrochemical filtration of azo dyes in solution. Specifically, nZVI was successfully grown and stabilized in a network of functionalized carbon nanotubes (CNTs) and deposited into an electrically conductive thin film on the surface of a polymeric microfiltration support membrane. Under a cathodic applied voltage, this thin film facilitated the direct reduction of the methyl orange (MO) azo dye in solution, and regenerated nZVI reactivity for enhanced electro-catalytic operation. The electro-catalytic performance of these nZVI-CNT membrane surface composites to remove MO was validated, modelled, and optimized in a batch system, as well as tested in a dead-end continuous flow cell system. In the batch experiments, systems with nZVI and a -2 V applied potential demonstrated synergistic enhancement of MO removal, which indicated the regeneration of nZVI reactivity and allowed for the complete removal of 0.25 mM MO batches within 2-3 hours. Partial least squares regression (PLSR) modelling was used to determine the impact of each experimental parameter in the batch system and provided the means for an optimization leading to maximized MO removal. Finally, tests in a continuous system yielded rates of MO removal 1.6 times greater than those of the batch system in a single pass, and demonstrated ~87% molar removal of MO at fluxes of approximately 422 lmh. The work herein lays the foundation for a promising technology that, if further developed, could be applied to remediate azo dyes and COCs in textile industry effluents and groundwater sites respectively. / Thesis / Master of Applied Science (MASc)
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Synthesis of biomass-based graphene nanomaterials for aqueous heavy metal removal and cement-based composite property enhancementKarunaratne, Tharindu N. 12 May 2023 (has links) (PDF)
Utilizing biomass such as lignin, bamboo, soybean, corn stalk, rice husk, etc., as a carbon source to produce graphene-based nanomaterials has been reported recently. However, the potential of using such nanomaterials for engineering and environmental applications has not been realized. This dissertation investigates the use of graphene-based nanomaterials synthesized from using biomass as a carbon source for water remediation and cement-based composites’ (CBCs) property enhancement.
The first chapter introduces graphene and graphene-based nanomaterials, as well as the synthesis and application of graphene-based nanomaterials for removing heavy metals in an aqueous solution and for property enhancement in CBCs. The experimental investigation on the pyrolytic synthesis of graphene-encapsulated iron nanoparticles from biochar (BC) as the carbon source (BC-G@Fe0) was covered in the second chapter. Two synthetic routes for producing BC-G@Fe0, i.e., impregnation-carbonization (route-I) and pyrolysis-impregnation-carbonization (route-II) processes, were investigated experimentally using different characterization techniques and heavy metal removal methods. The third chapter reports the experimental performances of the heavy metal removal of Pb2+, Cu2+, and Ag+ from an aqueous solution using BC-G@Fe0. The effectivenesses of various adsorption benchmarks, such as pH, kinetics, and isotherms were assessed. Additionally, the removal efficiency of BC-G@Fe0 was evaluated. BC-G@Fe0 sample made from route II, in particular, FeCl2-impregnated-BC with 15% wt% iron loading carbonized at 1000 ℃ for 1h showed promising Pb2+, Cu2+, and Ag+ removal capacities of 0.30, 1.58, and 1.91 mmol/g, respectively. The fourth chapter experimentally investigated the reinforcement effect of commercially sourced, industrial graphene nanoplates (IG) on the mechanical properties of CBCs. This investigation was based on a hypothesis that the uniform dispersion of IG would significantly enhance the compressive strength of CBC. The main outcome of this research was that, while the wet dispersion mixing process of IG into CBC did not consistently yield significant increases in the composite compressive strength, but the newly proposed dry dispersion process demonstrated significant increases (22%) in the composite compressive strength. Chapter Five investigated the synthesis of lignin-based graphene nanoplatelets (LG) and their application in CBC reinforcement. The main findings were that LG did not show impressive increases compared to IG, even when dry dispersion was introduced. This was attributed to LG's lack of effective surface area compared to IG. Finally, a general conclusion and outlook for the future of research into biomass-based graphene nanomaterials were discussed in chapter six.
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POST-EMPLACEMENT LEACHING BEHAVIORS OF NANO ZERO VALENT IRON MODIFIED WITH CARBOXYMETHYLCELLULOSE UNDER SIMULATED AQUIFER CONDITIONSWilliams, Leslie Lavinia January 2013 (has links)
No description available.
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