Global ETD Search

21	Physico-Chemical Processes for Oil Sands Process-Affected Water Treatment Pourrezaei,Parastoo Unknown Date No description available. Oil Sands Process Affected Water Coagulation/Flocculation Petroleum Coke Zero Valent Iron
22	Characterizing Chromium Isotope Fractionation During Reduction of Cr(VI): Batch and Column Experiments Jamieson-Hanes, Julia Helen January 2012 (has links) Chromium (VI) is a pervasive groundwater contaminant that poses a considerable threat to human health. Remediation techniques have focused on the reduction of the highly mobile Cr(VI) to the sparingly soluble, and less toxic, Cr(III) species. Traditionally, remediation performance has been evaluated through the measurement of Cr(VI) concentrations; however, this method is both costly and time-consuming, and provides little information regarding the mechanism of Cr(VI) removal. More recently, Cr isotope analysis has been proposed as a tool for tracking Cr(VI) migration in groundwater. Redox processes have been shown to produce significant Cr isotope fractionation, where enrichment in the ⁵³Cr/⁵²Cr ratio in the remaining Cr(VI) pool is indicative of a mass-transfer process. This thesis describes laboratory batch and column experiments that evaluate the Cr isotope fractionation associated with the reduction of Cr(VI) by various materials and under various conditions. Laboratory batch experiments were conducted to characterize the isotope fractionation during Cr(VI) reduction by granular zero-valent iron (ZVI) and organic carbon (OC). A decrease in Cr(VI) concentrations was accompanied by an increase in δ⁵³Cr values for the ZVI experiments. Data were fitted to a Rayleigh-type curve, which produced a fractionation factor α = 0.9994, suggesting a sorption-dominated removal mechanism. Scanning electron microscopy (SEM), X-ray absorption near-edge structure (XANES) spectroscopy, and X-ray photoelectron spectroscopy (XPS) indicated the presence of Cr(III) on the solid material, suggesting that reduction of Cr(VI) occurred. A series of batch experiments determined that reaction rate, experimental design, and pre-treatment of the ZVI had little to no effect on the Cr isotope fractionation. The interpretation of isotope results for the organic carbon experiments was complicated by the presence of both Cr(VI) and Cr(III) co-existing in solution, suggesting that further testing is required. A laboratory column experiment was conducted to evaluate isotopic fractionation of Cr during Cr(VI) reduction by OC under saturated flow conditions. Although decreasing dissolved Cr(VI) concentrations also were accompanied by an increase in δ⁵³Cr values, the isotope ratio values did not fit a Rayleigh-type fractionation curve. Instead, the data followed a linear regression equation yielding α = 0.9979. Solid-phase analysis indicated the presence of Cr(III) on the surface of the OC. Both the results of the solid-phase Cr and isotope analyses suggest a combination of Cr(VI) reduction mechanisms, including reduction in solution, and sorption prior to reduction. The linear characteristic of the δ⁵³Cr data may reflect the contribution of transport on Cr isotope fractionation. chromium isotope reduction double-spike synchrotron column batch zero-valent iron organic carbon Earth Sciences
23	Trade-offs in Utilizing of Zero-Valent Iron for Synergistic Biotic and Abiotic Reduction of Trichloroethene and Perchlorate in Soil and Groundwater January 2017 (has links) abstract: The advantages and challenges of combining zero-valent iron (ZVI) and microbial reduction of trichloroethene (TCE) and perchlorate (ClO4-) in contaminated soil and groundwater are not well understood. The objective of this work was to identify the benefits and limitations of simultaneous application of ZVI and bioaugmentation for detoxification of TCE and ClO4- using conditions relevant to a specific contaminated site. We studied conditions representing a ZVI-injection zone and a downstream zone influenced Fe (II) produced, for simultaneous ZVI and microbial reductive dechlorination applications using bench scale semi-batch microcosm experiments. 16.5 g L-1 ZVI effectively reduced TCE to ethene and ethane but ClO4- was barely reduced. Microbial reductive dechlorination was limited by both ZVI as well as Fe (II) derived from oxidation of ZVI. In the case of TCE, rapid abiotic TCE reduction made the TCE unavailable for the dechlorinating bacteria. In the case of perchlorate, ZVI inhibited the indigenous perchlorate-reducing bacteria present in the soil and groundwater. Further, H2 generated by ZVI reactions stimulated competing microbial processes like sulfate reduction and methanogenesis. In the microcosms representing the ZVI downstream zone (Fe (II) only), we detected accumulation of cis-dichloroethene (cis-DCE) and vinyl chloride (VC) after 56 days. Some ethene also formed under these conditions. In the absence of ZVI or Fe (II), we detected complete TCE dechlorination to ethene and faster rates of ClO4- reduction. The results illustrate potential limitations of combining ZVI with microbial reduction of chlorinated compounds and show the potential that each technology has when applied separately. / Dissertation/Thesis / Masters Thesis Civil, Environmental and Sustainable Engineering 2017 Environmental engineering Biogeochemistry Nanotechnology Bioremediation Groundwater Perchlorate Soil Trichloroethylene Zero Valent Iron
24	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 metals Slijepčević Nataša 02 October 2020 (has links) <p>Ekolo&scaron;ki  problem  svetskih  razmera  predstavlja  zagađenost  sedimenta  te&scaron;kim  metalima, usled negativnih ekolo&scaron;kih efekata metala na životnu sredinu. Mnoge zemlje i regioni, kao i na&scaron;a zemlja  suočavaju  se  sa  ovom  problematikom,  koja  je  vrlo  rasprostranjena  usled  sve  brže urbanizacije  i  industrijalizacije,  a  sa  sve  većom  nebrigom  usled  ispu&scaron;tanja  otpadnih  voda  bez prethodnog  preči&scaron;ćavanja  u  vodotokove.  Prilikom  promene  uslova  vodenog  ekosistema,  može doći do  izluživanja  metala  i &scaron;tetnih 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 ekolo&scaron;ki 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 uspe&scaron;nog  laboratorijskog  ispitivanja  nalaze  se  pilot  istraživanja.  Pomoću  njih  se  dobija  p ravi odgovor u smislu izbora optimalne tehnologije imajući u vidu investicione i operativne tro&scaron;kove,<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  te&scaron;kim  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 dana&scaron;nje vreme raste potražnja za novim, lako dostupnim agensima za stabilizaciju<br />sedimenta, do&scaron;lo 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  li&scaron;ća  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 sme&scaron;e sedimenta i nanomaterijala koje su pokazale najbolju efikasnost tr etmana. Nakon toga se ispitivanje  nastavilo  na  pilot  skali,  gde  se  pratilo  pona&scaron;anje  nanomaterijala  u  zavisnosti  od konvencionalnih  materijala  koji  su  već  u  literaturi  dokumentovani  kao  efikasni  imobilizacioni agensi. Dodatna potvrda uspe&scaron;nosti tretmana data je analizom i karakterizacijom s/s sme&scaron;a nakon pilot  ispitivanja  Na  osnovu  dobijenih  rezultata  proces  se  uspe&scaron;no  pokazao  pri  laboratorijskim uslovima,  a  takođe  i  prilikom  pilot  tretmana,  odnosno  nakon  pilot  tretmana  nije  do&scaron;lo  do povećanih koncentracija  izluživanja metala iz s/s sme&scaron;a, kao ni degradacije sme&scaron;a nakon procesa ovlaživanja  tokom  &scaron;est  meseci.  Na  osnovu  toga,  ovako  tertirani  sediment  se  može  bezbedno odlagati  na  deponije,  ili  pak  iskoristiti  za  &bdquo;kontrolisanu“  upotrebu,  izgradnju  puteva,kamenoloma, pomoćnih objekata i slično. Rezultati su doprineli u cilju trajnijeg re&scaron;avanja pitanja odlaganja  zagađenog  (izmuljenog)  rečnog  sedimenta,  pri  čemu  se  u  procesu stabilizacije/solidifikacije  dobijaju  proizvodi  sa  dodatom  vredno&scaron;ću  neumanjenog  kvaliteta .Nanomaterijali sintetisani u ovom radu na  bazi ekstrakta li&scaron;ća biljaka doprinose kako očuvanju životne  sredine,  tako  i  ekonomičnosti  primene  remedijacione  tehnike.  Zahvaljujući  velikoj specifičnoj  povr&scaron;ini,  malim  dimenzijama  čestica  i  velikom  kapacitetu  za  imobilizaciju  te&scaron;kih<br />metala predstavljaju efikasnu alternativu komercijalno dostupnim materijalima, &scaron;to ih čini veoma atraktivnim  i  obećavajućim  u  budućnosti  pri  tretmanu  rečnog  sedimenta  zagađenog  te&scaron;kim 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>
25	Rational Design and Characterization of Adsorbents for Environmental Remediation of FGD Wastewater Malibekova, Alma January 2022 (has links) No description available. Chemical Engineering FGD wastewater adsorbent functional groups zero valent iron bimetallic nanoparticles
26	Treatment of Microcontaminants in Drinking Water Srinivasan, Rangesh 14 August 2009 (has links) No description available. Environmental Engineering Environmental Science perchlorate chlorate zero valent iron MIB geosmin activated carbon fiber adsorption
27	Reduction of Perchlorate from Contaminated Waters Using Zero Valent Iron and Palladium under UV Light Zhao, Qiuming 20 April 2011 (has links) No description available. Environmental Engineering endocrine disruptor ground water remediation zero valent iron oxidizer perchlorate UV light
28	Optimalizace a aplikace testů pro stanovení ekotoxicity nanomateriálů / Optimization and application of assays for determination ecotoxicity of nanomaterials Semerád, Jaroslav January 2015 (has links) This thesis deals with optimization and application of assays for determination of ecotoxicity of nanomaterials based on nanoscale zero-valent iron (nZVI), which are used in remedial technologies. After in situ application of nZVI, a significant decrease in toxicity of polluted environment was detected; however, a potential negative effect of nanoparticles has not been sufficiently investigated yet. Standard used tests were found to be incompatible with nZVI for toxicity determination. Specific characteristics of nZVI, such as high reactivity and sorption, complicate determining the toxicity by routinely used ecotoxicity tests. Concentration ranging from 0,1 to 10 g/l that are used in practise for decontamination were tested. These concentrations resulted in formation of turbidity, which prevented the use of standard tests. In this work, a new method has been optimized for in vitro toxicity testing of nZVI and derived nanomaterials using bacteria. The principle of this assay is determination of oxidative stress (OS). The disbalance between formation and degradation of reactive oxygen species (i.e. OS) leads to irreversible changes in biomolecules of organisms and formation of undesirable products. A toxic and mutagenic product - malondialdehyde (MDA) is formed during lipid peroxidation and it is a...
29	Laboratory Investigation Of The Treatment Of Chromium Contaminated Groundwater With Iron-based Permeable Reactive Barriers Uyusur, Burcu 01 August 2006 (has links) (PDF) Chromium is a common groundwater pollutant originating from industrial processes such as metal plating, leather tanning and pigment manufacturing. Permeable reactive barriers (PRBs) have proven to be viable and cost-effective systems for remediation of chromium contaminated groundwater at many sites. The purpose of this research presented in this thesis is to focus on two parameters that affect the performance of PRB on chromium removal, namely the concentration of reactive media and groundwater flux by analyzing the data obtained from laboratory column studies. Laboratory scale columns packed with different amounts of iron powder and quartz sand mixtures were fed with 20 mg/l chromium influent solution under different fluxes. When chromium treatment efficiencies of the columns were compared with respect to iron powder/quartz sand ratio, the amount of iron powder was found to be an important parameter for treatment efficiency of PRBs. The formation of H2 gas and the reddish-brown precipitates throughout the column matrix were observed, suggesting the reductive precipitation reactions. SEM-EDX analysis of the iron surface after the breakthrough illustrated chromium precipitation. In addition to chromium / calcium and significant amount of iron-oxides or -hydroxides was also detected on the iron surfaces. When the same experiments were conducted at higher fluxes, an increase was observed in the treatment efficiency in the column containing 50% iron. This suggested that the precipitates may not be accumulating at higher fluxes which, in turn, create available surface area for reduction. Extraction experiments were also performed to determine the fraction of chromium that adsorbed to ironhydroxides. The analysis showed that chromium was not removed by adsorption to oxyhydroxides and that reduction is the only removal mechanism in the laboratory experiments. The observed rate of Cr(VI) removal was calculated for each reactive mixture which ranged from 48.86 hour-1 to 3804.13 hour-1. These rate constants and complete removal efficiency values were thought to be important design parameters in the field scale permeable reactive barrier applications.
30	Evidence for Volatile Organic Compound Mass Reduction Adjacent to Hydraulically Induced, ZVI-Filled Fractures in Clay Ramdial, Brent 18 May 2012 (has links) Volatile organic compound (VOC) contamination of low permeability geologic deposits due to Dense Non-Aqueous Phase Liquid (DNAPL) penetration through fractures is exceptionally difficult to remediate using in-situ methods as the low permeability of the sediments limits the delivery of reagents proximal to contaminant mass. This thesis examines in detail the extent of organic contaminant treatment away from hydraulically-induced fractures injected with particulate Zero Valent Iron as (1) ZVI and glycol (G-ZVI) and (2) an emulsified ZVI (EZVI) mixture within a contaminated glaciolacustrine clayey deposit. Continuous vertical cores were collected through the treatment zone at 2 and 2.5 years after substrate injections and soil sub-sample spacing was scaled to show the extent of the treatment zone adjacent to the ZVI in the fractures, expecting the treatment would be controlled by diffusion limited transport to the reaction zone. Analytical results show evidence of treatment in both the EZVI and the G-ZVI containing fractures with the presence of degradation by-products and reduced VOC concentrations in the fracture and surrounding clay matrix. / Natural Sciences and Engineering Research Council of Canada, University Consortium for Field-Focused Groundwater Contamination Research in situ remediation technology low permeability geologic deposits hydraulic fracturing EZVI DNAPL

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