EVALUATING A MEAT AND BONE MEAL BIOCHAR AMENDMENT FOR IMMOBILIZATION OF ZINC IN A SMELTER IMPACTED SOIL

2013 April 1900

Non-ferrous smelter emissions have prompted revegetation efforts near the border towns of Flin Flon, Manitoba and Creighton, Saskatchewan to facilitate regrowth of the surrounding boreal forest. Previously, several soil amendments were tested for plant response in soils from the smelter-impacted area and one amendment, a pyrolyzed meat and bone meal (MBM) biochar, was of particular interest because of its potential to immobilize Zn. Hydroxyapatite (HAP), with a small degree of carbonate substitution, was identified as the major component of the MBM biochar. The solubility of this Ca-mineral was pH dependent, with dissolution occurring at pH 6.3; consequently, adsorption experiments were performed at a slightly lower pH (6.1 ± 0.1). Zinc adsorption kinetics were bi-phasic and could be modeled using the Elovich equation, suggesting a diffusion limited reaction likely related to material aggregation. Adsorption also was modeled using the Langmuir equation, which indicated a moderate affinity of the biochar for Zn and an adsorption maximum of 0.650 mmol Zn g-1. Synchrotron-based Zn K-edge x-ray absorption spectroscopy (XAS) indicated an inner-sphere monodentate, tetrahedral bonding of Zn to phosphate groups in the MBM biochar. This was consistent with Zn adsorbed to a HAP standard, indicating that the same sorption mechanism was involved. The ability of MBM biochar to affect Zn speciation in soils was investigated using four soils from four locations in the smelter-impacted region around Flin Flon. A 1:10 (w/w) mixture of the MBM and soil was suspended in 200-mL deionized water (pH 6.1 ± 0.1) and equilibrated for 30 d. Whereas all the soils showed a decrease in extractable Zn following equilibration, only one exhibited a change in Zn speciation—with ca. 25% of the Zn adsorbed onto the MBM biochar. Ore-derived minerals were present in all soils and strong backscattering made identification of minor Zn species difficult. However, using microprobe-based x-ray absorption near edge structure (XANES) spectroscopy, several minor Zn species were identified; including hopeite, a ZnPO4 mineral. The presence of both hopeite and adsorbed Zn are indicative of a direct Zn-phosphate reaction. These results indicate that, under certain condition, MBM biochar can be an effective soil amendment.

A structural study of M-DNA

Hoffort, Angela

24 July 2006

In alkaline conditions, a complex called M-DNA is formed between a divalent metal ion, cobalt, nickel or zinc, and duplex DNA. The rate of formation and stability of M-DNA is dependent on many factors, including but not limited to temperature, pH, DNA sequence, and metal or DNA concentrations. It has been hypothesized that the divalent metal ions intercalate into the helix and replace the imino protons involved in the hydrogen bonding of both G-C and A-T base pairs. The complex is thought to have a double helical structure that is similar to B-DNA. The presence of the divalent metal ions and a more compact structure may contribute to M-DNAs remarkable ability to behave as a molecular wire. Because M-DNA is so similar to B-DNA, it adheres to the same rules with regards to self-assembly. The ability of DNA to self-assemble and the electronic conduction of M-DNA are ideal properties for nanotechnology of the future. M-DNA may eventually be used to detect the presence of biologically important small molecules and DNA binding proteins that block the flow of electrons. However, before M-DNA will be widely accepted, it is necessary to obtain an accurate 3-dimensional structure by X-ray crystallography and modelling. <p> In this work interactions between divalent cobalt, nickel or zinc with duplex DNA were studied using two different experimental methods; namely, X-ray crystallography and extended X-ray absorption fine structure spectroscopy. First, crystals of the sequence d[GA(5FU)(5FU)AA(5FU)C] and d[CG(5FU)G(5FU)GCACACG] complexed with divalent metals were grown in M-DNA favouring conditions. Both of the sequences gave crystals that provided diffraction data that were analyzed by molecular replacement using B-DNA models. Unfortunately, the quality of the diffraction was not high enough with either sequence to locate metal binding or to determine a model for M-DNA. Second, X-ray absorption spectroscopy data were analyzed for the Ni2+ K-edge of both Ni2+ M and B-DNA. Several differences between the M and the B-DNA data were noticed and some final bond distances were established.

nucleic acid structure

EXAFS

DNA metal interactions

crystallography

M-DNA

Integrating Methods for Characterizing the Passive Treatment of Mercury and Selenium in Groundwater and Sediment

Gibson, Blair Donald

January 2011

Standard geochemical analysis methods, such as aqueous geochemistry analysis and mineralogical analysis, frequently are utilized to evaluate the effectiveness of passive treatment systems, though they do not necessarily provide information regarding the mechanism of removal. Two emerging analytical techniques have shown promise by providing additional information to improve characterization of treatment systems: X-ray absorption spectroscopy (XAS) and stable isotope analysis. In this thesis, these novel analytical techniques were integrated with standard geochemical measurements to better characterize contaminated sites as well as potential treatment technologies used to mitigate aqueous contaminant mobility. Laboratory experiments were used to evaluate the removal of Se(VI) form simulated groundwater using granular Fe0 (GI) and organic carbon (OC). Greater than 90 % removal of Se(VI) was observed for systems containing GI after 5 days of reaction time and only 15 % removal was observed in systems containing OC. Synchrotron radiation-based XAS analysis of the treatment materials indicated the presence of both Se(IV) and Se(0) on the edges of GI grains after 6 hours reaction time, with no evidence of oxidized Se after 5 days of reaction. Several analytical techniques were integrated to characterize sediment contaminated with Hg and other contaminants through previous industrial practices. Analysis of the sediment by XAS indicated the possible presence of mercury selenide and copper sulfide. Resuspension tests were performed in oxic and anoxic conditions to simulate the effects of changing geochemical conditions of Hg release from sediments during dredging operations. The results indicated a higher release of Hg under oxic conditions in some sediment locations, suggesting that oxidative degradation of organic carbon or oxidative dissolution of Hg sulfides contributed to Hg release. The treatment of aqueous Hg(II) was evaluated with a variety of treatment media, including clay and GI. Treatment with GI was rapid, with 90 % removal observed after 2 hours reaction time. Extended X-ray absorption fine structure (EXAFS) analysis indicated the presence of Hg-O bonding on GI, suggesting that Hg was bound to Fe oxides formed on the surface of corroded GI. A new conceptual model for tracking the stable isotope fractionation of sulfur was coupled to the reactive transport model MIN3P to determine the effects of secondary transformations on sulfur cycling in passive treatment systems. Minor differences were noted when comparing the transport model-derived fractionation factor to calculations using a simplified Rayleigh distillation model, possibly indicating the effect of SO4 precipitation. The incorporation of stable isotope modeling provides a framework for the modeling of other isotope systems in treatment technologies.

selenium

mercury

anoxic treatment

XANES/EXAFS

isotope modeling

Earth Sciences

A structural study of M-DNA

Hoffort, Angela

24 July 2006

In alkaline conditions, a complex called M-DNA is formed between a divalent metal ion, cobalt, nickel or zinc, and duplex DNA. The rate of formation and stability of M-DNA is dependent on many factors, including but not limited to temperature, pH, DNA sequence, and metal or DNA concentrations. It has been hypothesized that the divalent metal ions intercalate into the helix and replace the imino protons involved in the hydrogen bonding of both G-C and A-T base pairs. The complex is thought to have a double helical structure that is similar to B-DNA. The presence of the divalent metal ions and a more compact structure may contribute to M-DNAs remarkable ability to behave as a molecular wire. Because M-DNA is so similar to B-DNA, it adheres to the same rules with regards to self-assembly. The ability of DNA to self-assemble and the electronic conduction of M-DNA are ideal properties for nanotechnology of the future. M-DNA may eventually be used to detect the presence of biologically important small molecules and DNA binding proteins that block the flow of electrons. However, before M-DNA will be widely accepted, it is necessary to obtain an accurate 3-dimensional structure by X-ray crystallography and modelling. <p> In this work interactions between divalent cobalt, nickel or zinc with duplex DNA were studied using two different experimental methods; namely, X-ray crystallography and extended X-ray absorption fine structure spectroscopy. First, crystals of the sequence d[GA(5FU)(5FU)AA(5FU)C] and d[CG(5FU)G(5FU)GCACACG] complexed with divalent metals were grown in M-DNA favouring conditions. Both of the sequences gave crystals that provided diffraction data that were analyzed by molecular replacement using B-DNA models. Unfortunately, the quality of the diffraction was not high enough with either sequence to locate metal binding or to determine a model for M-DNA. Second, X-ray absorption spectroscopy data were analyzed for the Ni2+ K-edge of both Ni2+ M and B-DNA. Several differences between the M and the B-DNA data were noticed and some final bond distances were established.

nucleic acid structure

EXAFS

DNA metal interactions

crystallography

M-DNA

Catalyseurs à base de molybdène supporté sur alumine [gamma] et zéolithe HY caractérisation des phases oxydes et sulfures /

Plazenet, Guillaume. Payen, Edmond.

January 2001

Thèse de doctorat : Spectrochimie, molécules, solides, réactivités : Lille 1 : 2001. / N° d'ordre (Lille) : 3006. Résumé en français et en anglais. Bibliogr. en fin chapitres.

Détection et caractérisation par rayons X des éléments traces dans les fruits et légumes

Camarillo Ravelo, Danté Babot, Daniel.

January 2008

Thèse doctorat : Images et Systèmes : Villeurbanne, INSA : 2007. / Titre provenant de l'écran-titre. Bibliogr. p. 167-175.

Étude structurale par diffraction, absorption des rayons X et simulations Monte-Carlo de matériaux zéolithiques

Borissenko, Elena Souhassou, Mohamed. Porcher, Florence.

January 2008

Thèse de doctorat : Sciences des Matériaux : Nancy 1 : 2008. / Titre provenant de l'écran-titre.

Integrating Methods for Characterizing the Passive Treatment of Mercury and Selenium in Groundwater and Sediment

Gibson, Blair Donald

January 2011

Standard geochemical analysis methods, such as aqueous geochemistry analysis and mineralogical analysis, frequently are utilized to evaluate the effectiveness of passive treatment systems, though they do not necessarily provide information regarding the mechanism of removal. Two emerging analytical techniques have shown promise by providing additional information to improve characterization of treatment systems: X-ray absorption spectroscopy (XAS) and stable isotope analysis. In this thesis, these novel analytical techniques were integrated with standard geochemical measurements to better characterize contaminated sites as well as potential treatment technologies used to mitigate aqueous contaminant mobility. Laboratory experiments were used to evaluate the removal of Se(VI) form simulated groundwater using granular Fe0 (GI) and organic carbon (OC). Greater than 90 % removal of Se(VI) was observed for systems containing GI after 5 days of reaction time and only 15 % removal was observed in systems containing OC. Synchrotron radiation-based XAS analysis of the treatment materials indicated the presence of both Se(IV) and Se(0) on the edges of GI grains after 6 hours reaction time, with no evidence of oxidized Se after 5 days of reaction. Several analytical techniques were integrated to characterize sediment contaminated with Hg and other contaminants through previous industrial practices. Analysis of the sediment by XAS indicated the possible presence of mercury selenide and copper sulfide. Resuspension tests were performed in oxic and anoxic conditions to simulate the effects of changing geochemical conditions of Hg release from sediments during dredging operations. The results indicated a higher release of Hg under oxic conditions in some sediment locations, suggesting that oxidative degradation of organic carbon or oxidative dissolution of Hg sulfides contributed to Hg release. The treatment of aqueous Hg(II) was evaluated with a variety of treatment media, including clay and GI. Treatment with GI was rapid, with 90 % removal observed after 2 hours reaction time. Extended X-ray absorption fine structure (EXAFS) analysis indicated the presence of Hg-O bonding on GI, suggesting that Hg was bound to Fe oxides formed on the surface of corroded GI. A new conceptual model for tracking the stable isotope fractionation of sulfur was coupled to the reactive transport model MIN3P to determine the effects of secondary transformations on sulfur cycling in passive treatment systems. Minor differences were noted when comparing the transport model-derived fractionation factor to calculations using a simplified Rayleigh distillation model, possibly indicating the effect of SO4 precipitation. The incorporation of stable isotope modeling provides a framework for the modeling of other isotope systems in treatment technologies.

selenium

mercury

anoxic treatment

XANES/EXAFS

isotope modeling

Earth Sciences

Röntgenabsorptionsspektroskopische Untersuchungen an katalytisch aktiven Metallkomplexen und nanostrukturierten anorganisch-organischen Hybridmaterialien

Feth, Martin Philipp,

January 2003

Stuttgart, Univ., Diss., 2003.

In-situ-Charakterisierung der thermischen Behandlung von Polymolybdaten mit EXAFS und XRD

Wienold, Julia.

Unknown Date

Techn. Universiẗat, Diss., 2003--Berlin.