Removal of barium, cobalt, strontium and zinc from solution by natural and synthetic allophane adsorbents

Baldermann, Andre; Grießbacher, Andrea Cäcilia; Baldermann, Claudia; Purgstaller, Bettina; Letofsky-Papst, Ilse; Kaufhold, Stephan; Dietzel, Martin

doi:10.20944/preprints201806.0478.v1

Cited by 10 publications

(8 citation statements)

References 33 publications

(79 reference statements)

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“…This suggests that the metal ion (Mg) uptake by secondary clay minerals and the related isotope fractionation mechanism are highly dependent on the starting fluid composition (including the pH, concentration of elements required for mineral formation, and the presence or absence of seed crystals and precipitation inhibitors). Furthermore, fractionation also depends on the physicochemical and surface characteristics of the alteration mineral (such as crystal structure and bond lengths, specific surface area, surface charge, etc., Li et al, 2014;Baldermann et al, 2018). Such factors can be further complicated by aqueous solution speciation, as Mg isotope fractionation can occur between individual species (e.g., Schott et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Magnesium isotope fractionation during hydrothermal seawater-basalt interaction

Voigt

Pearce

Fries

et al. 2020

Geochimica et Cosmochimica Acta

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Fluid-rock interactions in hydrothermal systems at or near mid-oceanic ridges (MOR) play a major role in determining the composition of the oceanic crust and seawater. To quantify the processes that govern cation exchange in these environments we have experimentally studied the isotopic evolution of δ 26/24 Mg in the fluid phase during seawater-basalt interaction at 250 and 290 °C. Mass balance constraints indicate that isotopically heavy Mg was preferentially incorporated into non-exchangeable (octahedral) sites in secondary clay minerals such as saponite (Mg-rich smectite), leaving residual fluids enriched in light Mg isotopes. The magnitude of fractionation observed during smectite precipitation in our experiments ( ) ranged from to . This observation, which contrasts with the preferential uptake of light Mg isotopes into biogenic and inorganic marine carbonates, *Manuscript highlights the potential utility of Mg isotopes as tracers of the precipitation dynamics of authigenic Mg-silicate and Mg-carbonate phases. Furthermore, although Mg isotopic fractionation is often masked by the almost complete removal of Mg in high temperature marine hydrothermal systems, our experiments demonstrate that it does become significant at lower temperatures where Mg removal by clay formation is incomplete. Under such conditions, this fractionation will create isotopically light fluids due to smectite precipitation, thus potentially represents an important component of the marine Mg isotope inventory.

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Section: Introductionmentioning

confidence: 99%

Magnesium isotope fractionation during hydrothermal seawater-basalt interaction

Voigt

Pearce

Fries

et al. 2020

Geochimica et Cosmochimica Acta

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“…It can be inferred from Figure 5 that the sorption capacity of the mineral-organic sorbent sharply increased with the increase of Zn(II) concentration in solution ( Figure 5 ), from 1.2 to 4.4 mg/L in the Zn-system, from 1.2 to 2.9 in the Zn/Cu/Sr system, from 0.9 to 2.9 in the Zn/Ni/Cu system, and from 0.8 to 2.6 mg/g in the Zn/Cu/Sr/Ba system. At low metal ion concentrations, a large number of available binding sites facilitate metal ion sorption, while at high metal concentrations, the number of binding sites on sorbent surfaces is limited and a sorption maximum has been attained [ 24 ].…”

Section: Resultsmentioning

confidence: 99%

Zinc-Containing Effluent Treatment Using Shewanella xiamenensis Biofilm Formed on Zeolite

et al. 2021

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The sorption properties of Shewanella xiamenensis biоfilm formed on zeolite (mineral-organic sorbent) as a sorbent have been investigated aiming to determine its suitability for complex zinc-containing effluent treatment. The optimum conditions for metal sorption from synthetic solutions were evaluated by changing the pH, zinc concentration, temperature, and time of sorption. The highest removal of metal ions was attained at pH range 3.0–6.0 within 60–150 min of sorbent-sorbate contact. The results obtained from the equilibrium studies were described using the Langmuir, Freundlich, and Temkin models. Maximum sorption capacity of the sorbent calculated from the Langmuir model changed from 3.4 to 6.5 mg/g. High coefficient of determination values calculated for pseudo-second-order and Elovich models indicate the predominant role of chemisorption in metal removal. Gibbs energy and ∆H° values point at the spontaneous and endothermic character of the sorption. The effect of pH and biosorbent mass on Zn(II) sorption from industrial effluent with an initial Zn(II) concentration of 52.8 mg/L was tested. Maximum removal of zinc ions (85%) was achieved at pH 6.0 by applying a two-step treatment system.

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“…The total concentrations of aqueous Na, Al, Ca, Co, Cr, Si and Zn were analysed in acidified aliquots (2% HNO 3 ) by inductively coupled plasma optical emission spectroscopy (ICP-OES) using a PerkinElmer Optima 8300 DV. The analytical precision (2r, 3 replicates) is better than ± 2% for Co and Si analyses and ± 4% for Al, Ca, Cr and Zn analyses, respectively, relative to replicate measurements of NIST 1640a, in-house and SPS-SW2 Batch 130 standards [31].…”

Section: Fluid-phase Characterizationmentioning

confidence: 89%

“…C-A-S-H phases share many structural similarities with phyllosilicates. Smectite group minerals, for instance, have a 2:1 layer structure comprising negatively charged octahedral and tetrahedral sheets that are connected to an interlayer site, where hydrated and partly exchangeable cations are intercalated [30][31][32]. The unique structure, besides a small particle size (\ 100 nm), a large specific surface area ([ 10 m 2 /g), and presence of surface functional groups (i.e.…”

Section: Introductionmentioning

confidence: 99%

Removal of heavy metals (Co, Cr, and Zn) during calcium–aluminium–silicate–hydrate and trioctahedral smectite formation

et al. 2019

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Hydrated aluminosilicates were synthesized with and without aqueous heavy metals (Me), such as cobalt (Co), chromium (Cr), and zinc (Zn), by a sol-gel process at different initial molar ratios of Ca/(Si ? Al) (0.6-1.6) and Me/Si (0.0-2.0), and constant Al/Si ratio (0.05) using equilibrium-approaching experiments. The chemical composition of the reactive solutions during aluminosilicate precipitation and maturation was monitored by ICP-OES. The mineralogy, nanostructure, and chemical composition of the precipitates were studied by XRD and high-resolution TEM. At Me/Si ratios B 0.2, calcium-aluminium-silicate-hydrates (C-A-S-H) with a defect 14 Å tobermorite-like structure formed, whereas at a Me/Si ratio of 2.0, either trioctahedral Co-and Zn-smectite or amorphous Cr gels precipitated, independent of the initial Ca/(Si ? Al) ratio used for gel synthesis. The immobilization capacities for Co 2þ , Cr 3þ , and Zn 2þ by C-A-S-H, Cr gel, and trioctahedral smectite are 3-40 mg/g, 30-152 mg/g, and 122-141 mg/g, respectively. The immobilization mechanism of heavy metals is based on a combination of isomorphous substitution, interlayer cation exchange, surface (ad)sorption, and surface precipitation. In engineered systems, such as underground concrete structures and nuclear waste disposal sites, hydrated aluminosilicates should exhibit a high detoxication potential for aqueous heavy metals.

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Removal of barium, cobalt, strontium and zinc from solution by natural and synthetic allophane adsorbents

Cited by 10 publications

References 33 publications

Magnesium isotope fractionation during hydrothermal seawater-basalt interaction

Magnesium isotope fractionation during hydrothermal seawater-basalt interaction

Zinc-Containing Effluent Treatment Using Shewanella xiamenensis Biofilm Formed on Zeolite

Removal of heavy metals (Co, Cr, and Zn) during calcium–aluminium–silicate–hydrate and trioctahedral smectite formation

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