18 research outputs found
Weak Magnetic Field Accelerates Chromate Removal by Zero-Valent Iron
Weak magnetic field (WMF) was employed to improve the removal of Cr(VI) by zero-valent iron (ZVI) for the first time. The removal rate of Cr(VI) was elevated by a factor of 1.12-5.89 due to the application of a WMF, and the WMF-induced improvement was more remarkable at higher Cr(VI) concentration and higher pH. Fe2+ was not detected until Cr(VI) was exhausted, and there was a positive correlation between the WMF-induced promotion factor of Cr(VI) removal rate and that of Fe2+ release rate in the absence of Cr(VI) at pH 4.0-5.5. These phenomena imply that ZVI corrosion with Fe2+ release was the limiting step in the process of Cr(VI) removal. The superimposed WMF had negligible influence on the apparent activation energy of Cr(VI) removal by ZVI, indicating that WMF accelerated Cr(VI) removal by ZVI but did not change the mechanism. The passive layer formed with WMF was much more porous than without WMF, thereby facilitating mass transport. Therefore, WMF could accelerate ZVI corrosion and alleviate the detrimental effects of the passive layer, resulting in more rapid removal of Cr(VI) by ZVI. Exploiting the magnetic memory of ZVI, a two-stage process consisting of a small reactor with WMF for ZVI magnetization and a large reactor for removing contaminants by magnetized ZVI can be employed as a new method of ZVI-mediated remediation
Inhibitory Effect of Sulfite on the SO<sub>4</sub>Ā·<sup>ā</sup>āInduced Transformation of Selected Organic Contaminants in Sulfite-Based Advanced Oxidation Processes
Sulfite (S(IV))-based advanced oxidation processes (AOPs),
with
SO4Ā·ā being the primary
oxidant, have attracted increasing attention for degrading organic
contaminants in water. However, the side effect of S(IV) as a reductant
on the SO4Ā·ā-induced
transformation of organic contaminants has never been revealed. For
the first time, we demonstrated such an effect of S(IV) by taking
the MnO2/S(IV) system as the surrogate S(IV)-based AOP.
Multiple evidence confirmed that SO4Ā·ā is the sole active oxidant in the MnO2/S(IV)
system. The relative-rate experiments in the UV/S2O82ā system, a SO4Ā·ā-dominated process with the presence of excess tert-butanol, and the MnO2/S(IV) system showed
that S(IV) can inhibit the SO4Ā·ā-induced transformation of some organic contaminants, with the inhibiting
effect being strongly dependent on the solution pH. Flash photolysis
experiments and reduction potential calculations clarified the necessary
reaction conditions for the inhibiting effect of S(IV) to occur, i.e.,
the reduction of oxidation intermediate of organic contaminants (TCĀ·+) by S(IV) to parent compound (TC) is exergonic
(ĪE > 0), and its rate is faster or comparable
to that of the transformation of TCĀ·+ to
stable products. This work updates the fundamental understanding of
the degradation of organic contaminants in S(IV)-based AOPs
Aging of Zerovalent Iron in Synthetic Groundwater: Xāray Photoelectron Spectroscopy Depth Profiling Characterization and Depassivation with Uniform Magnetic Field
Scanning
electron microscopy (SEM), Raman spectroscopy, and X-ray
photoelectron spectroscopy (XPS) depth profiling were employed to
characterize the aged zerovalent iron (AZVI) samples incubated in
synthetic groundwater. The AZVI samples prepared under different conditions
exhibited the passive layers of different morphologies, amounts, and
constituents. Owing to the accumulation of iron oxides on their surface,
all the prepared AZVI samples were much less reactive than the pristine
ZVI for SeĀ(IV) removal. However, the reactivity of all AZVI samples
toward SeĀ(IV) sequestration could be significantly enhanced by applying
a uniform magnetic field (UMF). Moreover, the flux intensity of UMF
necessary to depassivate an AZVI sample was strongly dependent on
the properties of its passive layer. The UMF of 1 mT was strong enough
to restore the reactivity of the AZVI samples with Fe<sub>3</sub>O<sub>4</sub> as the major constituent of the passive film or with a thin
layer of Ī±-Fe<sub>2</sub>O<sub>3</sub> and Ī³-FeOOH in
the external passive film. The flux intensity of UMF necessary to
depassivate the AZVI samples would increase to 2 mT or even 5 mT if
the AZVI samples were covered with passive films being thicker, denser,
and contained more Ī³-FeOOH and Ī±-Fe<sub>2</sub>O<sub>3</sub>. Furthermore, increasing the flux intensity of UMF facilitated the
reduction of SeĀ(IV) to Se(0) by AZVI samples
Effect of Weak Magnetic Field on Arsenate and Arsenite Removal from Water by Zerovalent Iron: An XAFS Investigation
In
this study, a weak magnetic field (WMF), superimposed with a
permanent magnet, was utilized to improve ZVI corrosion and thereby
enhance AsĀ(V)/AsĀ(III) removal by ZVI at pH<sub>ini</sub> 3.0ā9.0.
The experiment with real arsenic-bearing groundwater revealed that
WMF could greatly improve arsenic removal by ZVI even in the presence
of various cations and anions. The WMF-induced improvement in AsĀ(V)/AsĀ(III)
removal by ZVI should be primarily associated with accelerated ZVI
corrosion, as evidenced by the pH variation, Fe<sup>2+</sup> release,
and the formation of corrosion products as characterized with X-ray
absorption fine structure spectroscopy. The arsenic species analysis
in solution/solid phases at pH<sub>ini</sub> 3.0 revealed that AsĀ(III)
oxidation to AsĀ(V) in aqueous phase preceded its subsequent sequestration
by the newly formed iron (hydr)Āoxides. However, both AsĀ(V) adsorption
following AsĀ(III) oxidation to AsĀ(V) in solution and AsĀ(III) adsorption
preceding its conversion to AsĀ(V) in solid phase were observed at
pH<sub>ini</sub> 5.0ā9.0. The application of WMF accelerated
the transformation of AsĀ(III) to AsĀ(V) in both aqueous and solid phases
at pH<sub>ini</sub> 5.0ā9.0 and enhanced the oxidation of AsĀ(III)
to AsĀ(V) in solution at pH<sub>ini</sub> 3.0
Combined Effect of Weak Magnetic Fields and Anions on Arsenite Sequestration by Zerovalent Iron: Kinetics and Mechanisms
In this study, the effects of major
anions (e.g., ClO<sub>4</sub><sup>ā</sup>, NO<sub>3</sub><sup>ā</sup>, Cl<sup>ā</sup>, and SO<sub>4</sub><sup>2ā</sup>) in water on the reactivity
of zerovalent iron (ZVI) toward AsĀ(III) sequestration were evaluated
with and without a weak magnetic field (WMF). Without WMF, ClO<sub>4</sub><sup>ā</sup> and NO<sub>3</sub><sup>ā</sup> had
negligible influence on AsĀ(III) removal by ZVI, but Cl<sup>ā</sup> and SO<sub>4</sub><sup>2ā</sup> could improve AsĀ(III) sequestration
by ZVI. Moreover, the WMF-enhancing effect on AsĀ(III) removal by ZVI
was minor in ultrapure water. A synergetic effect of WMF and individual
anion on improving AsĀ(III) removal by ZVI was observed for each of
the investigated anion, which became more pronounced as the concentration
of anion increased. Based on the extent of enhancing effects, these
anions were ranked in the order of SO<sub>4</sub><sup>2ā</sup> > Cl<sup>ā</sup> > NO<sub>3</sub><sup>ā</sup> ā
ClO<sub>4</sub><sup>ā</sup> (from most- to least-enhanced).
Furthermore, the inhibitory effect of HSiO<sub>3</sub><sup>ā</sup>, HCO<sub>3</sub><sup>ā</sup>, and H<sub>2</sub>PO<sub>4</sub><sup>ā</sup> on ZVI corrosion could be alleviated taking advantage
of the combined effect of WMF and SO<sub>4</sub><sup>2ā</sup>. The coupled influence of anions and WMF was associated with the
simultaneous movement of anions with paramagnetic Fe<sup>2+</sup> to
keep local electroneutrality in solution. Our findings suggest that
the presence of anions is quite essential to maintaining or stimulating
the WMF effect
Advances in Sulfidation of Zerovalent Iron for Water Decontamination
Sulfidation
has gained increasing interest in recent years for
improving the sequestration of contaminants by zerovalent iron (ZVI).
In view of the bright prospects of the sulfidated ZVI (S-ZVI), this
review comprehensively summarized the latest developments in sulfidation
of ZVI, particularly that of nanoscale ZVI (S-nZVI). The milestones
in development of S-ZVI technology including its background, enlightenment,
synthesis, characterization, water remediation and treatment, etc.,
are summarized. Under most circumstances, sulfidation can enhance
the sequestration of various organic compounds and metalĀ(loid)Ās by
ZVI to various extents. In particular, the reactivity of S-ZVI toward
contaminants is strongly dependent on S/Fe molar ratio, sulfidation
method, and solution chemistry. Additionally, sulfidation can improve
the selectivity of ZVI toward targeted contaminant over water under
anaerobic conditions. The mechanisms of sulfidation-induced improvement
in contaminants sequestration by ZVI are also summarized. Finally,
this review identifies the current knowledge gaps and future research
needs of S-ZVI for environmental application
Highly Efficient Preparation of Multiscaled Quantum Dot Barcodes for Multiplexed Hepatitis B Detection
Both disease diagnosis and therapeutic treatments require real-time information from assays capable of identifying multiple targets. Among various multiplexed biochips, multiplexed suspension assays of quantum dot (QD)-encoded microspheres are highly advantageous. This arises from the excellent fluorescent properties of the QDs incorporated into these microspheres, thus allowing them to serve as āQD barcodesā. QD barcodes can be prepared through various approaches. However, the formulation of improved synthetic techniques that may allow more efficient preparation of QD barcodes with better encoding accuracy still remains a challenge. In this report, we describe a combined membrane emulsificationāsolvent evaporation (MESE) approach for the efficient preparation of QD barcodes. By combining the advantages of the MESE approach in controlling the barcode sizes with accurate encoding, a three-dimensional barcode library that integrates the signals of the forward scattering, fluorescence 1, and fluorescence 4 channels was established <i>via</i> flow cytometry. The five indexes of hepatitis B viruses were chosen as diagnostic targets to examine the feasibility of the QD barcodes in high-throughput diagnosis. On the basis of showing that singleplex detection is feasible, we demonstrate the ability of these QD barcodes to simultaneously and selectively detect a multitude of diverse biomolecular targets