Ting Wang scite author profile

Hierarchical porous Fe3O4 particles with tunable grain size were synthesized based on a facile poly (diallyldimethylammonium chloride) (PDDA)-modulated solvothermal method. The products were characterized with scanning electron microscopy (SEM) and transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), Fourier transform infrared spectroscopy (FT-IR), X-ray diffraction (XRD), N2 adsorption-desorption technique, vibrating sample magnetometer (VSM), and dynamic light scattering (DLS). The results show that increasing the PDDA dosage decrease the grain size and particle size, which increased the particle porosity and enhanced the surface area from 7.05 to 32.75 m(2) g(-1). Possible mechanism can be ascribed to the PDDA function on capping the crystal surface and promoting the viscosity of reaction medium to mediate the growth and assembly of grain. Furthermore, the arsenic adsorption application of the as-obtained Fe3O4 samples was investigated and the adsorption mechanism was proposed. High magnetic Fe3O4 particles with increased surface area display improved arsenic adsorption performance, superior efficiency in low-level arsenic removal, high desorption efficiency, and satisfactory magnetic recyclability, which are very promising compared with commercial Fe3O4 particles.

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Inactivation of Bacteria by Peracetic Acid Combined with Ultraviolet Irradiation: Mechanism and Optimization

Zhang

Wang

Mejia-Tickner

et al. 2020

Environ. Sci. Technol.

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Peracetic acid (PAA) is an emerging disinfectant for municipal wastewater treatment owing to good biocidal effects and limited harmful by-product formation. This study investigated the inactivation of Gram-negative Escherichia coli (E. coli) and Gram-positive Enterococcus durans (E. durans) and Staphylococcus epidermidis (S. epidermidis) by PAA combined with UV concurrently (UV/PAA) or sequentially (PAA-UV/PAA) for enhanced disinfection. Under UV/ PAA, the contributions of different mechanisms (UV, PAA, reactive radicals (mainly • OH and CH 3 C(O)OO • ), and the synergistic effect of all mechanisms involved) to the overall inactivation were quantitatively assessed. Results revealed that radicals played a moderate role in the enhanced disinfection, while the synergistic effect presented a greater contribution, which could be partially linked to the diffusion of PAA into the cells as evidenced for the first time by a fluorescence microscopic method. Taking advantage of PAA diffusion into bacteria, pre-exposure of PAA followed by UV/PAA was demonstrated to yield the highest disinfection efficiency. Indeed, compared to UV/PAA, PAA-UV/PAA could achieve additional 4.7−5.4, 4.1−5.3, and 2.9− 3.4 log inactivation of E. coli, E. durans, and S. epidermidis, respectively, in clean water and secondary/tertiary wastewater effluents when the same amounts of PAA and UV doses were applied in both approaches. Bacterial regrowth tests confirmed minimal regrowth potential after the disinfection.

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Self-Driven “Microfiltration” Enabled by Porous Superabsorbent Polymer (PSAP) Beads for Biofluid Specimen Processing and Storage

Chen

Wang

Dou

et al. 2020

ACS Materials Lett.

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A remote collection of biofluid specimens such as blood and urine remains a great challenge due to the requirement of continuous refrigeration. Without proper temperature regulation, the rapid degradation of analytical targets in the specimen may compromise the accuracy and reliability of the testing results. In this study, we develop porous superabsorbent polymer (PSAP) beads for fast and self-driven “microfiltration” of biofluid samples. This treatment effectively separates small analytical targets ( e.g. , glucose, catalase, and bacteriophage) and large undesired components ( e.g. , bacteria and blood cells) in the biofluids by capturing the former inside and excluding the latter outside the PSAP beads. We have successfully demonstrated that this treatment can reduce sample volume, self-aliquot the liquid sample, avoid microbial contamination, separate plasma from blood cells, stabilize target species inside the beads, and enable long-term storage at room temperature. Potential practical applications of this technology can provide an alternative sample collection and storage approach for medically underserved areas.

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Cu doped Fe₃O₄ magnetic adsorbent for arsenic: synthesis, property, and sorption application

et al. 2015

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Cu) particles were synthesized and applied for arsenic adsorption. As the copper ions increase, the adsorption capacity of Fe 3 O 4 :Cu towards As(V) and As(III) increase from 7.32 to 42.90 mg g -1 and from 8.12 to 37.97 mg g -1 , respectively. The incorporation of copper decreased the particle size, increased the surface area, porosity and zeta potential, leading to the increase of the adsorption sites and affinity toward negative As(V) species. More importantly, the doped copper ions catalyzed the efficient oxidation of As(III) to As(V) by O 2 followed by As(V) adsorption. The Fe 3 O 4 :Cu particles also exhibited good performance toward low level arsenic removal, excellent separation, and satisfactory regeneration property. The results indicate Fe 3 O 4 :Cu particles possess great potential for both As(III) and As(V) adsorption.

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Bacteria and Virus Inactivation: Relative Efficacy and Mechanisms of Peroxyacids and Chlor(am)ine

Wang

Chen

Wang

et al. 2023

Environ. Sci. Technol.

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Peroxyacids (POAs) are a promising alternative to chlorine for reducing the formation of disinfection byproducts. However, their capacity for microbial inactivation and mechanisms of action require further investigation. We evaluated the efficacy of three POAs (performic acid (PFA), peracetic acid (PAA), and perpropionic acid (PPA)) and chlor(am)ine for inactivation of four representative microorganisms (Escherichia coli (Gramnegative bacteria), Staphylococcus epidermidis (Gram-positive bacteria), MS2 bacteriophage (nonenveloped virus), and Φ6 (enveloped virus)) and for reaction rates with biomolecules (amino acids and nucleotides). Bacterial inactivation efficacy (in anaerobic membrane bioreactor (AnMBR) effluent) followed the order of PFA > chlorine > PAA ≈ PPA. Fluorescence microscopic analysis indicated that free chlorine induced surface damage and cell lysis rapidly, whereas POAs led to intracellular oxidative stress through penetrating the intact cell membrane. However, POAs (50 μM) were less effective than chlorine at inactivating viruses, achieving only ∼1-log PFU removal for MS2 and Φ6 after 30 min of reaction in phosphate buffer without genome damage. Results suggest that POAs' unique interaction with bacteria and ineffective viral inactivation could be attributed to their selectivity toward cysteine and methionine through oxygen-transfer reactions and limited reactivity for other biomolecules. These mechanistic insights could inform the application of POAs in water and wastewater treatment.

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Ting Wang

Controllable Synthesis of Hierarchical Porous Fe₃O₄ Particles Mediated by Poly(diallyldimethylammonium chloride) and Their Application in Arsenic Removal

Inactivation of Bacteria by Peracetic Acid Combined with Ultraviolet Irradiation: Mechanism and Optimization

Self-Driven “Microfiltration” Enabled by Porous Superabsorbent Polymer (PSAP) Beads for Biofluid Specimen Processing and Storage

Cu doped Fe₃O₄ magnetic adsorbent for arsenic: synthesis, property, and sorption application

Bacteria and Virus Inactivation: Relative Efficacy and Mechanisms of Peroxyacids and Chlor(am)ine

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Ting Wang

Controllable Synthesis of Hierarchical Porous Fe3O4 Particles Mediated by Poly(diallyldimethylammonium chloride) and Their Application in Arsenic Removal

Inactivation of Bacteria by Peracetic Acid Combined with Ultraviolet Irradiation: Mechanism and Optimization

Self-Driven “Microfiltration” Enabled by Porous Superabsorbent Polymer (PSAP) Beads for Biofluid Specimen Processing and Storage

Cu doped Fe3O4 magnetic adsorbent for arsenic: synthesis, property, and sorption application

Bacteria and Virus Inactivation: Relative Efficacy and Mechanisms of Peroxyacids and Chlor(am)ine

Contact Info

Product

Resources

About

Controllable Synthesis of Hierarchical Porous Fe₃O₄ Particles Mediated by Poly(diallyldimethylammonium chloride) and Their Application in Arsenic Removal

Cu doped Fe₃O₄ magnetic adsorbent for arsenic: synthesis, property, and sorption application