Potential of Nb2O5 nanofibers in photocatalytic degradation of organic pollutants

Jesus, Edson Tobias de; Moreira, Ailton José; Sá, Mayara Coelho; Freschi, Gian Paulo Giovanni; Joya, M. R.; Li, Máximo Siu; Paris, E. C.

doi:10.1007/s11356-021-15435-8

Cited by 26 publications

(6 citation statements)

References 65 publications

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“…Recent literature [18,19] has focused on producing niobium-based fibers for photodegradation of the organic pollutants, using polyvinylpyrrolidone (PVP) as a polymeric precursor. The results indicate that the pseudohexagonal TT-Nb 2 O 5 phase showed greater efficiency, more than 62% degradation.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Application of Nb2O5 Nanofibers in CO2 Photoconversion

et al. 2021

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Increasing global warming due to NOx, CO2, and CH4, is significantly harming ecosystems and life worldwide. One promising methodology is converting pollutants into valuable chemicals via photocatalytic processes (by reusable photocatalysts). In this context, the present work aimed to produce a Nb2O5 photocatalyst nanofiber system by electrospinning to convert CO2. Based on the collected data, the calcination at 600 ∘C for 2 h resulted in the best condition to obtain nanofibers with homogeneous surfaces and an average diameter of 84 nm. As a result, the Nb2O5 nanofibers converted CO2 mostly into CO and CH4, reaching values around 8.5 μmol g−1 and 0.55 μmol g−1, respectively.

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Section: Introductionmentioning

confidence: 99%

Preparation and Application of Nb2O5 Nanofibers in CO2 Photoconversion

et al. 2021

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“…It is reported that TC has p K a1 = 3 and p K a2 = 9, suggesting that TC presents in the form of zwitterions at 3 < pH < 9 . At pH = 7, both surface charges of PAA and Bi-N-CDs/BiOBr are negative (Figure S6); hence, electrostatic repulsion may be the main interaction between Bi-N-CDs/BiOBr@TW and zwitterionic TC and RhB, thus restraining the removal of contaminants. ,, Nevertheless, positively charged CV (p K a = 9.4) and MB (cationic) are readily absorbed onto Bi-N-CDs/BiOBr@TW because of electrostatic attraction, thus facilitating elimination reactions. , Impressively, the lower removal efficiency of MB compared to CV may be caused by the weak photosensitivity of MB due to its maximum absorption at 664 nm (Figure S7). TC, as an achromatic molecule, shows only 46.3% removal rate after 300 min, which is due to the absence of a photosensitization process, so it is not susceptible to photodegradation .…”

Section: Resultsmentioning

confidence: 99%

“…39,40,45 Nevertheless, positively charged CV (pK a = 9.4) and MB (cationic) are readily absorbed onto Bi-N-CDs/BiOBr@TW because of electrostatic attraction, thus facilitating elimination reactions. 46,47 Impressively, the lower removal efficiency of MB compared to CV may be caused by the weak photosensitivity of MB due to its maximum absorption at 664 nm (Figure S7). TC, as an achromatic molecule, shows only 46.3% removal rate after 300 min, which is due to the absence of a photosensitization process, so it is not susceptible to photodegradation.…”

Section: Optical Transmittance Of Wood Hydrogelsmentioning

confidence: 99%

A Transparent, High-Strength, and Recyclable Core–Shell Structured Wood Hydrogel Integrated with Carbon Dots for Photodegradation of Rhodamine B

Yue

2023

ACS Appl. Nano Mater.

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The opacity, fragility, and environmental unfriendliness of the traditional photocatalytic matrix cannot fully utilize the properties of photocatalysts and efficiently degrade pollutants. In this work, a transparent wood hydrogel with a core–shell structure was developed using transparent wood (TW) impregnated with polyacrylic acid (PAA) as the core layer and Bi-N-carbon dots/BiOBr (Bi-N-CDs/BiOBr) photocatalyst-initiated polymerization of acrylic acid (AA) monomers as the shell layer. In the shell layer, nanoscale CDs with rich hydrophilic groups built a link between BiOBr and PAA and strengthened the adsorption–photocatalysis synergistic removal for RhB. The original wood backbone well conserved during preparation led to an anisotropic structure in the resultant Bi-N-CDs/BiOBr@TW photocatalytic wood hydrogel. Namely, after introducing Bi-N-CDs/BiOBr as the linker and reinforcing agent, the tensile strength was up to 3.2 and 11.03 MPa along the radial (R-) and axial (A-) directions, which was 1.6- and 1.06-fold of R-TW and A-TW, respectively. Hence, Bi-N-CDs/BiOBr@TW with high strength furnishes multiple separations and reutilizations, and the RhB removal rate is approximately 85% after five cycles. The Bi-N-CDs/BiOBr@TW exhibited light transmittance up to 64.6 and 52.3% at 800 nm along the R- and A-directions, respectively. Moreover, the adsorption–photocatalysis synergistic rate of Bi-N-CDs/BiOBr@TW reached 93% in 300 min at pH = 7. This paper offers a strategy for fabricating wood hydrogels with outstanding stretchability, transparency, dye removal efficiency, and recyclability, opening a significant route for alleviating dye pollution.

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“…In the present case, we cannot assure that this was the cause of the formation of a mixture of crystalline T‐Nb 2 O 5 and H‐Nb 2 O 5 . Nevertheless, several studies connect the presence of T‐Nb 2 O 5 to an increase in photocatalytic activity, depicting results for RhB, [ 59 ] methyl blue (MB), [ 58 ] methyl orange (MO), [ 64 ] and fluoxetine (FLX) [ 65 ] above 40% of the photodegradation.…”

Section: Resultsmentioning

confidence: 99%