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In a study published in the Journal of Hazardous Materials, nanoparticles of manganese(III) oxide (Mn2O3) were anchored to the pores of attapulgite (APT) nanoscale fibers by an embedding and on-site precipitative process to form catalyst ceramic nanofiber membranes ([email protected]) for the degradation of water contaminants.

Study: Ceramic nanofiber membrane anchoring nanosized Mn2O3 catalytic ozonation of sulfamethoxazole in water. Image Credit: Christos Georghiou/Shutterstock.com

Water shortage has been identified as a worldwide concern due to population expansion and economic growth. A broad range of emerging contaminants (ECs) have been discovered in diverse bodies of water thus far.

Sulfamethoxazole (SMX), a common example of ECs, is widely found in aquatic environments, endangering human wellbeing and water ecosystems. Unfortunately, typical water treating systems are inefficient in removing ECs. As a result, it is critical to create successful EC removal technology.

Advanced oxidative processes (AOPs) are frequently employed to break down emerging pollutants by creating highly reactive species of oxygen such as ⋅OH, O2-, and SO4-. Among the AOPs, the non-uniform catalyzed ozonation procedure has received much interest in its ability to destroy emerging contaminants.

Several metallic oxide particles (Fe3O4, Al2O3, TiO2, CeOx, and MnOx) have been extensively researched in the non-uniform catalyzed ozonation procedure to date. Owing to manganese ions' high oxidation reduction capacity, MnOx has been shown to be an excellent catalyst.

The agglomeration of MnOx nanoparticles (NPs) regrettably leads to a decrease in accessible active spots and a reduction in catalytic performance. Furthermore, the reuse of nanoscale catalysts in suspension takes a while and limits practical uses.

Lately, non-uniform catalyzed ozonation combined with ceramic membrane filtering has been described as a viable approach for overcoming the above-mentioned problems.

The high porosity ceramic layer is ideal for supporting catalytic NPs, eliminating the need for NP reuse while also improving mass transference. The traditional ceramic layer comprised of Al2O3 particles, on the other hand, is comparatively less porous.

Furthermore, catalyst ceramic membranes were often made by impregnation with predecessors or co-sintering with a combination of catalytic particles and innocuous substrates. Under heat stress, catalytic NPs tend to agglomerate and expand to a larger size during the procedure, which is detrimental to catalytic performance.

Attapulgite (APT), an organic fibrous clay, was utilized to create a ceramic nanofiber membrane (CNM) with excellent permeability and porosity. APT also has a great number of nanoscale pits on its exterior. These pits may act as physical barriers and anchorage points to limit the development of catalytic NPs.

Catalyst ceramic nanofibrous membranes ([email protected]) were created and used in an integrative catalyzed ozonation/membrane filtering procedure by attaching manganese(III) oxide NPs to the pits of APT nanoscale fibers.

The developed [email protected] demonstrated better SMX removing ability, with up to 81.3 percent of SMX eliminated in seven hours of uninterrupted running. The quenching studies and electron paramagnetic resonance data supported the involvement of 1O2, ⋅OH, and O2- in the catalyst setup, and 1O2 may serve a major role in the breakdown of SMX.

[email protected] demonstrated a broad application for natural water systems, with the complete elimination of several ECs in actual hospital sewage water reaching 98.5 percent. The enhanced effectiveness of [email protected] may be attributed to the following important synergistic factors.

APT nanoscale pits successfully inhibited the agglomeration and development of Mn2O3 NPs, improved reaction site access, and improved catalyzed ozonation.

The interwoven APT nanofibers generated nanoscale network topologies in which reactive oxygen species (ROS) and SMX molecules were trapped in close proximity, increasing the likelihood of ROS attacking SMX.

The improved Mn(III)/Mn(IV) oxidation reduction cycles induced by engagement among Mn2O3 catalysts and APT targets gave [email protected] higher catalysis stability and allowed for the long-term elimination of SMX throughout continuous filtering.

The use of nanoscale pits on attapulgite nanofibers as anchorage points for catalytic NPs in this study is a unique technique for producing remarkably effective catalyst ceramic membranes.

This technique may be used to create various catalyst ceramic films built on cost-effective and organic mineral resources with nanoconfinement architectures. This inspirational work encourages the use of ceramic films in water filtration.

Yang, Y., Fu, W., Chen, X., Chen, L., Hou, C., Tang, T., & Zhang, X. (2022). Ceramic nanofiber membrane anchoring nanosized Mn2O3 catalytic ozonation of sulfamethoxazole in water. Journal of Hazardous Materials, 436. Available at: https://doi.org/10.1016/j.jhazmat.2022.129168

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Shaheer is a graduate of Aerospace Engineering from the Institute of Space Technology, Islamabad. He has carried out research on a wide range of subjects including Aerospace Instruments and Sensors, Computational Dynamics, Aerospace Structures and Materials, Optimization Techniques, Robotics, and Clean Energy. He has been working as a freelance consultant in Aerospace Engineering for the past year. Technical Writing has always been a strong suit of Shaheer's. He has excelled at whatever he has attempted, from winning accolades on the international stage in match competitions to winning local writing competitions. Shaheer loves cars. From following Formula 1 and reading up on automotive journalism to racing in go-karts himself, his life revolves around cars. He is passionate about his sports and makes sure to always spare time for them. Squash, football, cricket, tennis, and racing are the hobbies he loves to spend his time in.

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