The mechanism of Metal-H2O2 complex immobilized on MCM-48 and enhanced electron transfer for effective peroxone ozonation of sulfamethazine

“…[31] The electrode's surface should be modified to enhance enzyme immobilization and effectiveness of electron transfer, that's the third requisite. [32] The fourth condition is that the incorporation of nanomaterials and other functionalized materials can enhance the stability and functionality of the enzyme-electrode interface. [33] The fifth fundamental requirement is to increase the effectiveness of the enzymeelectrode interface can be affected by optimizing experimental parameters like pH, temperature, and ionic strength.…”

“…The stability of the enzyme‐electrode contact is essential for maintaining biosensor functionality over time, which is the second condition [31] . The electrode‘s surface should be modified to enhance enzyme immobilization and effectiveness of electron transfer, that's the third requisite [32] . The fourth condition is that the incorporation of nanomaterials and other functionalized materials can enhance the stability and functionality of the enzyme‐electrode interface [33] .…”

Graphene‐Based Enzymatic and Non‐Enzymatic Electrochemical Glucose Sensors: Review of Current Research and Advances in Nanotechnology

“…[31] The electrode's surface should be modified to enhance enzyme immobilization and effectiveness of electron transfer, that's the third requisite. [32] The fourth condition is that the incorporation of nanomaterials and other functionalized materials can enhance the stability and functionality of the enzyme-electrode interface. [33] The fifth fundamental requirement is to increase the effectiveness of the enzymeelectrode interface can be affected by optimizing experimental parameters like pH, temperature, and ionic strength.…”

“…The stability of the enzyme‐electrode contact is essential for maintaining biosensor functionality over time, which is the second condition [31] . The electrode‘s surface should be modified to enhance enzyme immobilization and effectiveness of electron transfer, that's the third requisite [32] . The fourth condition is that the incorporation of nanomaterials and other functionalized materials can enhance the stability and functionality of the enzyme‐electrode interface [33] .…”

Graphene‐Based Enzymatic and Non‐Enzymatic Electrochemical Glucose Sensors: Review of Current Research and Advances in Nanotechnology

“…5D, could be assigned to the lattice oxygen (O L ) and surface oxygen species (O s ), respectively. Clearly, the Ru-Ni/CNT (Ru:Ti=10:0) electrode has the highest surface oxygen content, possibly thanks to the adsorbed hydroxyl group on the electrode surface [41][42][43]. In all, This preprint research paper has not been peer reviewed.…”

Electrocatalytic Degradation of Levofloxacin Wastewater by Ni Single-Atom-Kernelled Ru Nanocluster Particles

“…Recently, advanced oxidation processes (AOPs) have been employed for the degradation of SMT, including photocatalysis, photocatalytic fuel cell, 10 Fenton and Fenton-like processes, 11 electrocatalysis, 12 gamma irradiation, 7 and ozonation. 13 Photocatalysis is an emerging advanced oxidation process that has shown tremendous potential for the eradication of anthropogenic pollutants due to its high degradation activities, moderate reaction conditions, and use of renewable solar energy. Through the use of powerful oxidizing radicals (e.g., superoxide radicals (O 2 ˙−) and hydroxyl radicals (˙OH)), which are generated by the redox reactions of photocatalysts, contaminants are broken down into simpler molecules and even inorganic substances.…”

An innovative S-scheme PhC₂Cu/Ag/Ag₂MoO₄ photocatalyst for efficient degradation of sulfamethazine antibiotics: heterojunctions and innergenerated-H₂O₂ promote radical production