TiO2 nanoparticles supported on N–S co-doped rGO as electrocatalyst for non-enzymatic H2O2 sensing

“…However, their reported detection limit of 0.061 mM was comparable to other hydrogen peroxide sensors listed in Table 4 . Meanwhile, Karatekin [ 121 ] attempted to boost the sensitivity and detection limit of hydrogen peroxide by leveraging the synergistic effects of incorporating TiO 2 nanoparticles with N and S-doped rGO. Their findings also demonstrated that incorporating S atoms into GO layers led to a significant enhancement in the catalytic activity of the sensor, hence improving its sensitivity towards hydrogen peroxide.…”

An Overview of Electrochemical Sensors Based on Transition Metal Carbides and Oxides: Synthesis and Applications

“…However, their reported detection limit of 0.061 mM was comparable to other hydrogen peroxide sensors listed in Table 4 . Meanwhile, Karatekin [ 121 ] attempted to boost the sensitivity and detection limit of hydrogen peroxide by leveraging the synergistic effects of incorporating TiO 2 nanoparticles with N and S-doped rGO. Their findings also demonstrated that incorporating S atoms into GO layers led to a significant enhancement in the catalytic activity of the sensor, hence improving its sensitivity towards hydrogen peroxide.…”

An Overview of Electrochemical Sensors Based on Transition Metal Carbides and Oxides: Synthesis and Applications

Metal-free N–S co-doped electrode for electrochemical CO2 reduction to HCOOH

Rapid preparation of Ag/CoO/rGO composites for electrochemical detection of hydrogen peroxide