Resistive_Ion_Sensors_Based_on_MetalOxideSemiconductor_Nanostructures_Formed_by_Heating_Metal_Foil
Sensor materials
CuO and ZnO nanostructures formed by heating Cu and Zn foils were applied to the sensor, and the sensing performance of chloride ions (Cl−), sodium ions (Na+), and calcium ions (Ca2+) was studied, and satisfactory sensing performance was demonstrated for low-concentration ionic solutions.
The sensing performance of CuO- and ZnO- base sensors for Cl−, Na+, and Ca2+ ions varies with ion concentration and has different sensitivity and response recovery time.
MOS nanostructures can be formed by heating metal foils, which have the advantages of easy morphology control and large surface area, and are expected to be used in the manufacture of ion sensors.
metal oxide semiconductor (MOS)
ion sensor
resistive sensor
nanostructure
MOS nanostructures can be formed by heating metal foils, which have the advantages of easy morphology control and large surface area, and are expected to be used in the manufacture of ion sensors.
CuO and ZnO nanostructures formed by heating Cu and Zn foils were applied to the sensors, and the sensing performance of chloride ions (Cl−), sodium ions (Na+) and calcium ions (Ca2+) was studied, and satisfactory sensing performance was demonstrated for low-concentration ionic solutions.
The sensing performance of CuO- and ZnO- base sensors for Cl−, Na+, and Ca2+ ions varies with ion concentration and has different sensitivities and response recovery times.
CuO and ZnO nanostructures formed by heating with Cu and Zn foils were applied to the sensor and demonstrated satisfactory sensing performance for low-concentration ionic solutions.
MOS nanostructures can be formed by heating metal foils, which have the advantages of easy morphology control and large surface area, and are expected to be used in the manufacture of ion sensors.
CuO and ZnO nanostructures formed by heating Cu and Zn foils were applied to the sensors, and the sensing performance of chloride ions (Cl−), sodium ions (Na+) and calcium ions (Ca2+) was studied, and satisfactory sensing performance was demonstrated for low-concentration ionic solutions.
The sensing principle of the MOS sensor is based on a change in resistance, and the reaction with DI water results in an increase in the number of electrons on the MOS surface, which in turn leads to an increase or decrease in resistance, which is consistent with the sensitivity to DI water.
CuO and ZnO nanostructures formed by heating Cu and Zn foils were applied to the sensors, and the sensing performance of chloride ions (Cl−), sodium ions (Na+) and calcium ions (Ca2+) was studied, and the satisfactory sensing performance of low-concentration ionic solutions was demonstrated.
The sensing principle of the MOS sensor is based on a change in resistance, and the reaction with DI water results in an increase in the number of electrons on the MOS surface, which in turn leads to an increase or decrease in resistance, which is consistent with the sensitivity to DI water.
MOS nanostructures can be formed by heating metal foils, which have the advantages of easy morphology control and large surface area, and are expected to be used in the manufacture of ion sensors.
MOS nanostructures can be formed by heating metal foils, which have the advantages of easy morphology control and large surface area, and are expected to be used in the manufacture of ion sensors.
CuO and ZnO nanostructures formed by heating Cu and Zn foils were applied to the sensors, and the sensing performance of chloride ions (Cl−), sodium ions (Na+) and calcium ions (Ca2+) was studied, and the satisfactory sensing performance of low-concentration ionic solutions was demonstrated.
The sensing principle of the MOS sensor is based on a change in resistance, and the reaction with DI water results in an increase in the number of electrons on the MOS surface, which in turn leads to an increase or decrease in resistance, which is consistent with the sensitivity to DI water.