Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on water-mediated exchange between holes in the semiconductor and protons in the gate dielectric, we predict anomalous current transients for a non-constant gate bias, while ensuring accumulation. When applying a strongly negative gate bias followed by a less negative bias a back-transfer of protons to holes and an increase of the current is expected. We verify this counterintuitive behavior experimentally and can quantitatively model the transients with the same parameters as used to describe the threshold voltage shift
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wat...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wat...
none6siHere we study the origin of the gate bias-stress effect in organic p-type transistors. Based ...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Organic field-effect transistors exhibit operational instabilities involving a shift of the threshol...
Organic field-effect transistors exhibit operational instabilities involving a shift of the threshol...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wat...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wat...
none6siHere we study the origin of the gate bias-stress effect in organic p-type transistors. Based ...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Here we study the origin of the gate bias-stress effect in organic p-type transistors. Based on wate...
Organic field-effect transistors exhibit operational instabilities involving a shift of the threshol...
Organic field-effect transistors exhibit operational instabilities involving a shift of the threshol...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...
Organic field-effect transistors exhibit operational instabilities when a gate bias is applied. For ...