Abstract
Defects of graphene are the most important concern for the successful applications of graphene since they affect device performance significantly. However, once the graphene is integrated in the device structures, the quality of graphene and surrounding environment could only be assessed using indirect information such as hysteresis, mobility and drive current. Here we develop a discharge current analysis method to measure the quality of graphene integrated in a field effect transistor structure by analyzing the discharge current and examine its validity using various device structures. The density of charging sites affecting the performance of graphene field effect transistor obtained using the discharge current analysis method was on the order of 1014/cm2, which closely correlates with the intensity ratio of the D to G bands in Raman spectroscopy. The graphene FETs fabricated on poly(ethylene naphthalate) (PEN) are found to have a lower density of charging sites than those on SiO2/Si substrate, mainly due to reduced interfacial interaction between the graphene and the PEN. This method can be an indispensable means to improve the stability of devices using a graphene as it provides an accurate and quantitative way to define the quality of graphene after the device fabrication.
Highlights
Defects of graphene are the most important concern for the successful applications of graphene since they affect device performance significantly
The density of charging sites affecting the performance of graphene field effect transistor obtained using the discharge current analysis method was on the order of 1014/cm[2], which closely correlates with the intensity ratio of the D to G bands in Raman spectroscopy
This method can be an indispensable means to improve the stability of devices using a graphene as it provides an accurate and quantitative way to define the quality of graphene after the device fabrication
Summary
Estimating defects in graphene devices using discharge current analysis method. A new electrical characterization method to obtain quantitative information on defects and other environmental factors representing the quality of graphene FETs has been proposed and its validity has been examined using devices fabricated on a large area monolayer graphene sheets with different levels of physical defect density (see Methods) This method, called the discharge current analysis (DCA) method, modulates the carrier concentration of graphene periodically using an external pulse bias and translates the frequency dependence of the charges discharged from the graphene channel into a density of charging sites.
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call