The advent of liquid cell technology facilitates the observation of liquid samples in electron microscopes. Such a method has been applied to different researching fields because of its high spatial resolution and feasibility of in-situ observations. Thin Si3N4 membranes are commonly used in commercial liquid cells, but the thickness of the Si3N4 membrane inevitably degrades the image resolution. On the other hand, graphene is the thinnest 2D material with high mechanical strength and high thermal and electrical conductivities. It is chemically inert and also a great adhesive layer for biological cells. It is expected that the liquid cell with graphene as the membrane material to seal liquid will have an improved image resolution for electron microscopy. In this research, we use graphene and Si3N4 in the newly designed liquid cell, which is named the graphene liquid cell microchip (GLC microchip). In the GLC microchip, graphene is used as the viewing window, and a suspended holey Si3N4 thin film supports the graphene membrane. The advantageous properties of graphene are preserved in such a liquid cell; besides, microfluidic channels and electrodes can be fabricated on the Si3N4 supporting layer for electrochemical observations. Nonetheless, the fabrication process of the GLC microchip is complicated. Amount the fabricating steps, transferring graphene onto the holey Si3N4 thin film is the most crucial process. Developing a reliable graphene transfer process is one of the major focuses in this study. Finally, we show the improved image resolution by comparing the scanning electron microscopy images of several kinds of nanoparticle solutions taken respectively from the GLC microchip and the conventional liquid cells.