With the rising awareness of environmental friendliness, reducing and replacing the use of petrochemicals has become a global trend in recent years. Among all the candidates for materials to replace petrochemicals, cellulose has gained much attention due to its advantages such as renewability, low cost, good biocompatibility, lightweight, and thermal stability. Because of its flexibility, environmental friendliness, printability, and compatibility with the roll-to-roll process, cellulose paper is more competitive with plastic and glass as a substrate for electronic components. Moreover, with the addition of cellulose nanomaterials, cellulose nanopaper becomes smoother and more transparent. Still, there are obstacles to the application of cellulose nanopaper because of its hydrophilicity. In this study, we modified cellulose with citric acid to improve its moisture resistance. Meanwhile, different cellulose nanomaterials were combined to gain preferable properties. The results showed that the cellulose nanopaper containing CNF had higher roughness and lower transparency due to the agglomeration of fibers, yet had a positive effect on the mechanical properties. Although TOCN can improve the transmittance of cellulose nanopaper, it had poor thermal stability. Not only did the presence of CNC improve the transparency of the nanopaper, it also exhibited ferroelectricity. On the other hand, by the modification of citric acid, the water resistance and thermal stability of the cellulose nanopaper were significantly improved. To sum up, by adjusting the composite ratio of cellulose nanomaterials, ideal properties can be obtained, and with esterification, a non-toxic and environmentally friendly process can be used to fabricate cellulose nanopaper.