With the increase of the mass ratio to 1:7.5, Ag particles further aggregate but still disperse well (Figure 4f). Finally, with the mass ratio of 2:1, the morphology of those Ag particles becomes bigger and irregular (Figure 4g). Figure 3 AFM images of graphene oxide. (a) AFM image
and (b) the height profile of the image. Figure 4 SEM images of surface morphologies of different films. (a) Graphene oxide films, (b) graphene films (reduced by ascorbic acid), and (c to g) graphene-Ag composite films (the amount of AgNO3 is from 2 to 300 mg in each film). EDX is used to qualitatively determine the variation of relative ratio of each element. The results in Figure 5 and Table 1 show that Selleck AZD6244 the atomic ratios of C/O of the graphene films and graphene-Ag composite films are various from 2.2 to 2.5, lower than those in a previous study [11]. Compared with the graphene oxide films (the atomic ratio of C/O is approximately 1.5), the increased CB-839 cell line atomic ratio of C/O of the composite films means that
the reduction progress has https://www.selleckchem.com/products/stattic.html occurred. Simultaneously, the weight percentages of the Ag element may influence the reaction in some way. When the amount of AgNO3 reaches to 300 mg, the atomic ratio of C/O is far lower, indicating that the reduction process may be affected
when the amount of AgNO3 is excessive. As for EDX results, the appropriate amount of AgNO3 is around 5 to 10 mg. Figure 5 EDX spectra of graphene and composite films. (a) Graphene films and (b) graphene-Ag composite films; the mass ratio of AgNO3/graphene oxide is 2:1. Table 1 Elements of all films measured by EDX AgNO3 (mg) Weight (%) Atomic (%) Atomic ratio (C/O) C O Ag C O Ag GO 50.03 44.03 58.11 39.17 1.48 0 65.57 34.43 71.72 28.28 2.54 2 61.54 37.83 0.63 68.37 31.55 0.08 2.17 5 64.85 34.26 0.89 71.52 28.37 0.11 2.52 10 63.46 34.42 2.12 70.88 28.86 0.26 2.46 20 59.06 35.09 5.85 68.63 30.61 0.76 2.24 300 51.86 40.87 7.27 62.22 36.81 0.97 1.69 0 stands for the graphene film reduced for 5 h. The XRD patterns also support the results from SEM and EDX. Only when the amount of AgNO3 is 300 mg, the final weight percentage of Ag is more than 7%, so the crystal structure Erastin cell line and ordering of Ag particles can be characterized by XRD. As shown in Figure 6 (i), the characteristic peaks at 38.02°, 44.24°, and 64.56° correspond with the (111), (200), and (220) planes of the cubic Ag crystal (JCPDS no. 04–0783), respectively, which indicates that the metallic Ag particles are formed after being reduced. According to the Bragg spacing equation, the characteristic peak of carbon (002) changes from 26.6° (Figure 6 (j), pristine graphite powder) to 9.6° (Figure 6 (a), graphene oxide) and sharply weakens, showing that the layer-to-layer distance (d-spacing) from 0.67 to 1.