16 [22, 24]. f c of the CCTO/Au system was larger than the calculated value (0.16). However, the critical exponent (q ≈ 0.55) was lower than the lower limit of the normal range (q ≈ 0.8 to 1), indicating a slow increase in ϵ′ with increasing metal content.
Deviation of f c and q from percolation theory may be due to the agglomeration of Au NPs to form large MK0683 Au particles in the CCTO matrix, as clearly seen in Figure 2d. f c of the CCTO/Au system is comparable to those observed in the Ba0.75Sr0.25TiO3/Ag (f c = 0.285) [9] and BaTiO3/Ni (f c = 0.232 to 0.310) [4, 7] microcomposite systems. In the cases of the nanocomposite systems of PbTiO3/Ag [8] and Pb0.4Sr0.6TiO3/Ag [11], f c values were found to be 0.16. Actually, the obtained f c and q might not be highly accurate values or not the best values due to a large range of Au NPs volume fraction between 0.1 and 0.2. However, one of the most important factors for the observed higher f c https://www.selleckchem.com/products/DAPT-GSI-IX.html for the CCTO/Au system clearly suggested a morphology transition from nanocomposite to microcomposite as Au NP concentration was increased to 20 vol.%. This result is consistent to the microcomposite systems of Ba0.75Sr0.25TiO3/Ag [9] and BaTiO3/Ni [4, 7]. Generally, the distribution of SN-38 datasheet fillers in a matrix has
an influence on the value of f c. For spherical fillers, f c of randomly distributed 3-oxoacyl-(acyl-carrier-protein) reductase fillers is given by the ratio between the particle size of the matrix phase (R 1) and the filler (R 2) [22]. When R 1/R 2 ≈ 1 or R 1 ≈ R 2, we obtain f c ≈ 0.16. As R 1/R 2 > > 1 or R 1 > > R 2, the fillers fill the interstitial space between the matrix phase particles, resulting in a continuous percolating cluster of the filler at f c < 0.16.
As shown in Figure 2, the particle size of CCTO (R 1) is larger than that of Au NPs (R 2), i.e., R 1/R 2 > > 1. Theoretically, f c of the CCTO/Au NP system should be lower than 0.16. However, the observed f c value in the CCTO/Au system was found to be 0.21. Therefore, it is strongly indicated that the primary factor that has a great effect on f c is the agglomeration of the Au filler. Figure 3 The dependence of Au volume fraction on ϵ′ at RT for CCTO/Au nanocomposites. The symbols and solid curve represent the experimental data and the fitted curve, respectively. Insets 1 and 2 show the frequency dependence of ϵ′ at RT and tanδ (at 1 kHz and RT) of CCTO/Au nanocomposites. Large increases in ϵ′ of percolating composites are generally attributed to formation of microcapacitor networks in the composites and/or Maxwell-Wagner polarization [4, 9, 22]. For pure CCTO ceramics, the giant dielectric response is normally associated with the mean grain size [16, 17, 25].