Because of its irregular spherical morphology with out any indication of a Tenofovir diphosphate In stock core-shell structure irregular spherical morphology with no any indication of a coreshell structure as a result of its prepared hydrophobicity and poor reaction with acrylate monomers. As for the composites hydrophobicity and poor reaction with acrylate monomers. As for the composites pre because of in the modified epoxy resins, they show a spherical structure (Figure 5b,c) pared from the modified epoxy resins, they show a spherical structure (Figure 5b,c) be core-shell their facile reaction together with the acrylate monomer. Nonetheless, the three-layer reason for their facile reaction with all the acrylate monomer. Nonetheless, the threelayer core monomer structure was not observable (Figure 5c), plausibly owing to the similarity with the composition among the intermediate layer and shell layer.Coatings 2021, 11, x FOR PEER REVIEWCoatings 2021, 11, x FOR PEER REVIEW9 of9 ofCoatings 2021, 11,shell structure was not observable (Figure 5c), plausibly owing towards the similarity on the monomer composition involving the intermediate layer and shell layer. towards the similarity in the shell structure was not observable (Figure 5c), plausibly owingmonomer composition in between the intermediate layer and shell layer.9 Aluminum Hydroxide Purity ofFigure 5. TEM of (a) E44, and that of waterborne epoxystyrene crylate composites with (b) con Figure five. TEM of (a) E-44, and that of waterborne epoxy-styrene crylate composites with (b) Figure five. TEM of (a) E44, and that of waterborne epoxystyrene crylate composites with (b) con ventional core hell structure and (c) threelayer core hell structure. conventional core-shell structure and (c) three-layer core-shell structure. ventional core hell structure and (c) threelayer core hell structure.three.4. Determination of Intermediate Layer Thickness of Three-Layer Core-Shell Emulsion three.4. Determination of Intermediate Layer Thickness of ThreeLayer Core hell Emulsion 3.four. Determination of Intermediate Layer Thickness of ThreeLayer Core hell Emulsion To determine thermal events, a DSC test was performed (Figure 6a). To identify thermal events, a DSC test was carried out (Figure 6a). To determine thermal events, a DSC test was conducted (Figure 6a).Figure six. DSC curves and TOPEM-DSC curves of waterborne epoxy-styrene crylate composite emulsion film: (a) DSC curves; TOPEM-DSC curves of (b) three-layer core-shell structure and (c) traditional core-shell structure. (15 modified E-44, the whole: complete latex particle, core: pure core polymer, and shell: pure shell polymer).Coatings 2021, 11,10 ofThere are 3 glass transitions for the three-layer core-shell composite, whereas you can find only two glass transitions for the traditional core-shell emulsion film. A extra detailed structure characterization from the three-layer core-shell emulsion film was performed by TOPEM-DSC (Figure 6b). For comparison, the conventional core-shell emulsion film was also characterized (Figure 6c). Determined by the TOPEM-DSC curves, the specific heat capacity C_p of every single phase of your film in the quasi-steady state could be obtained. The mass fraction of each phase can then be calculated by utilizing the formula, along with the thickness of each and every layer with the latex particles is often calculated by combining with all the particle size outcomes, as shown in Table two. As can be noticed, the sum of c and s for the conventional core-shell particle is much less than 1, indicating the existence of an interface layer Ri. Because of the similarity with the monomer compos.