2006
DOI: 10.1002/app.23295
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Synthesis, formulation, and characterization of siloxane‐modified epoxy‐based anticorrosive paints

Abstract: Diglycidyl ether of bisphenol A epoxy (E) was modified with hydroxyl-terminated polydimethylsiloxane through a ring-opening addition polymerization reaction. The structural elucidation of the siloxane-modified epoxy resin (ES) was carried out with Fourier transform infrared, 1 H-NMR, and 13 C-NMR spectroscopy techniques. The physicochemical characterization of the synthesized resin (ES) was performed with standard methods. E and ES were subjected to paint formulation with the help of a rutile (TiO 2 ) pigment.… Show more

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Cited by 48 publications
(23 citation statements)
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“…These results indicate that the thermal stability improves as siloxane components are incorporated into the cured networks. 27 This increasing thermal stability may be due to the high thermal stability of the silicon compound and the protecting effect of the silica layer formed during the decomposition process, where silica greatly restrained the oxidation weight loss of the polymeric materials, and resulted in high the residual weight for the polymers at 800 o C. 28 Nevertheless, the decomposition behavior of cured samples in air (Figure 7) follows the two step decomposition mechanism, which is different from that in N 2 ; and the T d 5% and T d 50% of epoxy resin don't increase exactly upon addition of increasing amounts of DPSO100, which may be due to the complex decomposition behavior of cured samples under air atmosphere. Easily obtained from Table II, the T d 5% of the cured samples in air is lower than that in N 2 while the T d 50% in air is higher than that in N 2 , which can be explained that in air, the surface part of the samples can be easily decomposed, resulting in the lower T d 5%, and when the surface part of the samples decomposed into oxides, these oxides can act as a protecting layer for the inside part of the samples, leading to the higher T d 50%.…”
Section: Resultsmentioning
confidence: 99%
“…These results indicate that the thermal stability improves as siloxane components are incorporated into the cured networks. 27 This increasing thermal stability may be due to the high thermal stability of the silicon compound and the protecting effect of the silica layer formed during the decomposition process, where silica greatly restrained the oxidation weight loss of the polymeric materials, and resulted in high the residual weight for the polymers at 800 o C. 28 Nevertheless, the decomposition behavior of cured samples in air (Figure 7) follows the two step decomposition mechanism, which is different from that in N 2 ; and the T d 5% and T d 50% of epoxy resin don't increase exactly upon addition of increasing amounts of DPSO100, which may be due to the complex decomposition behavior of cured samples under air atmosphere. Easily obtained from Table II, the T d 5% of the cured samples in air is lower than that in N 2 while the T d 50% in air is higher than that in N 2 , which can be explained that in air, the surface part of the samples can be easily decomposed, resulting in the lower T d 5%, and when the surface part of the samples decomposed into oxides, these oxides can act as a protecting layer for the inside part of the samples, leading to the higher T d 50%.…”
Section: Resultsmentioning
confidence: 99%
“…44 PDMS-epoxy blend is initially immiscible at room temperature; however, chemically bonding of epoxy to the PDMS chain by the reaction between their reactive groups such as hydroxyl (OH) 12,[21][22][23][24][25][26][27]29 , oxirane, 19,30,31 and amine [32][33][34][35][36][37]45 leads to partial compatibilization. The resulted modified epoxy resins are heterogeneous with PDMS-rich domains irregularly dispersed in the epoxy-rich matrix.…”
Section: Introductionmentioning
confidence: 99%
“…These results indicate that the thermal stability improved as siloxane components were incorporated into the cured networks. 37 This increasing thermal stability may be due to the high thermal stability of the silicone compound and the protecting effect of the silica layer formed during the decomposition process, where silica greatly restrains the oxidation weight loss of the polymeric materials, and results in high the residual weight for the polymers at 800 o C. 38 While T d 50% of HEPSO2-2 is lower than that of the neat epoxy resin. This can be explained that the HEPSO2 decomposed and transferred to the surface of the epoxy resin at the high temperature, in HEPSO2-2 the HEPSO2 content was so small that it could not form protect layer in the surface of the epoxy resin; and the HEPSO2 affected the network of the epoxy resin, which made the decomposition more easily.…”
Section: Resultsmentioning
confidence: 99%