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W3114012513 endingPage "121929" @default.
W3114012513 startingPage "121929" @default.
W3114012513 abstract "In this study, the effects of different harsh aging environments on the chemical and mechanical properties of neat and multiwall carbon nanotubes (MWCNT) reinforced epoxy resins were investigated. The neat and 1 wt% MWCNT reinforced epoxy resins were exposed to four different corrosive environments, namely deionized water, NaCl solution (10 wt% NaCl), H2SO4 solution (10 wt% H2SO4), and HCl solution (10 wt% HCl. The mass variation results revealed that the highest absorption rates were found in specimens aged in both acidic environments. The highest amount of absorption was observed in the H2SO4 environment, measured approximately 3% for neat epoxy, and 6.5% for MWCNT reinforced epoxy resin. FT-IR spectrums showed that the most affected peaks belong to specimens aged in both acidic environments. Tensile test results revealed that the aging process in H2SO4 solution and deionized water deteriorated the strength of specimens. According to the literature, it was reported that the strength of specimens aged in NaCl solution environment is decreased. However, the same trend has not been in this study. In our study, the strength of specimens aged in NaCl solution environment increased impressively by 29%, which makes this study more striking. Another important point analyzed from the tensile test results was that the MWCNT nanoparticle reinforcement adversely affects the strength of the epoxy resin. So, it can be clearly stated that the use of expensive MWCNTs as filler of epoxy resin is not useful to improve its aging resistance. The scanning electron microscope (SEM) and optical microscope images showed that acidic environments result in different fracture mechanisms from typical polymer damaged surfaces reported in available researches." @default.
W3114012513 created "2021-01-05" @default.
W3114012513 creator A5005345522 @default.
W3114012513 creator A5053295831 @default.
W3114012513 creator A5062476815 @default.
W3114012513 creator A5069400847 @default.
W3114012513 creator A5069621004 @default.
W3114012513 date "2021-02-01" @default.
W3114012513 modified "2023-10-18" @default.
W3114012513 title "The effects of harsh aging environments on the properties of neat and MWCNT reinforced epoxy resins" @default.
W3114012513 cites W1239520011 @default.
W3114012513 cites W1601590482 @default.
W3114012513 cites W1971965910 @default.
W3114012513 cites W1974847078 @default.
W3114012513 cites W1975017333 @default.
W3114012513 cites W1976594612 @default.
W3114012513 cites W1979009760 @default.
W3114012513 cites W1980305251 @default.
W3114012513 cites W1982868071 @default.
W3114012513 cites W1984296606 @default.
W3114012513 cites W1984802055 @default.
W3114012513 cites W1987262673 @default.
W3114012513 cites W1988838631 @default.
W3114012513 cites W1993670508 @default.
W3114012513 cites W1996671052 @default.
W3114012513 cites W1998728971 @default.
W3114012513 cites W1999152455 @default.
W3114012513 cites W2000664086 @default.
W3114012513 cites W2001041869 @default.
W3114012513 cites W2003912215 @default.
W3114012513 cites W2008252777 @default.
W3114012513 cites W2009761673 @default.
W3114012513 cites W2011187780 @default.
W3114012513 cites W2011826919 @default.
W3114012513 cites W2014319387 @default.
W3114012513 cites W2016513354 @default.
W3114012513 cites W2018737659 @default.
W3114012513 cites W2021197191 @default.
W3114012513 cites W2026990115 @default.
W3114012513 cites W2028572034 @default.
W3114012513 cites W2037811318 @default.
W3114012513 cites W2040256586 @default.
W3114012513 cites W2041787632 @default.
W3114012513 cites W2046958843 @default.
W3114012513 cites W2047922974 @default.
W3114012513 cites W2052074285 @default.
W3114012513 cites W2056659483 @default.
W3114012513 cites W2063760035 @default.
W3114012513 cites W2065298268 @default.
W3114012513 cites W2066737768 @default.
W3114012513 cites W2069419377 @default.
W3114012513 cites W2073147625 @default.
W3114012513 cites W2073716333 @default.
W3114012513 cites W2074731630 @default.
W3114012513 cites W2078769896 @default.
W3114012513 cites W2081464915 @default.
W3114012513 cites W2085314968 @default.
W3114012513 cites W2086992285 @default.
W3114012513 cites W2106601366 @default.
W3114012513 cites W2112629005 @default.
W3114012513 cites W2120429830 @default.
W3114012513 cites W2132069920 @default.
W3114012513 cites W2133836027 @default.
W3114012513 cites W2141008297 @default.
W3114012513 cites W2147670894 @default.
W3114012513 cites W2153629499 @default.
W3114012513 cites W2186491321 @default.
W3114012513 cites W2277674381 @default.
W3114012513 cites W2303651934 @default.
W3114012513 cites W2313006325 @default.
W3114012513 cites W2341765921 @default.
W3114012513 cites W2401225612 @default.
W3114012513 cites W2408914487 @default.
W3114012513 cites W2431534577 @default.
W3114012513 cites W2546763276 @default.
W3114012513 cites W2553087032 @default.
W3114012513 cites W2561263564 @default.
W3114012513 cites W2606457469 @default.
W3114012513 cites W2607247913 @default.
W3114012513 cites W2618731136 @default.
W3114012513 cites W2625388945 @default.
W3114012513 cites W2753072599 @default.
W3114012513 cites W2772004684 @default.
W3114012513 cites W2772905655 @default.
W3114012513 cites W2792507002 @default.
W3114012513 cites W2801626289 @default.
W3114012513 cites W2891671763 @default.
W3114012513 cites W2892194133 @default.
W3114012513 cites W2912741166 @default.
W3114012513 cites W2936377522 @default.
W3114012513 cites W3027955775 @default.
W3114012513 cites W3047494721 @default.
W3114012513 cites W3088198527 @default.
W3114012513 cites W4238154501 @default.
W3114012513 cites W795101684 @default.
W3114012513 cites W983639661 @default.
W3114012513 doi "https://doi.org/10.1016/j.conbuildmat.2020.121929" @default.
W3114012513 hasPublicationYear "2021" @default.