The degradation mechanism of an epoxy-phenolic can coating

Morsch, Suzanne; Lyon, S.B.; Gibbon, Simon

doi:10.1016/j.porgcoat.2016.03.019

Cited by 45 publications

(34 citation statements)

References 44 publications

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“…Absorbance of infrared radiation induces abrupt thermal expansion of the sample, and this is detected by deflection of an AFM probe in contact with the surface, Figure 1. Further details of the AFM‐IR technique may be found in our previous publications where we have shown that AFM‐IR spectra obtained using this method closely match to those obtained by conventional FTIR techniques 14–17 . For the present study, AFM‐IR height images were collected in contact mode at a scan rate of 1 Hz using a gold‐coated silicon nitride probe (0.07–0.4 N/m spring constant, 13 ± 4 kHz resonant frequency, Bruker).…”

Section: Methodsmentioning

confidence: 76%

Spectroscopic insights into adhesion failure at the buried epoxy‐metal interphase using AFM‐IR

Morsch

Lyon

Gibbon

2020

Surface & Interface Analysis

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Local AFM-IR analysis is performed on the organic coating residues remaining on carbon steel substrates after pull-off adhesion tests. This approach provides unique spectral information, because scattering from these rough substrates has previously prohibited transflectance FTIR analysis of such regions. The AFM-IR spectra of epoxy-amine residues display characteristic oxidation bands, which can only be detected by ATR-FTIR spectroscopy of intact coatings after thermal aging. These oxidation bands are shown to be more intense for thinner coating remnants and dominate the spectra of residue left by coatings removed after thermal aging at 70 C for 4 weeks. This, alongside distinctive changes in the macroscopic adhesion behavior after thermal aging, provides direct evidence that rapid oxidation occurs in the buried polymer-metal interphase during thermal aging.

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Section: Methodsmentioning

confidence: 76%

Spectroscopic insights into adhesion failure at the buried epoxy‐metal interphase using AFM‐IR

Morsch

Lyon

Gibbon

2020

Surface & Interface Analysis

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“… 15 , 40 , 43 , 44 Furthermore, since the IR pulse (10 ns duration), thermal expansion, and damping down of the induced oscillation occur on a faster time scale than the feedback electronics of the AFM, simultaneous contact-mode topographical measurement and IR absorption mapping can be performed at a given wavelength. 8 , 45 − 47 For the present study, AFM-IR images were collected in a contact mode at a scan rate of 0.04 Hz using a gold-coated silicon nitride probe (0.07–0.4 N/m spring constant, 13 ± 4 kHz resonant frequency, Bruker). Maps were obtained using 32 co-averages for 600 points per 300 scan lines.…”

Section: Methodsmentioning

confidence: 99%

Reflectance in AFM-IR: Implications for Interpretation and Remote Analysis of the Buried Interface

et al. 2020

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AFM-IR combines the chemical sensitivity of infrared spectroscopy with the lateral resolution of scanning probe microscopy, allowing nanoscale chemical analysis of almost any organic material under ambient conditions. As a result, this versatile technique is rapidly gaining popularity among materials scientists. Here, we report a previously overlooked source of data and artifacts in AFM-IR analysis; reflection from the buried interface. Periodic arrays of gold on glass are used to show that the overall signal in AFM-IR is affected by the wavelength-dependent reflectivity and thermal response of the underlying substrate. Excitingly, this demonstrates that remote analysis of heterogeneities at the buried interface is possible alongside that of an overlying organic film. On the other hand, AFM-IR users should carefully consider the composition and topography of underlying substrates when interpreting nanoscale infrared data. The common practice of generating ratio images, or indeed the normalization of AFM-IR spectra, should be approached with caution in the presence of substrate heterogeneity or variable sample thickness.

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“…To prevent damage to the aluminum alloys used in aircraft structures due to corrosion, a double-layer protection system consisting of epoxy primers along with an anodized film of sulfuric acid has been used as a protection measure [1,2]. Because aircraft are on the ground for most of the time, the main corrosive environment for them is the ground atmosphere, where the coastal atmosphere has the most significant impact on the safety of the structure of aircraft [3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Long-Term Atmospheric Aging and Corrosion of Epoxy Primer-Coated Aluminum Alloy in Coastal Environments

Zhang

et al. 2021

Coatings

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Aircraft are subjected to extreme weather conditions in coastal areas. This study reports long-term atmospheric exposure tests carried out on an epoxy primer-coated aluminum alloy in a coastal environment for 7, 12, and 20 years. The micromorphology and characteristics of the section and surface, the products of corrosion, electrochemical impedance, and molecular structure of the coated specimens were examined through a spectrophotometer, scanning electron microscopy (SEM), atomic force microscopy (AFM), X-ray diffraction (XRD), electrochemical impedance spectroscopy (EIS), and X-ray photoelectron spectrometer (XPS). The results showed that the angles of contact of the specimens with different numbers of years of atmospheric exposure satisfied the normal distribution. Their fractal dimensions increased with an increase in the duration of exposure. Intergranular corrosion and exfoliation corrosion appeared in the specimens after 20 years, where the product of corrosion was Al(OH)3. The impedances and thermal properties of the epoxy coatings were influenced by the synergistic effects of aging and post-curing. The impedances of the coatings decreased greatly after long-term atmospheric exposure. After 20 years of corrosion, the specimen showed the characteristics of the substrate being corroded. The mechanism of corrosion and the electrochemical equivalent circuit were also analyzed.

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The degradation mechanism of an epoxy-phenolic can coating

Cited by 45 publications

References 44 publications

Spectroscopic insights into adhesion failure at the buried epoxy‐metal interphase using AFM‐IR

Spectroscopic insights into adhesion failure at the buried epoxy‐metal interphase using AFM‐IR

Reflectance in AFM-IR: Implications for Interpretation and Remote Analysis of the Buried Interface

Long-Term Atmospheric Aging and Corrosion of Epoxy Primer-Coated Aluminum Alloy in Coastal Environments

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