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Topics Covered
Background
Benefits to Customer
Case Study One:
Crater Defects in Lacquer and Paint Coatings
Case Study Two:
Failure of Beverage Can Coatings
Case Study Three: Evaluation of Coating
Integrity
Case Study Four: Lacquer/Varnish Coatings on Wood
Background
Many of today’s lacquer and paint coatings are complex multi-component
formulations, designed for decorative and/or protective and/or functional
applications. Surface analysis methods are important for the study of such
coatings e.g.
- Investigation of lacquer and paint delamination (adhesive and cohesive failures).
- Analysis of other coating defects e.g. craters, particulates, changes in
cosmetic appearance (e.g. bloom, loss of gloss).
- Evaluation of coating integrity e.g. uniformity and distribution, thickness,
homogeneity (phase separation, additive segregation).
Benefits to Customer
- Cost effective - one day of analysis can often identify the coating problem
- Rapid information - clear decisions can be made to take remedial action to
improve processes
- Validation of new processes by comparison to predicted models
- Assessment of competitors’ products - reverse engineering
Case Study One: Crater Defects
in Lacquer and Paint Coatings
Craters were visible in a melamine-based lacquer coating on a metallised
foil. ToF-SIMS was used to analyse a crater with reference to
non-cratered lacquer material. The results revealed high levels of caprylate and
caprate-based esters of glycerol within the crater. Diagnostic signals for this
material include m/z 127+/155+
(CnH2n+1CO+) and m/z
327+/355+/383+
(CnH2n+1C(=O)O-CH2-CH[O(O=C)CnH2n+1]-CH2+)
(where n is a mixture of 7 and 9), readily identifiable using the molecular
specificity of ToF-SIMS. Glyceride esters can be used in lubricant
formulations and the source of this contamination was the coating equipment.
Craters and other defects have also been observed in automotive coatings, illustrating
the necessity for stringent cleanliness specifications during the painting process.
ToF-SIMS is used routinely to investigate these (see figure
1).
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Figure 1. ToF SIMS analysis of a crater defect.
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Figure 2. ToF-SIMS data acquired from within a crater
in an automotive coating, showed that a fluorocarbon contaminant had caused
localised de-wetting of the surface during paint application, resulting in crater
formation.
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Figure 3. The two-colour overlay ToF-SIMS image shows
an intense fluorine signal in the de-wetted area (cyan), associated with the
fluorocarbon contaminant. Organic species from the paint layer are shown in
red.
Case Study Two: Failure of
Beverage Can Coatings
SIMS
depth profiling was used to study the failure of beverage can coatings on long
term shelf storage. The locus of failure was believed to have occurred at the
lacquer coating / can wall interface with a suspected corrosion mechanism
involved.
SIMS profiles
through the lacquer coating and into the steel can substrate revealed the presence
of high levels of chlorine at the lacquer/steel interface on cans with poor
long-term performance (see below). In contrast, good cans had relatively low
levels of chlorine present. In combination with other analyses, the results
revealed a corrosion mechanism involving transport of chlorine to potential
corrosion sites during storage.
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Figure 4. SIMS profile through a the lacquer coating
and into the steel substrate.
Case Study Three: Evaluation of
Coating Integrity
As a quantitative method, XPS is a valuable tool for the determination of coating
uniformity and thickness. This is demonstrated for a functional siloxane coating
on a polymer substrate where multi-area XPS analysis
(supported by SIMS imaging) showed a reasonably homogeneous siloxane
distribution over the polymer surface.
Table 1. XPS
analysis of a siloxane coating on a polymer substrate.
| Element |
Area 1 |
Area 2 |
Area 3 |
| Carbon |
65.9 + 0.3 |
66.1 + 0.3 |
65.0 + 0.4 |
| Oxygen |
26.0 + 0.2 |
25.9 + 0.2 |
26.2 + 0.2 |
| Silicon |
2.5 + 0.1 |
2.7 + 0.1 |
2.8 + 0.2 |
| Sulfur |
1.4 + 0.1 |
1.1 + 0.1 |
1.2 + 0.1 |
| Sodium |
2.1 + 0.2 |
1.8 + 0.2 |
2.3 + 0.3 |
| Potassium |
1.3 + 0.2 |
0.9 + 0.2 |
1.3 + 0.3 |
| Calcium |
0.1 + 0.1 |
0.4 + 0.1 |
0.3 + 0.1 |
| Chlorine |
0.07 + 0.02 |
0.13 + 0.04 |
0.19 + 0.04 |
| Boron |
0.7 + 0.2 |
1.0 + 0.2 |
0.7 + 0.3 |
| Nitrogen |
Not detected |
Not detected |
Not detected |
Case Study Four:
Lacquer/Varnish Coatings on Wood
Depth profiling SIMS and/or SIMS imaging can give an assessment of the effectiveness of
different lacquer formulations for varnishing different woods. This is illustrated
by a two-colour overlay SIMS image of
a varnished wood cross-section which shows the surface film structure and penetration
of a UV-lacquer (blue; using a lacquer-specific signal in the SIMS mass spectrum)
into a wood (brown; using a wood-specific signal in the SIMS mass spectrum).
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Figure 5. Two colour SIMS overlay of a lacquer coating
over wood, lacquer shown in blue and wood in brown.
Source: Ceram
For more information on this source please visit Ceram.