Laboratory for analysis and expertise

Corrosion identification expertise on parts in the laboratory

Identifying the origin of corrosion on a metal part

A corrosion observed on a metal part can have multiple causes: aggressive environment, coating defect, surface contamination, material heterogeneity, galvanic coupling, or process drift. For an industrial company, the challenge is to quickly determine the mechanism involved in order to secure production, address the nonconformity, and avoid recurrence in service. Our laboratory supports manufacturers and users of metal materials in the corrosion identification on parts, from observing the first clues to identifying the root causes.

Analyzing corrosion, fracture, and surface defects

The expertise may include a fractographic analysis to characterize brittle, ductile, or fatigue fracture, observation of the fracture surface to highlight signs of corrosion, comparison of sound and failed areas by hardness and microstructure, as well as determination of the composition of the metal part. In the event of a surface defect, the examination makes it possible to identify wear, irregularities, cracks, topographic defects, coating nonconformities, or abnormal roughness. These investigations naturally fit within the services of Laboratoire Materiaux.

Checking corrosion resistance before market launch

To anticipate failures before industrialization, the laboratory assesses a part’s corrosion resistance through accelerated aging and tests in simulated environments. Studies may cover bare materials, coatings, paints, surface treatments, or assemblies of dissimilar metals. The objective is to compare solutions, rank risks, and validate the robustness of a technical choice under representative service conditions.

Having multi-scale analytical capabilities

The effectiveness of a corrosion expertise relies on combining several levels of analysis: surface, cross-section, deposit, metal matrix, and environment. The laboratory relies on microscopic observations, elemental analysis, and behavior tests to link visible damage to its physico-chemical mechanism. This approach makes it possible to move from a finding of corrosion on parts to a conclusion that can be used for quality, production, or R&D.

Laboratory expertise to understand and control corrosion

Our corrosion expertise approach combines multi-scale observations, chemical analysis, electrochemical tests, and metallographic examinations. It makes it possible to characterize the corrosion mode, assess the oxidation state, look for corrosive or oxidizing agents, verify material compliance, and check the homogeneity of a surface treatment. This approach applies equally to failure investigations, validation studies before industrialization, coating comparisons, and process quality monitoring.

Using the right techniques for each mechanism

Depending on the need, the laboratory uses SEM-EDX for morphology and local composition, FEG-SEM and FEB-EDX SEM for detailed surface and deposit observation, optical microscopy for metallographic cross-sections, ICP-AES for trace elements, XPS for surface chemistry, XRD for crystal structure, as well as hardness measurements and C/S, N/O, H elemental analyzers. For surface observations, our Laboratoire Analyse Meb provides a particularly relevant level of insight.

Performing electrochemical tests and accelerated aging

The test methods include measurement of the open-circuit potential OCV, determination of the corrosion rate by LSV, electrochemical impedance spectroscopy EIS, and the study of galvanic coupling. Salt spray tests and simulations of specific media can also be carried out: seawater, chlorides, extreme pH, acidic or basic solutions, inhibiting media. This approach is particularly useful for parts produced by innovative processes, including Fabrication Additive Pieces Metalliques.

Combining chemistry, metallography, and electrochemistry

The main resources available are the potentiostat, salt spray chambers, optical microscope, hardness tester, SEM-EDX, FEG-SEM, FEB-EDX SEM, ICP, XPS, XRD, and elemental analyzers. These instruments make it possible to characterize deposits, detect precursors such as halogens or contamination, measure coating thickness loss, verify a material grade, and document process compliance. For additional characterization needs, also see Laboratoire Materiaux.

Rely on a laboratory partner focused on industrial results

Filab supports manufacturers in the metallurgy sector and users of metallic materials throughout the entire product lifecycle: failure analysis, compliance testing, comparative coating studies, R&D support, design of experiments, simulation of specific environments, and tailor-made training. The laboratory works with a decision-oriented approach: understanding the origin of corrosion, validating the resistance of a material or process, then defining the actions to take to ensure the long-term reliability of parts and assemblies.

Frequently asked questions

How can you reliably identify the origin of corrosion on a metal part?

Reliable identification of corrosion on a part relies on a cross-analysis of the appearance, chemical composition, microstructure, surface condition, and exposure environment. The laboratory determines whether the degradation is due to pitting, galvanic, crevice, or general corrosion, then checks the contributing factors: coating defect, loss of thickness, surface contamination, noncompliant grade, or aggressive service conditions.

What analysis should be carried out to characterize corrosion, fracture, or a surface defect?

The analysis to be carried out depend on the observed symptom and the level of information required. Visible corrosion generally calls for surface observation, chemical identification of deposits, and metallurgical verification of the part. A fracture additionally requires fractography and microstructural comparison. A coating defect or loss of protection calls for cross-section, composition, and homogeneity examinations.

How can the corrosion resistance of a material, coating, or metal assembly be validated?

Corrosion resistance validation relies on comparative, instrumented tests that make it possible to measure the spontaneous behavior of the metal, its degradation rate, coating integrity, and the risk of differential corrosion between materials. The results are used to select a material, optimize a surface treatment, or justify a process before moving into production.

What technical resources does the Filab laboratory use for a complete corrosion expertise assessment?

Filab’s laboratory uses a combination of observation techniques, chemical analysis, and electrochemical testing to establish a robust diagnosis. This complementary approach makes it possible to address issues related to inspection, expert assessment, material validation, and industrial decision-making support.

Why use Filab’s laboratory for corrosion identification expertise on parts?

Using Filab’s laboratory means benefiting from technical support to identify, compare, validate, and improve reliability. Have a damaged part analyzed. Verify a metal grade. Inspect a coating. Measure a corrosion rate. Simulate an aggressive environment. Compare several material or treatment solutions. Secure industrial-scale production.
The filab advantages
A highly qualified team
A highly qualified team
Responsiveness in responding to and processing requests
Responsiveness in responding to and processing requests
A COFRAC ISO 17025 accredited laboratory
A COFRAC ISO 17025 accredited laboratory
(Staves available on www.cofrac.com - Accreditation number: 1-1793)
A complete analytical facility of 5,200m²
A complete analytical facility of 5,200m²
Tailor-made support
Tailor-made support
Video debriefing available with the expert
Video debriefing available with the expert
Anaïs DECAUX Customer Support Manager
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