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Why Oxidation and Decarburization Matter

Oxidation and decarburization are among the most expensive and damaging heat treatment defects in aerospace, automotive, oil & gas, tooling, and heavy manufacturing industries. Even when parts meet dimensional tolerances, poor atmosphere control during heat treatment can result in:

• Reduced hardness
• Loss of fatigue strength
• Surface softening
• Poor wear resistance
• Case depth failure
• Nitriding rejection
• Surface cracking
• NADCAP nonconformance
• Expensive scrap and rework

“Heat treatment failures often begin at the surface — exactly where oxidation and decarburization occur.”

What Is Oxidation During Heat Treatment?

Oxidation occurs when oxygen reacts with hot metal surfaces during heat treatment, producing scale, discoloration, and metal loss.

Common Signs of Oxidation

• Heavy black scale
• Blue or brown discoloration
• Surface roughness
• Weight loss
• Pitting after nitriding
• Poor surface finish

What Is Decarburization?

Decarburization is the loss of carbon from the steel surface during heat treatment. When steel is heated in oxygen-containing atmospheres, carbon reacts with oxygen and leaves the material surface.

Why Decarburization Is Dangerous

Decarburization creates a softer surface layer with lower hardness and reduced fatigue resistance. For aerospace gears, bearings, shafts, springs, and tooling, this can cause catastrophic failures.

Common Grades Highly Susceptible to Oxidation and Decarburization

Main Causes of Oxidation and Decarburization

Most Effective Ways to Reduce Oxidation and Decarburization

1. Use Vacuum Heat Treatment

Vacuum furnaces remove oxygen from the heat treatment chamber, dramatically reducing oxidation and decarburization.

2. Use Controlled Atmosphere Furnaces

Controlled atmospheres use protective gases such as Nitrogen, Hydrogen, Endothermic gas, and Argon to reduce oxygen levels and stabilize carbon potential.

3. Monitor Carbon Potential

For carburizing steels (8620, 9310), maintaining correct carbon potential is critical for avoiding case depth failure, soft case conditions, and surface carbon depletion.

4. Improve Furnace Sealing

Air leaks are one of the biggest causes of oxidation. Check door seals, thermocouple ports, fan penetrations, and quench vestibules.

5. Maintain AMS 2750 Furnace Compliance

AMS 2750 governs Temperature Uniformity Surveys (TUS) and System Accuracy Tests (SAT). Poor temperature uniformity increases oxidation risk and process instability.

How Aerospace Manufacturers Prevent Decarburization

• Vacuum furnaces
• AMS 2750 pyrometry systems
• Controlled carbon potential systems
• Low-pressure carburizing (LPC)
• Oxygen probes and Dew point monitoring

Final Thoughts

Oxidation and decarburization remain major quality risks in aerospace and industrial heat treatment. Critical alloys require carefully controlled atmospheres, accurate pyrometry, and process discipline to maintain surface integrity.