Heat Treatment of Metals: Hardening and Annealing
Heat Treatment of Metals: Controlling Microstructure
The same piece of steel can be soft as butter or hard as a knife blade — the difference is heat treatment. Controlled heating and cooling rearrange atoms inside the metal and completely change its properties. This is not magic — it is the science of microstructure.
Why Heat Treatment Works
Steel is an alloy of iron and carbon. At different temperatures, iron atoms adopt different crystal arrangements:
- Ferrite (α): BCC (body-centered cubic) — soft, ductile, magnetic. Stable below 727°C.
- Austenite (γ): FCC (face-centered cubic) — dissolves more carbon. Stable above 727°C.
- Cementite (Fe₃C): an iron-carbon compound, very hard and brittle.
- Pearlite: alternating layers of ferrite and cementite — a balance of strength and ductility.
- Martensite: distorted BCT structure — extremely hard and brittle. Forms by rapid cooling.
The critical temperature of 727°C (for steel with 0.77% carbon) is called the eutectoid temperature — above it, everything transforms to austenite.
Hardening: Creating Maximum Hardness
Goal: obtain martensite — the hardest possible microstructure.
Steps:
- Heating: above the critical temperature (typically 800-900°C for carbon steel)
- Soaking: sufficient time to fully transform the structure to austenite
- Quenching: immersion in a cooling medium — austenite has no time to transform to pearlite and instead becomes martensite
Quenching media:
| Medium | Cooling Rate | Usage |
|---|---|---|
| Water | Very fast | Plain carbon steel |
| Oil | Moderate | Alloy steel |
| Brine (salt water) | Fastest | When maximum hardness is needed |
| Air | Slow | High-alloy steel (air-hardening) |
| Polymer | Adjustable | Modern alternative to oil |
Warning: after hardening, the part is hard but extremely brittle — it will shatter like glass. It must never be used in this condition directly.
Tempering: Restoring Toughness
Immediately after hardening, the part is reheated to a temperature below the critical point (150-650°C) and then cooled slowly.
What happens? Martensite releases some of its internal stresses. Part of it transforms into more stable structures. The result: a slight decrease in hardness in exchange for a large increase in toughness.
| Tempering Temperature | Hardness | Toughness | Application |
|---|---|---|---|
| 150-200°C | Very high | Low | Cutting tools, files |
| 200-350°C | High | Moderate | Springs, dies |
| 350-500°C | Moderate | High | Machine parts, shafts |
| 500-650°C | Relatively low | Very high | Wrenches, hammers |
Annealing: Restoring Softness
Goal: soften the metal, relieve internal stresses, and improve machinability.
Steps:
- Heat above the critical temperature
- Soak for sufficient time
- Very slow cooling inside the furnace (turn off the furnace and let it cool naturally)
Result: coarse pearlite — the softest possible condition for steel. Used before difficult forming and machining operations.
Types of annealing:
- Full annealing: heating above critical + furnace cooling — maximum softness
- Stress relief annealing: 550-650°C — does not change microstructure but removes stresses from welding or forming
- Spheroidizing: prolonged heating near the critical temperature — converts cementite into spheres — easiest machining for high-carbon steel
Normalizing: Homogenizing the Structure
Similar to annealing but with cooling in still air instead of the furnace.
Result: fine, uniform pearlite — slightly harder than annealed and more homogeneous. Used:
- After casting or forging to homogenize the structure
- Before final heat treatment
- To improve machinability
Comparing the Four Processes
| Process | Heating | Cooling | Goal | Relative Hardness |
|---|---|---|---|---|
| Hardening | Above critical | Fast (water/oil) | Maximum hardness | Highest |
| Tempering | 150-650°C | Air | Toughness + reduce brittleness | Decreases with temperature |
| Annealing | Above critical | Very slow (furnace) | Maximum softness | Lowest |
| Normalizing | Above critical | Still air | Homogenize structure | Moderate |
Case Hardening: Hard Outside, Tough Inside
Sometimes we need a hard, wear-resistant surface and a soft core that absorbs impact — such as gears and shafts.
Carburizing
Low-carbon steel (0.1-0.2%) is heated in a carbon-rich atmosphere at 900-950°C. Carbon diffuses into the surface (depth 0.5-2mm), making the surface high-carbon and hardenable while the core remains soft.
Nitriding
Heating in an ammonia atmosphere at 500-570°C. Nitrogen diffuses into the surface and forms very hard nitrides. Advantages:
- No quenching needed — hardness forms directly
- Much less distortion (low temperature)
- Excellent wear resistance
Induction Hardening
An induction coil rapidly heats only the surface, followed by spray quenching. Ideal for gear teeth and shaft surfaces — fast, and the hardened layer depth can be precisely controlled.
Microstructure Changes
A metallographic microscope reveals the metal's structure after polishing and chemical etching:
- After annealing: large, clearly defined pearlite grains with ferrite at boundaries — regular and soft
- After normalizing: finer grains — more homogeneous structure
- After hardening: crossed martensite needles — sharp acicular structure
- After tempering: less sharp needles — more stable structure
The Jominy End-Quench Test
The key test for determining hardenability — the ability of steel to form martensite in depth.
Procedure:
- A standard cylindrical specimen (25mm x 100mm) is heated to austenitizing temperature
- Mounted vertically with water sprayed on the bottom end only
- After cooling, a flat is ground along one side
- Hardness is measured at increasing distances from the quenched end
Result: a hardness-distance curve. Steel with high hardenability retains hardness over greater distances.
Alloying elements (Cr, Mo, Mn, Ni) increase hardenability — this is why alloy steel can be hardened with oil or even air instead of water.
Practical Tips from the Shop Floor
- Do not harden steel with less than 0.3% carbon — it will not achieve adequate hardness
- Tempering must follow hardening immediately — do not let the part cool completely
- Cracking during quenching is mainly caused by: sharp corners, uneven cooling, or wrong steel grade
- Large parts need a slower quenching medium to avoid thermal stresses
- Record every heat treatment: temperature, time, quenching medium — repeatability is the key to quality