Carburizing vs Nitriding vs Carbonitriding: Case Hardening Comparison Guide
Carburizing, nitriding, and carbonitriding are the three most widely practised diffusion-based case hardening processes in industrial metallurgy, collectively treating hundreds of millions of components annually in the automotive, aerospace, tooling, and heavy engineering industries. Each process achieves a hard, wear-resistant surface over a tough core by diffusing interstitial atoms into the steel surface, but the diffusing species, process temperature, achievable hardness, case depth, distortion, and required steel composition differ fundamentally — and selecting the wrong process for an application is one of the most common and costly specification errors in manufacturing.
Key Takeaways
- Carburizing (850–950 °C) diffuses carbon into low-C steel, requires quenching to develop martensite, produces the deepest cases (0.5–4 mm), and is the best choice for heavily loaded gears and shafts requiring deep case depth.
- Nitriding (480–580 °C) diffuses nitrogen into alloy steel below the transformation temperature; no quench is required, distortion is minimal, surface hardness reaches 700–1200 HV, but case depth is limited to 0.1–0.6 mm.
- Carbonitriding (700–900 °C) co-diffuses carbon and nitrogen; the nitrogen enrichment improves hardenability, enabling adequate case hardness in plain carbon steels with shallower cases (0.1–0.75 mm) and less distortion than full carburizing cycles.
- Nitriding produces the highest surface hardness and best corrosion resistance; carburizing gives the deepest case; carbonitriding is the best compromise for short-cycle, lower-distortion, moderate-depth applications.
- All three processes produce compressive residual stresses in the case, improving bending and contact fatigue resistance.
- Steel selection is critical: nitriding requires alloy steels with Cr, Mo, Al, or V; carburizing and carbonitriding are suited to low-to-medium carbon steels including plain carbon grades.
Carburizing
Nitriding
Carbonitriding
Carburizing: Carbon Diffusion and Case Formation
Process Principles
Carburizing enriches the surface layer of a low-carbon steel (<0.25 wt% C) with carbon by holding the component at 850–950 °C in a carbon-rich atmosphere, above the Ac3 transformation temperature where the steel is fully austenitic and has high carbon solubility (∼1.0 wt% C at 900 °C versus ∼0.02 wt% in ferrite). Carbon diffuses inward from the surface following Fick’s second law, building a concentration gradient. After carburizing, the component is quenched to transform the high-carbon case to martensite while the low-carbon core remains tough and ductile.
Fick's Second Law of Diffusion (governing case depth): ∂C/∂t = D ∂²C/∂x² Solution for semi-infinite solid with constant surface composition Cs: (C(x,t) - C₀) / (Cs - C₀) = 1 - erf(x / (2√(D·t))) Where: C(x,t) = carbon concentration at depth x after time t C₀ = initial carbon content of steel (wt%) Cs = surface carbon content (carbon potential of atmosphere) D = diffusion coefficient of C in austenite (m²/s) erf = Gauss error function Diffusion coefficient D for carbon in austenite (approx.): D (m²/s) = 2.0×10⁻⁵ × exp(-142,000 / (R×T)) At 927°C (1200 K): D ≈ 1.3×10⁻¹¹ m²/s Effective case depth estimate (to 0.4 wt% C): ECD ≈ 2√(D×t) [approximate; exact value from full erf solution]
Process Variants
Gas Carburizing
The dominant industrial process. The atmosphere is an endothermic carrier gas (typically 40% CO + 40% H2 + 20% N2) enriched with a hydrocarbon additive (methane, propane, or natural gas) to maintain a controlled carbon potential (Cp), typically 0.8–1.2 wt% C at the component surface. Carbon potential is monitored and controlled by CO2 analysers or oxygen probes (lambda sensors), enabling precise case depth and surface carbon content programming. The process is well suited to batch and continuous furnace production.
Vacuum (Low-Pressure) Carburizing
The workpiece is heated in a vacuum furnace, then hydrocarbon gas (acetylene or propane) is pulsed into the chamber at low pressure (5–25 mbar). Carbon is deposited by pyrolysis and absorbed at the surface. After the enrichment pulse, a diffusion period in vacuum redistributes carbon deeper into the case. High-pressure gas quenching (HPGQ) with nitrogen or helium replaces oil quench, giving very low distortion. Vacuum carburizing is preferred for complex aerospace components and precision gears where distortion control and surface cleanliness are critical.
Pack and Salt Bath Carburizing
Older processes now largely supplanted by gas and vacuum variants. Pack carburizing (workpiece buried in charcoal + carbonate energiser) is used for small batches or field repairs. Salt bath (liquid) carburizing uses cyanide-containing salts at 845–900 °C — now restricted or banned in many jurisdictions due to cyanide toxicity and waste treatment requirements.
Case Microstructure After Carburizing and Quenching
After gas or vacuum carburizing and quenching, the case consists of high-carbon martensite (typically 0.7–1.0 wt% C at the surface) with retained austenite content increasing toward the surface as carbon content rises. The core transforms to low-carbon lath martensite or bainite (depending on hardenability and quench rate) overlying the original ferrite-pearlite. A well-controlled carburizing cycle produces:
- Surface carbon: 0.75–0.95 wt% (controlled by carbon potential)
- Case hardness: 700–900 HV (60–67 HRC)
- Retained austenite (surface): 15–30 vol% for well-controlled cycles; excessive Cp can raise this to 40%+, reducing hardness and wear resistance
- Core hardness: 25–45 HRC (depending on steel hardenability and section size)
Retained austenite at the surface is a common quality problem in carburizing. It reduces hardness and wear resistance and is managed by limiting surface carbon potential (<0.9 wt% C at surface), applying cryogenic treatment after quenching to convert austenite to martensite, or by double quenching (normalise from carburizing temperature, then requench from below Ac3).
Carburizing Steel Grades
The ideal carburizing steel has low surface carbon (<0.25 wt%) to provide a large driving force for carbon absorption, combined with sufficient core hardenability to develop core strength on quenching. Common grades include:
- AISI 8620 (0.18–0.23% C, 0.4–0.7% Cr, 0.4–0.7% Ni, 0.15–0.25% Mo) — the most widely used automotive carburizing grade
- AISI 4118, 4320, 4820 — higher hardenability for larger section gears and shafts
- AISI 9310 (Ni-Cr-Mo) — aerospace grade for high toughness core requirements
- EN 20MnCr5, 18CrNiMo7-6 — European automotive and gearbox grades
Nitriding: Nitrogen Diffusion and Nitride Formation
Process Principles
Nitriding is performed at 480–580 °C — entirely below the ferrite-to-austenite transformation temperature (Ac1 ∼727 °C for most steels). At these temperatures, atomic nitrogen diffuses into the ferritic steel surface and reacts with nitride-forming alloying elements (Al, Cr, Mo, V, Ti) to precipitate hard, coherent alloy nitrides (AlN, CrN, Cr2N, Mo2N). These nitride precipitates, 2–20 nm in diameter, impose a large strengthening effect through coherency strains — the primary mechanism of nitrided case hardness. Because the process operates below Ac1, no phase transformation occurs in the core and no quenching is required, making nitriding the lowest-distortion case hardening process.
The Nitrided Case Structure: Compound Zone and Diffusion Zone
A fully nitrided case consists of two distinct layers:
Compound Zone (White Layer)
The outermost 5–25 μm consists entirely of iron nitrides: ε-Fe2–3N (hexagonal) and γ’-Fe4N (FCC). This layer is called the “white layer” because it does not etch with Nital under optical microscopy and appears featureless white. It is extremely hard (900–1100 HV) but brittle, with very low toughness. For wear applications, the compound zone is beneficial; for fatigue-critical applications it is typically removed by lapping or controlled to a thin, predominantly γ’ composition by adjusting the nitriding potential (KN).
Diffusion Zone
Below the compound zone lies the diffusion zone, extending 0.1–0.6 mm depending on the steel grade, temperature, and time. This zone contains precipitated alloy nitrides within a nitrogen-supersaturated ferrite matrix. The diffusion zone is the primary source of the hardness gradient and of the beneficial compressive residual stresses that improve fatigue performance. Hardness in the diffusion zone decreases gradually from values approaching those of the compound zone at the interface to core hardness at the diffusion front.
Nitriding case depth (diffusion zone, approximate): d ≈ K×tⁿ where n ≈ 0.5 (parabolic growth), K = rate constant Nitriding potential (controlling compound zone composition): Kₙ = p(NH₃) / p(H₂)^(3/2) Low Kₙ (<1): predominantly γ'-Fe₄N (less brittle compound zone) High Kₙ (>5): predominantly ε-Fe₂ₓ₃N (harder, more brittle) Gas nitriding atmosphere: NH₃ → [N] + 3/2 H₂ (catalysed at steel surface) Dissociation rate controlled to maintain desired Kₙ
Process Variants
Gas Nitriding
Ammonia (NH3) is thermally dissociated at the steel surface, releasing atomic nitrogen for diffusion. Process parameters: 510–540 °C, 20–100 hours, NH3 + N2 + H2 atmosphere with controlled dissociation rate. The Floe (two-stage) process uses a high-nitriding-potential first stage to establish case depth and a low-potential second stage to reduce compound zone brittleness. Gas nitriding is the most widely used nitriding variant for production volumes.
Plasma (Ion) Nitriding
A DC or pulsed-DC glow discharge plasma (N2-H2 mixture, typically 75–80% H2, at 1–10 mbar) bombards the workpiece surface with nitrogen ions, providing both surface activation (sputtering of passive oxide layers) and nitrogen supply. Advantages: lower treatment temperature (down to 400 °C), excellent control of compound zone composition and thickness (or elimination of compound zone entirely), ability to nitride stainless steels and other normally difficult-to-nitride grades by in situ sputtering of the passive layer, shorter cycle times, and better surface finish retention. Limitations: higher equipment cost, smaller batch capacity, Faraday cage effects on complex geometries requiring current-equalisation fixtures.
Salt Bath Nitriding (Ferritic Nitrocarburizing)
Processes such as Tenifer, Tufftride, and Kolene use molten salt baths containing cyanates (KCNO, NaCNO) at 560–580 °C. These are strictly ferritic nitrocarburizing processes (both N and C diffuse simultaneously), producing a compound zone of predominantly ε-carbonitride (ε-Fe2–3(N,C)) with excellent wear and corrosion resistance. The QPQ (Quench-Polish-Quench) variant — salt bath nitrocarburize, quench, oxidise in a second salt bath — provides outstanding corrosion resistance (superior to hard chrome on mild steels) and is widely used for automotive hydraulic parts, firearm components, and tools.
Nitriding Steel Grades
The response to nitriding depends critically on the alloy content. Grades in order of nitriding response:
- 38CrMoAl / Nitralloy 135M (0.35–0.42% C, 1.5% Cr, 0.2% Mo, 1.0% Al): the premier nitriding steel; AlN precipitation gives 950–1100 HV case hardness
- H13 die steel (5% Cr, 1.3% Mo, 1% V): 800–950 HV; excellent for hot-work tooling
- 4140 / 4340 (Cr-Mo steels): 650–750 HV; widely used where moderate nitriding response is acceptable
- M2 HSS: 950–1050 HV; plasma nitriding of HSS cutting tools gives excellent compound zone wear layers
- 316L, 17-4PH stainless: plasma nitriding at low temperature (400–450 °C) produces “expanded austenite” (S-phase) with >1000 HV without sensitisation
Carbonitriding: Combined Carbon and Nitrogen Diffusion
Process Principles
Carbonitriding is a hybrid process performed at 700–900 °C in a gas carburizing atmosphere to which ammonia (NH3, typically 3–10 vol%) is added. Both carbon and nitrogen diffuse simultaneously into the steel surface. The presence of nitrogen has two critical effects that distinguish carbonitriding from carburizing:
- Hardenability enhancement: Nitrogen is a strong austenite stabiliser (it depresses Ms and Mf temperatures and retards pearlite and bainite formation). This allows thinner cases and lower-alloy or plain carbon steels to achieve full martensite transformation on quenching, without the high hardenability alloying required for deep carburizing.
- Improved tempering resistance: Nitrogen in martensite retards carbide coarsening during tempering, giving higher secondary hardness and better dimensional stability at elevated service temperatures (<200 °C).
Because carbonitriding is typically performed at 700–870 °C (lower than gas carburizing) and produces shallower cases requiring shorter cycle times and less severe quenching, distortion is lower than in standard carburizing.
Atmosphere and Process Control
The carbonitriding atmosphere consists of an endothermic carrier gas (as for gas carburizing) plus 3–10% NH3. Increasing NH3 content increases the nitrogen absorption and therefore the nitrogen content at the case surface (typically 0.2–0.5 wt% N at the surface for 5% NH3 additions). Carbon potential is controlled as for carburizing. The upper temperature limit of effective carbonitriding (∼900 °C) is set by the increasing rate of NH3 decomposition to N2 (which does not contribute to nitrogen absorption) as temperature rises. Above 900 °C, the process reverts to essentially carburizing with minimal nitrogen absorption.
Carbonitrided Case Microstructure
After quenching from carbonitriding temperature, the case consists of nitrogen-containing martensite (sometimes called “carbonitride martensite”) with a thin compound zone of ε-carbonitride at the extreme surface (typically 1–5 μm, thinner than in nitriding). The nitrogen in solution within the martensite increases resistance to tempering, making the case harder than an equivalent carburized case at the same tempering temperature. Retained austenite is typically lower in carbonitrided cases than in carburized cases at equivalent surface carbon due to the Ms-depressing effect of nitrogen (somewhat counterintuitively, the hardenability improvement is more pronounced than the Ms depression effect for the nitrogen levels involved).
Master Process Comparison Table
| Property / Parameter | Carburizing | Nitriding | Carbonitriding |
|---|---|---|---|
| Diffusing species | Carbon (C) | Nitrogen (N) | C + N simultaneously |
| Process temperature | 850–950 °C | 480–580 °C | 700–900 °C |
| Atmosphere / medium | Endothermic gas + hydrocarbon; vacuum + acetylene; salt | NH3 / plasma N2-H2 / cyanate salt | Endothermic gas + NH3 (3–10%) |
| Cycle time (typical) | 4–20 h | 10–100 h | 1–4 h |
| Case depth (ECD) | 0.5–4.0+ mm | 0.1–0.6 mm | 0.1–0.75 mm |
| Surface hardness | 700–900 HV (60–67 HRC) | 700–1200 HV | 700–900 HV |
| Quench required? | Yes | No | Yes |
| Distortion risk | Moderate–High | Very Low | Low–Moderate |
| Hardening mechanism | High-C martensite | Alloy nitride precipitation | N-bearing martensite; thin carbonitride compound zone |
| Steel requirement | Low-C (0.08–0.25%) | Alloy (Cr, Mo, Al, V) | 0.15–0.45% C, low-to-medium alloy |
| Post-treatment required | Quench + temper (150–200 °C) | None; optional light temper | Quench + temper |
| Temperature stability of case | Up to 150–200 °C (tempering) | Up to 480–520 °C | Up to 180–230 °C (improved over carb.) |
| Corrosion resistance | No improvement | Good (compound zone); QPQ: excellent | Modest improvement |
| Compressive residual stress | Moderate (case-core transformation mismatch) | High (nitride precipitation volumetric expansion) | Moderate |
| Relative cost (process) | Moderate | High (long cycle) / Moderate (plasma) | Low–Moderate (short cycle) |
| Applicable standards | AMS 2759/7, AMS 2759/2, ISO 15787 | AMS 2759/6, AMS 2759/11 (plasma), ISO 15787 | AMS 2759/3, ISO 15787 |
Process Selection Guide
Selecting between carburizing, nitriding, and carbonitriding requires simultaneous consideration of:
When to Specify Carburizing
- Case depth >0.75 mm is required — for heavily loaded gears, rolling contact bearings, large shafts under combined bending and contact loading
- The component is machined from a low-carbon steel (<0.25% C) with controlled core hardenability
- The application demands high core toughness with a hard case — automotive transmission gears, aircraft propeller shafts, differential pinions
- Component geometry is compatible with the distortion introduced by austenitising at 900 °C and oil/polymer quenching — flat sections, symmetric geometries, or components with grinding allowance after hardening
When to Specify Nitriding
- Minimum distortion is mandatory — crankshafts, injection moulding dies, precision spindles, large thread gauges, and measuring instruments
- Maximum surface hardness is required (>900 HV) — nitralloy grades, H13 die inserts, HSS tools
- The component operates at elevated temperature (<500 °C) where carburized martensite would temper and soften
- Corrosion resistance is required alongside wear resistance — QPQ/Tenifer for automotive hydraulic components and firearm barrels
- The component is already finish-machined to final dimensions and cannot be ground after hardening
When to Specify Carbonitriding
- Short cycle time and low distortion are the primary drivers — high-volume stampings, small gears, chain links, threaded fasteners, nuts
- The component is made from a plain carbon steel (1018, 1020, 1045) where carburizing would give adequate case but nitriding would give inadequate hardness
- Moderate case depth (0.1–0.75 mm) is sufficient for the application loading
- Improved resistance to softening during tempering is required versus standard carburizing
Contextually, the iron-carbon phase diagram directly governs the operating logic of all three processes: carburizing and carbonitriding operate in the austenite phase field where carbon solubility is high; nitriding operates entirely in the ferrite field. The grain boundary characteristics and prior microstructure of the steel influence carbide dissolution kinetics during carburizing and nitrogen diffusion path during nitriding. For components where case depth verification is required, microhardness testing traverses on cross-sections are the standard method per ISO 18203 and AMS standards. The Charpy impact toughness of the core is a critical design parameter for all three processes, as it is the core that provides the damage tolerance and fatigue crack arrest capability of the component.
Industrial Applications
Carburizing Applications
Gas-carburized and case-hardened gears dominate the automotive and truck transmission market. Typical automotive helical and spur gears in 8620 or 20MnCr5 are carburized to 0.6–1.0 mm ECD (to 550 HV) at 920 °C, oil or polymer quenched, tempered at 170 °C, and finish-ground. The combination of high surface hardness (700–800 HV after grinding) and compressive residual stresses gives the contact fatigue and bending fatigue performance required for 200,000–300,000 km vehicle lifespans. Aerospace applications use deeper-case 9310 Ni-Cr-Mo steel carburized to 1.5–2.5 mm ECD for helicopter gearbox main shaft gears and high-reduction planetary sets operating under extreme Hertzian contact stresses.
Nitriding Applications
Nitrided crankshafts in 38CrMoAl are standard in diesel engines, particularly large marine and industrial engines where the shaft cannot easily be reground and where the fatigue life improvement from the deep compressive stress field is critical. Injection moulding dies in H13 tool steel are plasma nitrided to achieve hard, corrosion-resistant wear surfaces without dimensional change. Thread-rolling dies, form tools, precision extrusion dies, and gear-hobbing cutters are nitrided to extend tool life between regrinds. Low-temperature plasma nitriding of 316L stainless steel medical components produces an expanded austenite layer with very high hardness that improves fretting wear resistance of implant tapers and surgical instrument contact surfaces without compromising biocompatibility.
Carbonitriding Applications
The largest volume application of carbonitriding is shallow-case hardening of small, high-volume automotive fasteners — bolts, studs, and threaded components in 1018–1045 plain carbon steel processed in continuous-belt atmosphere furnaces at 850 °C with 5% NH3 addition, oil quenched, and tempered. Small transmission components (shift forks, pawls, detent plungers), chain link pins and bushings, and small spur gears in low-carbon steel are similarly carbonitrided in basket charges through continuous furnaces, achieving 0.2–0.5 mm ECD in 1–2 hour cycle times unsuitable for full carburizing. The normalised or annealed starting microstructure for carbonitriding should be uniform and fine-grained to maximise carbide dissolution rate during the short thermal cycle.
Frequently Asked Questions
What is the fundamental difference between carburizing and nitriding?
Which process achieves the highest surface hardness?
Which process causes the least distortion?
What steel grades are required for each process?
What is the compound zone (white layer) in nitriding and why does it matter?
How deep is the case produced by each process?
Can carburizing be applied to alloy steels, and can nitriding be applied to plain carbon steels?
What is plasma (ion) nitriding and how does it differ from gas nitriding?
What is carbonitriding and when is it preferred over carburizing?
How does corrosion resistance compare across the three processes?
Recommended Reference Books
ASM Handbook Vol. 4A: Steel Heat Treating Fundamentals and Processes
The definitive reference covering gas carburizing, vacuum carburizing, gas nitriding, plasma nitriding, ferritic nitrocarburizing, and carbonitriding with comprehensive process data tables.
View on AmazonThermochemical Surface Engineering of Steels — Mittemeijer & Somers (Eds.)
A comprehensive academic treatment of all diffusion-based surface hardening processes including the thermodynamic and kinetic fundamentals of carburizing, nitriding, and carbonitriding.
View on AmazonSteel Heat Treatment: Metallurgy and Technologies — Totten
Graduate-level coverage of all steel hardening processes with dedicated chapters on carburizing, nitriding, and carbonitriding including case depth prediction and microstructure interpretation.
View on AmazonNitriding Technology — Lakhtin (MIR Publishers)
The classic monograph on gas and plasma nitriding theory, compound zone control, diffusion zone kinetics, and alloy nitriding steel grades — comprehensive for specialists.
View on AmazonDisclosure: MetallurgyZone participates in the Amazon Associates programme. If you purchase through these links, we may earn a small commission at no extra cost to you. This helps support free technical content on this site.
Further Reading
Martensite Formation in Steel
Shear transformation mechanism, Ms/Mf temperatures, and martensite hardness — the basis of carburizing and carbonitriding case properties.
Iron-Carbon Phase Diagram
Phase fields and transformation temperatures that define the operating regimes of carburizing (austenite field) vs nitriding (ferrite field).
Quenching & Tempering
Conventional hardening — the post-carburizing and post-carbonitriding treatment required to develop the martensitic case microstructure.
Hardness Testing Methods
Microhardness traverses are the standard verification method for case depth and hardness profile in all three case hardening processes.
Grain Boundaries Guide
Grain boundary diffusion paths influence carbon and nitrogen transport kinetics in carburizing and nitriding; prior austenite grain size affects case microstructure.
Annealing & Normalising
Starting microstructure preparation — normalised or pre-treated steel gives more uniform case response in all diffusion hardening processes.
Charpy Impact Testing
Core impact toughness verification — critical for case-hardened components where the tough core provides fatigue crack arrest under cyclic loading.
Corrosion Mechanisms
Corrosion science fundamentals — relevant to nitrided compound zone corrosion resistance and QPQ/ferritic nitrocarburizing applications.