White Cast Iron vs Gray Cast Iron vs Ductile Iron: Microstructure and Properties
Cast irons form a family of iron-carbon-silicon alloys with carbon content between 2 and 4 wt% — above the maximum solubility in austenite and therefore fundamentally distinct in solidification behaviour and microstructure from steels. The three commercially dominant types — white, gray, and ductile (spheroidal graphite) cast iron — differ not in carbon content but in the form in which that carbon exists in the final microstructure: as iron carbide (cementite), as interconnected graphite flakes, or as discrete graphite spheroids. This single structural variable governs the mechanical properties, failure modes, machinability, and application domains of each iron family in ways that no other factor approaches in significance.
- White cast iron solidifies via the metastable Fe-Fe3C eutectic, retaining all carbon as cementite (ledeburite); gray iron solidifies via the stable Fe-C eutectic, precipitating flake graphite. Ductile iron is gray iron composition with magnesium-treated melt producing spheroidal graphite.
- Silicon is the primary graphitiser: raising Si above approximately 1.5 wt% in a 3–4 wt% C iron promotes stable graphite solidification over metastable cementite. Fast cooling and low Si produce white iron; slow cooling and higher Si produce gray iron.
- White iron is extremely hard (600–700 HBW), brittle, and unmachinable; it excels in abrasion resistance. Gray iron has excellent vibration damping, castability, and machinability but near-zero ductility. Ductile iron uniquely combines strength and elongation comparable to medium-carbon steel.
- Graphite flakes in gray iron act as stress raisers and crack initiators, limiting tensile strength to 150–400 MPa with 0% elongation. Spheroidising graphite into nodules (ductile iron) eliminates the stress concentration, enabling elongations of 2–18% and tensile strengths of 400–900 MPa.
- Austempered ductile iron (ADI, ASTM A897) achieves tensile strength of 900–1600 MPa through an ausferrite matrix, directly competing with forged and heat-treated steel at lower cost and density.
- All three iron types can be given the same matrix microstructure (ferritic, pearlitic, or martensitic) by heat treatment; the graphite morphology is fixed at solidification and cannot be changed by subsequent heat treatment.
The Iron-Carbon Phase Diagram and Cast Iron Solidification
Cast irons span compositions from approximately 2.0 to 4.5 wt% C with 1.0 to 3.0 wt% Si, placing them in the hypereutectic or near-eutectic region of the Fe-C-Si system. Solidification behaviour is governed by whether the iron follows the metastable Fe-Fe3C phase diagram or the stable Fe-C (graphite) phase diagram. The two systems have slightly different eutectic temperatures (1147°C for Fe-Fe3C; 1153°C for Fe-C graphite) and eutectic compositions, and both pathways are available depending on cooling rate, silicon content, and inoculation practice.
The full thermodynamic basis for these transformation choices is grounded in the iron-carbon phase diagram. The eutectoid reaction at 727°C in pure Fe-C (shifted to higher temperatures by Si in cast iron) governs the decomposition of austenite to ferrite plus pearlite or ferrite plus graphite during solid-state cooling, determining whether the final matrix is ferritic, pearlitic, or mixed.
Carbon Equivalent (CE) for cast irons: CE = %C + (%Si + %P) / 3 Eutectic CE = 4.3 (for the Fe-C-Si stable system) CE < 4.3: Hypoeutectic iron (primary austenite dendrites form first) CE = 4.3: Eutectic iron (highest fluidity, minimum shrinkage) CE > 4.3: Hypereutectic iron (primary graphite or cementite precipitates first) Typical CE ranges: White iron: CE = 3.0–3.6 (hypoeutectic, metastable solidification) Gray iron: CE = 3.8–4.5 (near-eutectic to slightly hypereutectic) Ductile iron: CE = 4.1–4.6 (near-eutectic to hypereutectic, Mg-treated)
Stability of Graphite vs Cementite
The stability of graphite versus cementite is the central question in cast iron metallurgy. Iron carbide (cementite, Fe3C) is thermodynamically metastable with respect to iron and graphite at all temperatures below approximately 1147°C, but its decomposition rate is negligible at low temperatures. Silicon accelerates cementite decomposition by reducing the activity of carbon in the iron matrix, making it energetically more favourable for carbon to precipitate as graphite. Fast cooling suppresses graphite nucleation kinetics and favours cementite formation, even in silicon-rich compositions — this is why thin sections of gray iron can solidify white (“chilling”).
White Cast Iron: Composition, Microstructure, and Properties
Composition and Solidification
White cast iron is produced when solidification follows the metastable Fe-Fe3C eutectic rather than the stable Fe-graphite eutectic. This is achieved by one or more of: low silicon content (<1.0 wt%), rapid cooling (thin sections, metal moulds), or addition of carbide-stabilising elements (Cr, Mo, V). The eutectic product is ledeburite, a two-phase mixture of austenite (which transforms to pearlite or martensite on further cooling) and cementite. At room temperature, the microstructure consists of pearlite colonies dispersed in a continuous network or plate-like cementite matrix — a microstructure of extreme hardness and brittleness.
| Element | Typical Range (wt%) | Role |
|---|---|---|
| Carbon (C) | 1.8–3.6 | Primary strength donor; forms cementite; lower C in white iron improves toughness |
| Silicon (Si) | 0.5–1.5 | Kept low to prevent graphitisation; Si below ~1.0 promotes white solidification |
| Manganese (Mn) | 0.25–0.80 | Stabilises cementite; counteracts sulphur by forming MnS |
| Chromium (Cr) | 1.4–28 (alloy grades) | Potent carbide stabiliser; forms M7C3 and M23C6 carbides of high hardness; primary alloying element in ASTM A532 abrasion-resistant grades |
| Molybdenum (Mo) | 0.5–3.5 (alloy grades) | Hardenability agent; prevents pearlitic transformation in heavy sections; used with Cr in duplex white irons |
| Nickel (Ni) | 2.7–4.5 (Ni-hard grades) | Increases hardenability; stabilises martensite matrix; used in Ni-Hard grades I–IV |
Mechanical Properties
White cast iron’s defining mechanical characteristic is extreme hardness (500–800 HBW depending on composition) derived from the cementite phase (Vickers hardness approximately 840–1100 HV). This hardness makes white iron effectively unmachinable by conventional cutting — grinding is the only practical material removal method. The high cementite volume fraction simultaneously makes white iron extremely brittle: tensile strength is typically 140–180 MPa, compressive strength 1400–1800 MPa (the high compressive strength being characteristic of cementite-containing microstructures), and impact energy near zero. There is no measurable elongation or reduction in area in tensile testing.
High-Chromium White Irons (ASTM A532)
The commercially important white irons are not plain Fe-C alloys but chromium-alloyed grades per ASTM A532. Chromium additions of 11–35 wt% convert the cementite phase from Fe3C to M7C3 (chromium-rich carbide, hardness 1600–1800 HV), which is harder and more stable than Fe3C and significantly improves wet abrasion resistance. Three classes are defined in A532:
Class I (Ni-Hard): 2.7–4.5 wt% Ni, 1.4–4.0 wt% Cr, 2.4–3.6 wt% C. The Ni promotes martensite matrix transformation; Cr stabilises cementite. Used in pumps, pipe fittings, grinding media.
Class II (Chromium): 7–15 wt% Cr, 2.0–3.3 wt% C, lower Ni. Intermediate abrasion and corrosion resistance. Used in slurry pumps, impellers, and roll surfaces.
Class III (High Chromium): 18–28 wt% Cr, up to 3.5 wt% C. The highest chromium grades with M7C3 primary carbides in a martensitic or austenitic matrix. Used for mill liners, crusher wear parts, and dredge pump components.
Gray Cast Iron: Composition, Microstructure, and Properties
Graphite Morphology: ASTM A247 Classification
ASTM A247 classifies graphite in cast iron by morphology (Types A–E for flakes; Type VI for the true spheroid of ductile iron), distribution, and size (grades 1–8, with 1 being coarsest). For gray iron, the graphite type has a decisive effect on mechanical properties:
| ASTM A247 Type | Morphology | Distribution | Strength Effect | Preferred Application |
|---|---|---|---|---|
| Type A | Randomly oriented flakes | Uniform | Highest (best for gray iron) | General engineering castings, cylinder liners |
| Type B | Rosette clusters | Irregular, inter-rosette carbon regions | Moderate | Tolerable; often from near-eutectic composition |
| Type C | Kish graphite, coarse plates | Uniform (hypereutectic) | Lowest (severe stress concentration) | Avoid in structural castings; present in hypereutectic irons |
| Type D | Dendritic interdendritic flakes | Interdendritic, random orientation | Low–moderate | Associated with rapid cooling; grey iron in thin sections |
| Type E | Interdendritic flakes, preferred orientation | Oriented along thermal gradient | Directionally weak | Avoid; associated with undercooling and poor inoculation |
Matrix Microstructure and Grade
The matrix of gray iron — the phases surrounding the graphite — is controlled by composition and cooling rate and can range from fully ferritic to fully pearlitic. Ferrite provides lower strength but better machinability and thermal shock resistance. Pearlite provides higher strength and hardness. The ASTM A48 class number directly reflects the matrix constitution: Class 20 irons are typically fully ferritic or have a ferritic-pearlitic matrix; Class 60 irons are nearly fully pearlitic with fine interlamellar spacing.
Inoculation — the addition of small amounts of ferrosilicon or calcium-silicon alloy to the melt just before pouring — is essential to producing Type A graphite distribution. Inoculants promote graphite nucleation sites, preventing undercooled graphite types (D and E) and white iron formation in thin sections. The nucleation mechanism relates directly to the grain boundary phenomena described in the Grain Boundaries Guide; inoculant particles (calcium silicate, aluminium oxide inclusions) serve as heterogeneous nucleation sites for graphite.
Mechanical and Physical Properties of Gray Iron
| Property | Class 20 | Class 30 | Class 40 | Class 60 |
|---|---|---|---|---|
| Min. Tensile Strength (MPa / ksi) | 138 / 20 | 207 / 30 | 276 / 40 | 414 / 60 |
| Compressive Strength (MPa, approx.) | 570 | 750 | 965 | 1170 |
| Typical Brinell Hardness (HBW) | 156–179 | 187–241 | 207–255 | 241–300 |
| Elongation (%) | — (essentially 0) | — | — | — |
| Elastic Modulus (GPa) | 66–97 | 90–113 | 110–138 | 131–162 |
| Damping capacity (relative) | Excellent | Very good | Good | Moderate |
| Machinability (relative to Class 30 = 1.0) | 1.2 | 1.0 | 0.8 | 0.5 |
| Matrix (typical) | Ferrite + fine pearlite | Pearlite + ferrite | Predominantly pearlite | Fine pearlite (may require alloy) |
The nonlinear elastic behaviour of gray iron — absent from ductile iron and steel — arises from the opening of graphite flake tips under tensile load, which progresses continuously from the elastic onset, giving a stress-strain curve that has no clear linear portion. Gray iron has no defined yield point; its tensile “strength” is simply the fracture stress. In compression, the graphite flakes cannot open and the iron behaves more like a full matrix material, producing the 3–4× ratio of compressive-to-tensile strength characteristic of the family. This property makes gray iron ideal for bases, beds, and frames of machine tools where compressive loads dominate. The vibration damping capacity of gray iron exceeds that of steel by a factor of 20–25; the graphite flakes dissipate acoustic and vibrational energy by internal friction at the flake-matrix interfaces.
Ductile Cast Iron: Composition, Production, and Microstructure
Magnesium Treatment and Spheroidisation
Ductile iron was invented by Keith Millis at the International Nickel Company in 1943–1948 through the discovery that magnesium additions to molten iron cause graphite to solidify as spheroids rather than flakes. The mechanism of spheroidisation is still not fully settled in the literature, but the dominant model holds that Mg (and Ce) adsorb preferentially onto the prismatic (a-axis) crystal faces of hexagonal graphite, preventing lateral growth and forcing growth in the c-axis direction, producing a sphere rather than a flat plate. Oxygen and sulphur — which naturally adsorb onto basal planes and promote flake growth — must be scavenged to below approximately 0.02 wt% S and 0.02 wt% O before Mg treatment is effective.
Magnesium treatment parameters: Base iron S before treatment: <0.020 wt% (desulphurisation required if higher) Mg addition (as FeSiMg master alloy): 1.0–1.8 wt% of melt weight Residual Mg in iron after treatment: 0.030–0.060 wt% Recovery of Mg from FeSiMg: ~50–70% (Mg loss to slag and vapour) Inoculation after Mg treatment: FeSi75 or Ca-Si inoculant: 0.1–0.3 wt% addition to ladle or stream Purpose: promote graphite nucleation, prevent white iron in thin sections Inoculant fade: nuclei dissolve within 8–12 minutes; pour promptly
Grades and Mechanical Properties: ASTM A536
| ASTM A536 Grade | Min. Tensile (MPa / ksi) | Min. Yield 0.2% (MPa / ksi) | Min. Elongation (%) | Typical HBW | Matrix |
|---|---|---|---|---|---|
| 60-40-18 | 414 / 60 | 276 / 40 | 18 | 140–190 | Fully ferritic |
| 65-45-12 | 448 / 65 | 310 / 45 | 12 | 156–217 | Ferritic + some pearlite |
| 80-55-06 | 552 / 80 | 379 / 55 | 6 | 187–255 | Predominantly pearlitic |
| 100-70-03 | 689 / 100 | 483 / 70 | 3 | 241–302 | Pearlitic or normalised |
| 120-90-02 | 827 / 120 | 621 / 90 | 2 | 269–341 | Q&T martensitic |
The Grade 60-40-18 (fully ferritic) condition is achieved by a full ferritising anneal at 900–955°C, which dissolves pearlite and converts austenite to ferrite during slow cooling, relocating the austenite carbon to the existing graphite nodules. This is a direct application of the annealing and normalising cycles discussed for steel, but at higher temperatures due to silicon raising Ac1 in cast iron. The pearlitic grades (80-55-06, 100-70-03) are produced by normalising or controlled as-cast cooling. The martensitic Grade 120-90-02 requires the full quenching and tempering cycle, producing a tempered martensite matrix around the undissolved graphite nodules.
Nodule Count and Nodularity
The quality of a ductile iron casting is assessed partly through nodularity — the percentage of graphite present as true spheroids (ASTM A247 Type V and VI) versus degenerate forms. A nodularity above 85% is typically required for Grade 60-40-18 and Grade 65-45-12 compliance; lower nodularity produces vermiular or compacted graphite morphologies that significantly reduce ductility. Nodule count (number of nodules per unit area in polished section) should be above 100/mm² for most applications; very low nodule counts indicate insufficient inoculation and risk of chunky graphite formation in heavier sections. The hardness testing methods article covers the Brinell and Vickers methods used for routine quality assurance of ductile iron castings.
Austempered Ductile Iron (ADI)
Austempered ductile iron represents the highest-performance form of cast iron available commercially. The process austenitises a ductile iron casting at 850–950°C to dissolve the pearlite and partially enrich the austenite with carbon from the graphite nodules, then quenches into a salt bath held at 250–400°C (below Ms but above Mf) for isothermal transformation. The resulting ausferrite matrix — a mixture of acicular ferrite and high-carbon retained austenite — provides a unique combination of strength, ductility, and toughness unavailable in any conventionally cooled microstructure.
The bainite microstructure article is directly relevant here: ausferrite is mechanistically related to lower bainite but formed in a system where graphite nodules act as carbon sources and sinks, making the transformation kinetics and microstructure distinct from bainite in steel. The martensite formation article explains why the retained austenite in ADI is stabilised by high carbon content (1.8–2.2 wt% C in the austenite) rather than transforming on cooling to room temperature.
| ASTM A897 Grade | Min. Tensile (MPa) | Min. Yield 0.2% (MPa) | Min. Elongation (%) | Austempering Temp. (°C) | Typical Application |
|---|---|---|---|---|---|
| Grade 1 (900/650/9) | 900 | 600 | 9 | 380–420 | Steering knuckles, agricultural equipment |
| Grade 2 (1050/750/7) | 1050 | 700 | 7 | 340–380 | Gears, crankshafts, camshafts |
| Grade 3 (1200/850/4) | 1200 | 850 | 4 | 300–340 | Heavy gears, mining equipment, crushers |
| Grade 4 (1400/1100/1) | 1400 | 1100 | 1 | 260–300 | Wear parts, ballistic armour, grinding media |
| Grade 5 (1600/1300/<1) | 1600 | 1300 | <1 | 230–260 | Extreme wear applications; near white iron hardness |
Compacted Graphite Iron (CGI)
Between flake graphite (gray iron) and spheroidal graphite (ductile iron) lies compacted graphite iron (CGI, also called vermicular iron), in which graphite forms interconnected worm-like particles intermediate in aspect ratio between flakes and spheroids. CGI is produced by controlling Mg residual to 0.005–0.015 wt% — below the threshold for full spheroidisation. ISO 16112 governs the specification.
CGI has higher tensile strength and stiffness than gray iron (typically 300–450 MPa tensile strength and elastic modulus of 140–165 GPa versus 66–162 GPa for gray iron), retains most of the castability and thermal conductivity advantages of gray iron, and provides modest elongation (1–3%). These characteristics make CGI the preferred material for diesel engine cylinder blocks and heads where the combination of thermal fatigue resistance, high stiffness, and moderate strength required exceeds the capability of gray iron without reaching the cost of ductile iron.
Heat Treatment of Cast Irons
The graphite morphology in any cast iron is fixed permanently at solidification and cannot be altered by heat treatment — flakes remain flakes; spheroids remain spheroids. What heat treatment can change is the matrix microstructure surrounding the graphite.
| Heat Treatment | Temperature (°C) | Cooling | Result | Applicable Iron |
|---|---|---|---|---|
| Stress relief anneal | 500–565 | Slow furnace cool | Residual stress reduction; no microstructural change | All types |
| Ferritising (full) anneal | 900–955 | Slow furnace cool (<50°C/hr) | Fully ferritic matrix; maximum ductility and machinability | Gray iron, ductile iron |
| Normalising | 870–940 | Air cool | Fine pearlite matrix; higher strength than as-cast | Gray iron, ductile iron |
| Quench and temper | 845–925 (austenitise); 150–600 (temper) | Oil or water quench; then temper | Tempered martensite matrix; highest hardness and wear resistance | Ductile iron (primarily) |
| Austempering (ADI) | 850–950 (austenitise); 250–400 (isotherm) | Salt bath quench and hold | Ausferrite (acicular ferrite + retained austenite) | Ductile iron only |
| Surface hardening (induction) | Local surface only | Water spray quench | Martensitic surface case over as-cast or Q&T core | Gray iron (Class 40+), ductile iron |
| Malleabilising (white iron) | 900–970 (Stage 1); 740–760 (Stage 2) | Very slow furnace cool | Decomposes cementite to temper carbon; creates malleable iron | White iron only |
Industrial Applications and Selection Guide
| Application | Preferred Cast Iron Type | Primary Reason |
|---|---|---|
| Machine tool bases, bed plates, frames | Gray iron Class 25–35 | Vibration damping, compressive strength, castability, low cost |
| Engine cylinder blocks and heads | Gray iron Class 30–40 or CGI | Thermal conductivity, damping, castability; CGI for diesel engines |
| Brake discs, drums | Gray iron Class 30–40 | Thermal conductivity, wear resistance, vibration damping |
| Pipes, valves, fittings (pressure service) | Ductile iron Grade 65-45-12 | Pressure containment requiring ductility; replaces gray iron under AWWA C151 |
| Automotive crankshafts, camshafts | Ductile iron Grade 80-55-06 or ADI Grade 2 | Fatigue strength, machinability, cost advantage over forged steel |
| Abrasion-resistant liners, mill balls | White iron ASTM A532 Class III | Cementite/M7C3 carbide hardness; abrasion resistance |
| High-performance gears, suspension | ADI Grade 1–3 (ASTM A897) | Strength and ductility competitive with forged steel; lighter section possible |
| Thin-walled ornamental and plumbing fittings | Malleable iron (ASTM A47) | Complex thin sections; historical use; largely replaced by ductile iron |
For corrosion considerations in cast iron selection — particularly relevant for water pipe, pump, and marine applications — the Corrosion Mechanisms article covers the electrochemical basis of graphitic corrosion in gray iron (selective leaching of iron matrix leaving graphite skeleton) and why ductile iron with its lower free graphite area-to-volume ratio is less susceptible. The Pitting Corrosion article addresses localised attack at graphite-matrix interfaces in aggressive aqueous environments. The Charpy impact test is routinely specified for ductile iron grades used in pressure service to verify adequate toughness at operating temperature.
Frequently Asked Questions
Why does white cast iron look white and gray cast iron look gray on a fracture surface?
What is the role of silicon in cast iron?
How is ductile iron produced from cast iron melt?
What is malleable cast iron and how does it differ from ductile iron?
What causes mottled cast iron?
What is the carbon equivalent of cast iron and why does it matter?
Can cast iron be welded?
What grades of ductile iron are specified in ASTM A536?
What grades of gray cast iron are specified in ASTM A48?
What is austempered ductile iron (ADI)?
Recommended References
Cast Iron: Physical and Engineering Properties — Heine, Loper & Rosenthal
Classic comprehensive reference covering the physical metallurgy, solidification, microstructure, mechanical properties, and production of all cast iron families at graduate level.
View on AmazonDuctile Iron Handbook — AFS / BCIRA
Industry-standard handbook from the American Foundry Society covering ductile iron composition design, Mg treatment practice, heat treatment, grades, and application engineering.
View on AmazonASM Handbook Vol. 1: Properties and Selection — Irons, Steels
Definitive ASM reference covering all cast iron families — gray, white, ductile, malleable, and CGI — with composition ranges, property tables, microstructure descriptions, and application guidance.
View on AmazonMetallurgy of Iron and Steel — Tupperware Baker
Graduate-level materials science text covering ferrous metallurgy from phase diagrams through cast iron, steelmaking, and heat treatment, with strong coverage of graphitisation thermodynamics.
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
Iron-Carbon Phase Diagram
Foundational guide to the Fe-C system equilibria governing solidification choices between graphite and cementite in cast irons.
Eutectoid Reaction
How austenite decomposes to pearlite below A1 and how silicon shifts this reaction in cast iron relative to plain steel.
Pearlite Colony Growth
Interlamellar spacing and colony morphology governing the strength of pearlitic matrices in gray and ductile iron.
Martensite Formation
Martensitic transformation applied to Q&T ductile iron and the retained austenite stabilisation in ADI ausferrite microstructures.
Bainite Microstructure
Bainite and ausferrite transformation mechanics directly relevant to the austempered ductile iron (ADI) heat treatment process.
Annealing and Normalising
Heat treatment cycles for controlling matrix microstructure in ductile and gray cast irons from ferritic anneal to normalising.
Corrosion Mechanisms
Electrochemical corrosion of cast irons including graphitic corrosion of gray iron and comparative behaviour of ductile iron.
Hardness Testing Methods
Brinell, Rockwell, and Vickers methods for quality assurance of cast iron grades from soft ferrite anneal to hard white iron.