Titanium Alloys: Grade 1 to Grade 5 (Ti-6Al-4V) Properties and Applications
Titanium alloys span from unalloyed, single-phase alpha grades used for their outstanding corrosion resistance to the two-phase alpha-beta workhorse Ti-6Al-4V (Grade 5), which accounts for the majority of titanium mill product consumed globally. This article covers the ASTM grade system for commercially pure and alloyed titanium, the alpha-beta phase transformation that underpins heat treatment response, and the property trade-offs that drive material selection across aerospace, chemical processing, and biomedical applications.
Key Takeaways
- Grades 1-4 are commercially pure (unalloyed) titanium, differing mainly in oxygen and iron interstitial content, which controls a strength range from about 240 MPa (Grade 1) to 550 MPa (Grade 4) tensile strength with no heat-treatable phases.
- Grade 5 (Ti-6Al-4V) is an alpha-beta alloy containing 6 wt% Al (an alpha stabiliser) and 4 wt% V (a beta stabiliser), enabling solution treatment and ageing for tensile strengths of 900-1100 MPa.
- The beta transus of Ti-6Al-4V is approximately 995°C; processing and heat treatment temperature relative to this transus controls whether the microstructure is lamellar, equiaxed, or bimodal.
- All titanium grades derive their corrosion resistance from a stable, self-healing TiO2 passive film, largely independent of alloy content, giving excellent resistance to seawater, chlorides, and oxidising acids.
- Titanium alloys offer the best strength-to-weight ratio among common structural metals but require strict shielding during welding and heat treatment due to high-temperature reactivity with oxygen, nitrogen, and hydrogen.
- Grade selection is driven by the strength/corrosion trade-off: pure grades for maximum corrosion resistance and formability, Grade 5 and its variants for structural strength and elevated-temperature service.
ASTM Grade System for Titanium
ASTM B265 (sheet/plate) and related specifications assign sequential grade numbers to titanium chemistries. Grades 1-4 are unalloyed, commercially pure (CP) titanium distinguished only by controlled maximum limits on oxygen, iron, carbon, nitrogen, and hydrogen — interstitial elements that raise strength but reduce ductility and impact toughness. Grade 5, Ti-6Al-4V, is the most common alloyed grade. Grade 7 adds a small palladium addition (0.12-0.25 wt%) to Grade 2 for enhanced crevice corrosion resistance in reducing acid environments, and Grade 23 is an extra-low-interstitial (ELI) version of Grade 5 used for critical fatigue and biomedical applications.
| Grade | Type | Nominal Composition | Min. Tensile Strength | Typical Use |
|---|---|---|---|---|
| Grade 1 | CP-Ti, lowest strength | O ≤ 0.18, Fe ≤ 0.20 | 240 MPa | Deep-drawn chemical processing components |
| Grade 2 | CP-Ti, general purpose | O ≤ 0.25, Fe ≤ 0.30 | 345 MPa | Piping, heat exchangers, marine hardware |
| Grade 3 | CP-Ti, higher strength | O ≤ 0.35, Fe ≤ 0.30 | 450 MPa | Aerospace ducting, pressure vessels |
| Grade 4 | CP-Ti, highest strength | O ≤ 0.40, Fe ≤ 0.50 | 550 MPa | Airframe fittings, surgical instruments |
| Grade 5 | Alpha-beta alloy | 6 Al, 4 V | 900 MPa | Airframes, jet engine components, implants |
| Grade 7 | CP-Ti + Pd | 0.15 Pd (bal. as Gr.2) | 345 MPa | Reducing-acid chemical process equipment |
| Grade 23 | Alpha-beta, ELI | 6 Al, 4 V, low O/Fe | 830 MPa | Fatigue-critical and biomedical implants |
Phase Structure and Alloy Classification
Alpha and Near-Alpha Alloys
Pure titanium transforms from the room-temperature hexagonal close-packed (HCP) alpha phase to the body-centred cubic (BCC) beta phase at 882°C. Aluminium, oxygen, nitrogen, and carbon are alpha stabilisers that raise this transus; Grades 1-4 remain single-phase alpha at all practical service temperatures, which gives them excellent weldability (no transformation-hardening response) and good creep resistance, but no mechanism for heat-treatable strengthening beyond interstitial and cold-work hardening.
Alpha-Beta Alloys
Vanadium, molybdenum, chromium, and iron are beta stabilisers that lower the transus and allow a controlled fraction of beta phase to be retained at room temperature. Ti-6Al-4V balances 6 wt% Al (alpha stabiliser, solid-solution strengthening of the alpha phase) against 4 wt% V (beta stabiliser, retaining 10-20 vol% beta at room temperature in the mill-annealed condition). This two-phase structure is heat-treatable: solution treating in the alpha-beta field followed by ageing produces a fine, controlled microstructure with a much better strength-ductility combination than either single-phase alpha or fully beta alloys.
Beta Alloys
Alloys with sufficient beta-stabiliser content (e.g., Ti-10V-2Fe-3Al, Ti-15V-3Cr-3Sn-3Al) can be quenched to a fully metastable beta structure and subsequently aged to precipitate fine alpha, achieving very high strength (up to 1300 MPa) at the cost of higher density and generally lower ductility than Grade 5.
Related: Phase Transformation Fundamentals
The alpha-beta transformation in titanium is conceptually analogous to the austenite-to-ferrite transformation discussed in our iron-carbon phase diagram guide, though titanium’s HCP-to-BCC transformation and alloying response differ substantially from steel’s FCC-to-BCC/BCT behaviour.
Mechanical Properties Comparison
| Property | Grade 2 (annealed) | Grade 4 (annealed) | Grade 5 (STA) |
|---|---|---|---|
| Tensile strength | 345-480 MPa | 550-680 MPa | 900-1100 MPa |
| Yield strength (0.2%) | 275 MPa | 480 MPa | 830 MPa |
| Elongation | 20-25% | 15% | 10-14% |
| Elastic modulus | 103 GPa | 104 GPa | 114 GPa |
| Density | 4.51 g/cm3 | 4.51 g/cm3 | 4.43 g/cm3 |
| Max continuous service temp. | 315°C | 315°C | 315-350°C |
STA denotes solution-treated-and-aged condition. Note the substantial strength gain from Grade 2 to Grade 5 with only a modest ductility penalty — this favourable strength-ductility balance, combined with a lower density than steel or nickel alloys, is the central reason Ti-6Al-4V dominates weight-critical structural applications, alongside considerations discussed in our hardness testing methods guide for QC verification of heat-treated response.
Heat Treatment of Ti-6Al-4V
Mill-annealed Ti-6Al-4V is typically annealed at 700-845°C (well below the 995°C beta transus) followed by air cooling, producing an equiaxed alpha-beta structure with good ductility and fatigue resistance. Solution treating and ageing (STA) involves heating to 955-970°C (just below the transus), water quenching to retain metastable beta and produce fine acicular alpha, then ageing at 480-595°C to precipitate additional fine alpha from the retained beta, raising strength significantly above the annealed condition.
Processing above the beta transus (beta annealing or beta forging) produces a coarser lamellar (Widmanstatten-like) structure with superior fracture toughness and crack-growth resistance but lower ductility and fatigue strength than the equiaxed or bimodal structures obtained by processing in the alpha-beta field — an important trade-off for fatigue-critical versus damage-tolerant aerospace design.
Approximate beta transus shift with common alloying additions (first-order guide only): T_beta(alloy) ≈ T_beta(pure Ti, 882°C) + Σ(k_i × wt%_i) where k_i is positive for alpha stabilisers (Al, O, N) and negative for beta stabilisers (V, Mo, Fe, Cr). For Ti-6Al-4V, the combined effect raises the transus to approximately 995°C.
Corrosion Resistance
All titanium grades, regardless of alloy content, owe their corrosion resistance to a thin (2-6 nm), extremely adherent, self-healing TiO2 passive film that forms instantly on exposure to air or moisture. This film gives titanium outstanding resistance to seawater, chloride solutions, wet chlorine, nitric acid, and most oxidising media, generally exceeding that of stainless steels and comparable to that of the most highly alloyed nickel superalloys in chloride service — a corrosion mechanism entirely distinct from the mechanisms discussed in our corrosion mechanisms and pitting corrosion guides for iron-based alloys.
Titanium is not resistant to reducing, non-oxidising acids such as hydrochloric or concentrated sulfuric acid, where the passive film cannot be maintained; Grade 7’s palladium addition specifically improves performance in these reducing environments by shifting the corrosion potential into the passive region.
Fabrication: Welding and Machining
Welding
Titanium is predominantly welded by GTAW (with GMAW and laser/electron beam welding also used for production) with high-purity argon or helium shielding. Because titanium reacts readily with oxygen, nitrogen, and hydrogen above roughly 350°C, the weld pool, hot heat-affected zone (comparable in concept to the HAZ microstructure considerations in ferrous welding), and the joint underside must all be shielded with trailing shields and backing gas until the metal cools below this threshold. Weld colour is a practical quality indicator: bright silver indicates adequate shielding, while straw, blue, or grey-white oxide colours indicate progressively worse contamination and embrittlement, and heavy contamination can promote hydrogen-related cracking mechanisms analogous to those seen in steel weldments.
Machining
Titanium’s low thermal conductivity concentrates cutting heat at the tool edge, and its high strength-to-modulus ratio causes tool deflection and chatter, so machining requires sharp tooling, positive rake angles, low cutting speeds relative to steel, and generous coolant flow to control temperature and prevent alpha-case formation or work hardening of the machined surface.
Industrial Applications
| Grade/Alloy | Typical Applications |
|---|---|
| Grade 1-2 | Chemical process piping, desalination plant components, marine heat exchangers |
| Grade 3-4 | Aerospace ducting, cryogenic pressure vessels, surgical instruments |
| Grade 5 (Ti-6Al-4V) | Airframe structural members, jet engine compressor blades and discs, fasteners |
| Grade 7 | Chemical process equipment in reducing acid or high-chloride service |
| Grade 23 (ELI) | Orthopaedic and dental implants, fatigue-critical airframe components |
Frequently Asked Questions
What is the difference between titanium Grade 2 and Grade 5?
Why is Ti-6Al-4V called Grade 5?
What is the alpha-beta transus temperature of Ti-6Al-4V?
Can commercially pure titanium be heat treated to increase strength?
Why does Ti-6Al-4V have excellent corrosion resistance despite containing vanadium?
What is the difference between alpha, near-alpha, alpha-beta, and beta titanium alloys?
Is Ti-6Al-4V biocompatible?
How is titanium welded and what precautions are needed?
What is the maximum service temperature for Ti-6Al-4V?
What causes alpha case in titanium and how is it prevented?
Recommended Reference Materials
Titanium and Titanium Alloys: Fundamentals and Applications
Comprehensive reference covering phase transformations, alloy design, and processing of commercial titanium grades.
View on AmazonASM Handbook, Volume 2: Properties and Selection of Nonferrous Alloys
Authoritative property data and metallurgical background for titanium and other non-ferrous alloy systems.
View on AmazonWelding Metallurgy and Weldability of Titanium Alloys
Focused reference on shielding practice, weld defects, and microstructural response in titanium welding.
View on AmazonCallister’s Materials Science and Engineering
Foundational textbook covering phase diagrams, strengthening mechanisms, and corrosion principles applicable to titanium alloys.
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