Updated July 16, 2026 15 min read Non-Ferrous Metallurgy

Nickel-Based Superalloys: Inconel 625 vs 718 vs Hastelloy Properties

Inconel 625, Inconel 718 and Hastelloy C-276 are the three most commonly specified wrought nickel superalloys outside the turbine-blade class, yet they occupy distinct positions on the strength-corrosion-temperature map. This guide compares their compositions, strengthening mechanisms, mechanical properties, weldability and typical service envelopes to support alloy selection decisions.

Key Takeaways

  • Inconel 625 and Hastelloy C-276 are solid-solution-strengthened via molybdenum, niobium, chromium and tungsten; Inconel 718 is precipitation hardened via gamma double prime (Ni3Nb).
  • Inconel 718 delivers roughly double the yield strength of 625 or C-276 (over 1030 MPa aged versus 415-515 MPa and 355-400 MPa respectively) but loses strength above about 650-700 C.
  • Inconel 625 retains useful strength and oxidation resistance to roughly 980 C for shorter-term exposure, exceeding 718’s practical high-temperature ceiling.
  • Hastelloy C-276’s high molybdenum and tungsten content and ultra-low carbon specification give it the best resistance among the three to reducing acids, pitting and crevice corrosion.
  • 718’s sluggish gamma double prime precipitation kinetics make it one of the most weldable age-hardenable superalloys; high-copper-free 625 is easily welded as a non-heat-treatable alloy.
  • Alloy choice is rarely about raw strength alone: 625 and C-276 are corrosion-driven selections, while 718 is a strength-and-weldability-driven selection for structural components.

Superalloy Selection Advisor

Choose the property that matters most for your application to see the recommended alloy with supporting data.

Strength vs. Service Temperature — Three Nickel Superalloys Maximum practical service temperature (°C) 0.2% Yield Strength (MPa) 400 600 800 1000 300 600 900 1200 Hastelloy C-276 YS ~355-400 MPa Inconel 625 YS ~415-515 MPa Inconel 718 YS ~1030-1170 MPa
Figure 1. Approximate positioning of 0.2% yield strength versus maximum practical service temperature for Inconel 625, Inconel 718 and Hastelloy C-276. © metallurgyzone.com

Composition and Strengthening Mechanism

All three alloys are nickel-based, but they occupy different points in composition space and rely on different strengthening routes. Inconel 625 and Hastelloy C-276 are solid-solution alloys: their strength comes from substitutional alloying elements distorting the nickel lattice and impeding dislocation glide, with no aging response required. Inconel 718 is a precipitation-hardened alloy whose strength depends on a controlled thermal aging cycle following solution treatment, in the same conceptual family as the quench-and-age logic used elsewhere in physical metallurgy, though the precipitate chemistry and kinetics are unique to nickel-niobium systems.

ElementInconel 625 (typical, wt%)Inconel 718 (typical, wt%)Hastelloy C-276 (typical, wt%)
Nickel58.0 min (balance)50.0-55.0Balance (~57)
Chromium20.0-23.017.0-21.014.5-16.5
Molybdenum8.0-10.02.80-3.3015.0-17.0
Niobium (+Ta)3.15-4.154.75-5.50
Iron5.0 maxBalance (~17-18)4.0-7.0
Tungsten3.0-4.5
Titanium0.4 max0.65-1.15
Aluminium0.4 max0.20-0.80
Carbon0.10 max0.08 max0.01 max
Strengthening phaseSolid solution (Mo, Nb)Gamma double prime (Ni3Nb, body-centred tetragonal)Solid solution (Mo, W)

Inconel 625

Inconel 625 derives its strength primarily from molybdenum and niobium in solid solution within the nickel-chromium matrix, supplemented by minor carbide and, in some conditions, small amounts of Ni3Nb. It is used almost exclusively in the mill-annealed condition; extended thermal exposure between roughly 550 C and 980 C instead promotes formation of delta phase, Laves phase and grain boundary carbides that reduce ductility and toughness rather than provide useful strengthening, so the alloy is deliberately not aged in service.

Inconel 718

Inconel 718 is strengthened by a fine, coherent dispersion of gamma double prime (Ni3Nb), a metastable body-centred tetragonal phase, with a smaller contribution from gamma prime (Ni3(Al,Ti)). The defining metallurgical feature of 718 is the sluggish nucleation and growth kinetics of gamma double prime relative to the gamma prime that strengthens most other superalloys — this slow response is what makes 718 weldable without the strain-age cracking that limits fusion welding of faster-aging alloys.

Hastelloy C-276

Hastelloy C-276 relies on molybdenum and tungsten in solid solution for strength, with chromium providing oxidation and general corrosion resistance. Its defining feature is an extremely low carbon ceiling (0.01% maximum), developed specifically to suppress the grain-boundary carbide precipitation that sensitized the original Hastelloy C alloy during welding, a mechanism closely related to the intergranular corrosion mechanisms seen in sensitized austenitic stainless steels.

Mechanical Properties Comparison

PropertyInconel 625 (annealed)Inconel 718 (solution treated + aged)Hastelloy C-276 (annealed)
Ultimate tensile strength830-1035 MPa1240-1450 MPa690-895 MPa
0.2% yield strength415-515 MPa1030-1170 MPa355-400 MPa
Elongation at break30-60%12-20%40-60%
Max practical service temperature~980 C (short-term, oxidation-limited)~650-700 C (strength-limited)~550 C (structural); higher in corrosive service
Density8.44 g/cm38.19 g/cm38.89 g/cm3

Strength ceiling versus temperature is not linear

Inconel 718’s high room-temperature strength does not carry through to elevated temperature. Above roughly 650 C, gamma double prime begins to coarsen and revert toward equilibrium delta phase, causing a comparatively sharp loss of strength. This is why 718 dominates the cooler rear stages and static structure of a jet engine, while hotter rotating sections use gamma-prime-strengthened alloys with better high-temperature microstructural stability.

Weldability and Corrosion Resistance

Weldability

Inconel 625, being solid-solution strengthened, welds readily with matching filler metal and requires no post-weld heat treatment to restore base metal properties. Inconel 718 is unusual among precipitation-hardened superalloys in also being highly weldable, specifically because of the slow gamma double prime precipitation kinetics described above; most fabricators still recommend a post-weld solution and age cycle to restore full design strength across the weld and heat-affected zone. Hastelloy C-276 is weldable with low heat input and matching or slightly overalloyed filler, but excessive heat input or multiple reheats can precipitate intermetallic mu and P phases in the heat-affected zone, locally reducing corrosion resistance even though the ultra-low carbon prevents classical sensitization.

Corrosion Resistance

Hastelloy C-276 leads the group in resistance to reducing environments such as hydrochloric acid, wet chlorine and mixed oxidizing-reducing acid streams, owing to its high combined molybdenum and tungsten content. Inconel 625 offers excellent resistance to seawater, marine chloride environments and moderately oxidizing media, making it the standard choice for subsea flexible risers, umbilicals and marine hardware, an application area closely tied to pitting corrosion resistance under chloride attack. Inconel 718’s corrosion resistance is good but secondary to its role as a structural, strength-driven alloy; it is not typically the first choice purely for aggressive chemical service.

Approximate pitting resistance equivalent number (PREN):

  PREN = %Cr + 3.3 x (%Mo + 0.5 x %W) + 16 x %N

  Inconel 625  (Cr 21.5, Mo 9,  W 0):    PREN ≈ 21.5 + 3.3(9)      ≈ 51
  Hastelloy C-276 (Cr 15.5, Mo 16, W 3.7): PREN ≈ 15.5 + 3.3(16+1.85) ≈ 74
  Inconel 718  (Cr 19, Mo 3, W 0):       PREN ≈ 19 + 3.3(3)       ≈ 29
PREN is a nitrogen-free approximation commonly applied to nickel alloys by analogy with stainless steel practice; it ranks relative pitting/crevice resistance but does not replace environment-specific corrosion testing per ASTM G48 or NACE methods.

Typical Applications

AlloyRepresentative applications
Inconel 625Subsea flexible risers and umbilicals, chemical process piping, aircraft exhaust and ducting, cryogenic tankage, nuclear fuel reprocessing components
Inconel 718Gas turbine discs and casings (cooler stages), aerospace fasteners, downhole oil and gas tooling, cryogenic and pressure vessel bolting
Hastelloy C-276Flue gas desulfurization scrubbers, chemical reactors and piping handling wet chlorine or mixed acids, pulp and paper bleach plant equipment, pollution control hardware

Selection Logic

Treat these three alloys as answers to different questions rather than direct substitutes. If the governing requirement is aggressive chemical corrosion resistance, start with Hastelloy C-276 and only step down to 625 if cost or availability dictates. If the governing requirement is high strength with reasonable corrosion resistance and good weldability at moderate temperature, 718 is the default. If the requirement spans high-temperature oxidation resistance with good but not extreme corrosion resistance and easy fabrication, 625 covers the widest envelope of the three.

Frequently Asked Questions

What is the main difference between Inconel 625 and Inconel 718?
Inconel 625 is a solid-solution-strengthened nickel-chromium-molybdenum alloy used mainly in the mill-annealed condition, offering excellent corrosion resistance and useful strength up to about 980 C. Inconel 718 is precipitation hardened by gamma double prime (Ni3Nb) precipitates formed during a two-step aging treatment, giving much higher room-temperature strength (yield strength above 1030 MPa) but a lower practical service temperature ceiling of roughly 650 to 700 C.
Why is Inconel 718 considered highly weldable compared to other superalloys?
Inconel 718 owes its weldability to the sluggish precipitation kinetics of its strengthening phase, gamma double prime (Ni3Nb). Because this phase forms slowly, the heat-affected zone does not rapidly age and embrittle during weld cooling or post-weld heat treatment, avoiding the strain-age cracking that afflicts faster-aging gamma-prime alloys such as Waspaloy or Rene 41.
What makes Hastelloy C-276 more corrosion resistant than Inconel 625?
Hastelloy C-276 carries a higher molybdenum content (15 to 17 percent versus roughly 8 to 10 percent in Inconel 625) combined with tungsten additions and an extremely low carbon content. The higher molybdenum and tungsten levels improve resistance to reducing acids and localized pitting and crevice attack, while the low carbon minimizes carbide precipitation at grain boundaries that would otherwise sensitize the alloy during welding or thermal exposure.
Can Inconel 625 be precipitation hardened like Inconel 718?
Inconel 625 has limited precipitation hardening capability through Ni3Nb formation, but it is not used this way in practice. Extended exposure in the 550 to 980 C range instead promotes formation of delta phase, Laves phase and various carbides, which reduce ductility and toughness rather than provide useful strengthening. Inconel 625 is therefore almost always supplied and used in the solution-annealed condition.
What is the aging treatment for Inconel 718?
Standard practice solution anneals Inconel 718 at approximately 954 to 1010 C, followed by a two-step age: 8 hours at about 720 C, furnace cooled at roughly 55 C per hour to 620 C, held at 620 C for a total aging time of 18 hours, then air cooled. This sequence precipitates a controlled distribution of gamma double prime, with minor gamma prime, to reach specified strength levels per AMS 5662 and AMS 5663.
Which alloy should be used for high-temperature service above 700 C?
Inconel 625 is generally preferred over Inconel 718 above roughly 650 to 700 C because Inconel 718’s gamma double prime strengthening phase coarsens and reverts at elevated temperature, causing a sharp strength drop. Inconel 625 retains useful strength and oxidation resistance up to about 980 C for shorter-term exposure, though for continuous long-term high-temperature structural service, gamma-prime-strengthened alloys such as Inconel 617 or Waspaloy may outperform both.
Is Hastelloy the same as Inconel?
No. Both are nickel-based alloy families but from different producers and compositional systems. Inconel, a Special Metals Corporation trademark, spans a range of nickel-chromium alloys including solid-solution grades like 625 and precipitation-hardened grades like 718. Hastelloy, a Haynes International trademark, spans nickel-molybdenum-chromium alloys such as C-276 and C-22 developed primarily for aggressive chemical corrosion resistance rather than high mechanical strength.
Why does Hastelloy C-276 have such a low carbon specification?
The original Hastelloy C alloy was prone to sensitization: chromium carbides precipitated at grain boundaries during welding, depleting adjacent chromium and molybdenum and creating a corrosion-susceptible zone. Hastelloy C-276 was developed with carbon held below about 0.01 percent specifically to suppress this carbide precipitation, preserving corrosion resistance in and around weld heat-affected zones without requiring post-weld solution annealing.
What fraction of a jet engine by weight is typically Inconel 718?
Inconel 718 is often cited as making up roughly a third to half of the total superalloy weight in a modern jet engine, used for turbine discs, casings, shafts and fasteners in the cooler rear stages and static structure. Its combination of high strength, good fatigue and fracture toughness, weldability and lower cost relative to single-crystal superalloys explains its dominant tonnage share despite a lower maximum service temperature than blade alloys.
How do the strengthening mechanisms of 625, 718 and Hastelloy C-276 compare?
Inconel 625 and Hastelloy C-276 are both solid-solution-strengthened, relying on molybdenum, niobium, chromium and tungsten atoms distorting the nickel lattice to impede dislocation motion, with no aging treatment required. Inconel 718 is precipitation hardened, relying on a controlled two-step age to nucleate coherent, metastable gamma double prime (Ni3Nb) precipitates that provide a substantially larger strengthening increment than solid solution effects alone.

Reference Reading

Reed, The Superalloys: Fundamentals and Applications

The standard graduate reference on nickel superalloy physical metallurgy, precipitation strengthening and microstructural stability.

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ASM Handbook Vol. 2: Properties and Selection — Nonferrous Alloys

Comprehensive composition, property and selection data for Inconel, Hastelloy and other nickel alloy families.

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Donachie & Donachie, Superalloys: A Technical Guide

A practitioner-focused guide covering superalloy metallurgy, processing, welding and failure modes.

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Davis (ed.), Corrosion of Nickel and Nickel Alloys (ASM Specialty Handbook)

Focused reference on corrosion behaviour and environment-specific performance of nickel alloy systems including Hastelloy grades.

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