Updated: 14 July 2026 Reading time: 14 min Non-Ferrous Metallurgy

Copper Alloys: Brass vs Bronze vs Cupronickel — Composition and Properties

Brass, bronze, and cupronickel are the three dominant families of wrought and cast copper alloys, distinguished by their principal alloying element — zinc, tin, and nickel respectively — and each optimised for a different combination of strength, machinability, and corrosion resistance. This article compares their composition ranges, phase structures, mechanical and physical properties, and corrosion behaviour, and identifies the selection criteria engineers use to specify each family for plumbing, marine, electrical, and bearing applications.

Key Takeaways

  • Brass (Cu-Zn) is defined by an alpha (FCC) single-phase field up to about 35-37 wt% Zn, and an alpha+beta or beta (BCC) structure above that, which governs whether an alloy is cold-workable or must be hot-worked.
  • Bronze historically means Cu-Sn, but the term is now applied broadly to non-zinc copper alloys including aluminium bronze, silicon bronze, and phosphor bronze, each with distinct strengthening mechanisms.
  • Cupronickel (Cu-Ni) alloys, chiefly the 90-10 and 70-30 grades, form a complete solid solution across all compositions and derive their exceptional seawater corrosion resistance from nickel-stabilised passive oxide films.
  • Brass offers the best machinability and electrical/thermal conductivity of the three families; cupronickel offers the best seawater and biofouling resistance; bronze sits between them with superior wear resistance and bearing performance.
  • Dezincification is the dominant failure mode specific to high-zinc brasses and is controlled with arsenic, antimony, or phosphorus inhibitors or by selecting low-zinc grades.
  • Selection between the three families is driven primarily by the service environment (freshwater vs seawater vs atmosphere), required conductivity, and fabrication route (machining, cold forming, casting, or welding).
Zinc Content (wt% Zn) Temperature (°C) 0 20 37 45 1085 room alpha (FCC) soft, ductile, cold-workable alpha+beta beta (BCC) harder, hot-worked Cartridge brass (70/30) Muntz metal (60/40) ~here
Simplified Cu-Zn phase diagram highlighting the alpha, alpha+beta, and beta brass fields that determine cold-workability. © metallurgyzone.com

Composition Ranges of the Three Alloy Families

Each family is a solid-solution-strengthened copper alloy, but the solute element controls a very different phase behaviour and property set.

Brass (Cu-Zn system)

Wrought brasses range from about 5 wt% Zn (gilding metal, used for coinage and ammunition cartridge cases) up to 40 wt% Zn (Muntz metal, a hot-working alloy). Cartridge brass at roughly 30 wt% Zn is the classic deep-drawing composition. Free-machining grades such as C36000 add 2-3 wt% Pb. Naval brass and admiralty brass add small tin additions (0.75-1.0 wt%) specifically to suppress dezincification corrosion.

Bronze (Cu-Sn and related systems)

True tin bronzes range from about 4 to 12 wt% Sn for wrought grades and up to 20 wt% Sn for high-leaded or bearing bronzes. Phosphor bronzes (C51000, C52100) add 0.03-0.35 wt% P as a deoxidiser and minor strengthener. The modern commercial usage of “bronze” also covers aluminium bronze (Cu with 5-13 wt% Al, often with Fe and Ni additions), silicon bronze (Cu with 1-3 wt% Si), and manganese bronze — none of which contain tin as the principal solute.

Cupronickel (Cu-Ni system)

Commercial cupronickels are dominated by two grades: 90-10 (C70600, nominally 88.6 wt% Cu, 10 wt% Ni, 1.4 wt% Fe/Mn) and 70-30 (C71500, nominally 68.7 wt% Cu, 30 wt% Ni, 0.8 wt% Fe/Mn). Iron and manganese additions in the 1-2 wt% range are critical — they refine grain size and dramatically improve resistance to erosion-corrosion in flowing seawater.

AlloyUNSNominal CompositionPrimary Strengthening
Cartridge brassC2600070 Cu, 30 ZnSolid solution (alpha)
Naval brassC4640060 Cu, 39.2 Zn, 0.75 SnAlpha+beta, Sn inhibits dezinc.
Free-cutting brassC3600061.5 Cu, 35.5 Zn, 3 PbAlpha+beta + Pb inclusions
Phosphor bronzeC5100094.8 Cu, 5 Sn, 0.2 PSolid solution + fine oxide
Aluminium bronzeC6300082 Cu, 10 Al, 5 Ni, 3 FeSolid solution + precipitation
90-10 cupronickelC7060088.6 Cu, 10 Ni, 1.4 Fe/MnComplete solid solution
70-30 cupronickelC7150068.7 Cu, 30 Ni, 0.8 Fe/MnComplete solid solution

Phase Structure and Microstructural Control

The Cu-Zn system exhibits a copper-rich alpha (FCC) terminal solid solution stable up to roughly 35-37 wt% Zn at room temperature, above which the ordered beta phase (BCC, based on the CuZn intermetallic) appears. Alpha brass is soft and highly ductile — ideal for deep drawing, cold heading, and tube forming. Above the alpha/beta boundary, alloys such as Muntz metal must generally be hot-worked, since the beta phase has an order-disorder transformation near 460°C and limited cold ductility below it.

The Cu-Sn system is far more complex, with several intermediate phases (beta, gamma, delta, epsilon), but commercial wrought tin bronzes are kept within the copper-rich alpha field, avoiding the brittle delta phase that would otherwise form on slow cooling of higher-tin compositions — this is why cast tin bronzes with high Sn content rely on non-equilibrium, coring-retained microstructures rather than full equilibrium phase distribution.

Cu-Ni forms a complete, isomorphous solid solution across the entire composition range with no intermediate phases — copper and nickel share the same FCC crystal structure and similar atomic radii, satisfying the Hume-Rothery rules for complete solubility. This is why cupronickel microstructures are simple single-phase equiaxed grains regardless of composition, and strengthening is achieved almost entirely through solid-solution hardening and cold work rather than phase transformation.

Related: Solid Solution Strengthening Fundamentals

The Hume-Rothery rules governing complete solubility in Cu-Ni parallel the substitutional solid-solution behaviour discussed in our iron-carbon phase diagram guide, where interstitial rather than substitutional solubility dominates.

Mechanical Properties Comparison

Property (annealed)Brass (C26000)Phosphor Bronze (C51000)Cupronickel (C71500)
Tensile strength340 MPa350 MPa380 MPa
Yield strength (0.2%)105 MPa130 MPa140 MPa
Elongation65%48%40%
Elastic modulus110 GPa110 GPa150 GPa
Electrical conductivity (%IACS)28154.6
Thermal conductivity (W/m·K)1206229

Cold work increases strength substantially in all three families through dislocation multiplication and pile-up at grain boundaries, but the achievable strength-ductility trade-off differs: cupronickels retain useful ductility at high hardness levels because nickel raises stacking-fault energy only moderately, while heavily cold-worked brass becomes susceptible to grain boundary stress-corrosion cracking (season cracking) if residual stresses are not relieved.

Corrosion Behaviour

Brass — Dezincification

High-zinc alpha-beta brasses are susceptible to dezincification, a selective dissolution mechanism in which zinc is preferentially leached, leaving a weak, porous, copper-rich residue with negligible mechanical strength. Stagnant, low-velocity, chloride-bearing, or slightly acidic waters accelerate the attack. Inhibited brasses add 0.02-0.10 wt% arsenic, antimony, or phosphorus, which form a protective layer that suppresses the selective dissolution.

Bronze — General and Wear-Related Corrosion

Tin bronzes form a stable, adherent cuprous oxide/stannic oxide film and generally outperform brass in seawater and atmospheric exposure, with tin bronze statuary surviving for centuries via a protective patina. Aluminium bronzes develop a highly protective alumina-enriched film and are used for pump and valve bodies in aggressive brines, though they require careful heat treatment to avoid selective phase corrosion of any retained gamma-2 phase.

Cupronickel — Seawater and Biofouling Resistance

Cupronickel’s outstanding seawater performance stems from a thin, tenacious, nickel-stabilised oxide film that resists erosion-corrosion even at flow velocities up to 3-4 m/s for 90-10 grade, and it strongly suppresses marine biofouling by releasing a low, steady flux of cuprous ions toxic to settling organisms. This combination makes cupronickel the default choice for seawater piping, condenser tubing, and ship hull sheathing.

Relative Performance Comparison (qualitative, 0-10 scale) Brass Bronze Cupronickel Machinability Seawater corrosion resistance
Qualitative comparison of machinability versus seawater corrosion resistance across the three copper alloy families. © metallurgyzone.com

Fabrication and Application Selection

Machining and Forming

Leaded free-cutting brass (C36000) is the machinability benchmark against which all other alloys are rated (100% machinability rating). Bronzes machine less freely due to higher tensile strength and work-hardening tendency, especially the higher-strength aluminium and silicon bronzes. Cupronickel is the most difficult to machine of the three, being gummy and prone to built-up edge, and typically requires sharp, positive-rake tooling and generous coolant.

Welding and Joining

Silicon and aluminium bronzes weld well by GTAW/GMAW with matched filler. Tin bronzes are prone to hot cracking from their wide freezing range and are more commonly brazed or cast net-shape. Cupronickel welds readily with matching Cu-Ni filler and is the standard choice for shipboard seawater piping systems where field welding is required, referencing procedures analogous to those in our HAZ microstructure guide for dissimilar-metal transition joints.

Approximate copper equivalent (informal weldability screening, Cu-Zn system):
Cu_eq (wt%) = %Cu + 0.5(%Sn) + 0.3(%Ni)  — used only as a rough solidification-range indicator,
not a substitute for full CCT/solidification-mode analysis.

Industrial Applications Summary

Alloy FamilyTypical Applications
BrassPlumbing fittings, ammunition cases, musical instruments, decorative hardware, electrical connectors
BronzeBearings and bushings, gears, marine propellers, springs, sculpture, pump/valve bodies
CupronickelSeawater piping, condenser and heat-exchanger tubing, ship hull sheathing, coinage

Frequently Asked Questions

What is the main difference between brass and bronze?
Brass is a copper-zinc alloy, while bronze is traditionally a copper-tin alloy, though the term now covers other copper alloys such as aluminium bronze and silicon bronze that do not contain tin. Brass is generally more machinable and less expensive; bronze offers better corrosion resistance in marine and wear applications and better performance at elevated temperature.
Is cupronickel stronger than brass?
In the annealed condition, cupronickel alloys such as C70600 (90-10) and C71500 (70-30) typically have lower tensile strength than free-machining brasses, but they gain considerable strength from cold working and offer far superior resistance to seawater corrosion and biofouling, which is why they dominate marine piping applications rather than brass.
Why does brass contain lead?
Lead is added in small amounts, typically 0.5-3.5 wt%, to free-machining brasses such as C36000 because it is insoluble in the copper-zinc matrix and forms soft globules that act as internal chip breakers during machining, dramatically improving tool life and surface finish. Lead-free brasses use bismuth or selenium as substitutes to meet drinking-water regulations.
What is alpha brass and beta brass?
Alpha brass is the copper-rich face-centred cubic solid solution phase stable up to roughly 35-37 wt% zinc, and it is soft, highly ductile, and cold-workable. Beta brass is a body-centred cubic ordered phase that forms above about 37 wt% zinc, and it is harder and stronger but must generally be hot-worked because it has limited cold ductility below the order-disorder transition temperature.
Which copper alloy resists seawater corrosion best?
Cupronickel alloys, particularly the 90-10 (C70600) and 70-30 (C71500) grades, provide the best general seawater corrosion resistance among common copper alloys because the nickel addition stabilises a thin, adherent, protective oxide film and the alloys are highly resistant to biofouling and impingement attack in flowing seawater.
What causes dezincification in brass?
Dezincification is a selective corrosion mechanism in which zinc is preferentially leached from the alloy, leaving behind a porous, mechanically weak copper-rich layer. It is most severe in high-zinc alpha-beta brasses exposed to stagnant, chloride-containing, or acidic waters, and it is mitigated by adding small amounts of arsenic, antimony, or phosphorus as inhibitors, or by specifying low-zinc or inhibited brass grades.
Can bronze be welded?
Most bronzes can be welded, but weldability varies by type. Silicon bronzes and aluminium bronzes weld well with GTAW or GMAW using matching filler metal. Tin bronzes are more prone to hot cracking due to a wide freezing range and are often preferred for brazing or casting rather than fusion welding of thick sections.
What is the typical composition of naval brass?
Naval brass (C46400) typically contains about 60 wt% copper, 39.2 wt% zinc, and 0.75 wt% tin, with the tin addition suppressing dezincification and improving corrosion resistance in seawater relative to plain 60-40 brass, making it a common choice for marine hardware and condenser components.
Why is phosphor bronze used for springs and bearings?
Phosphor bronze (Cu-Sn-P alloys such as C51000 and C52100) combines high fatigue strength, excellent elastic properties, and low friction with good corrosion resistance, and the residual phosphorus deoxidises the melt and improves fluidity and wear resistance, making it well suited for springs, bellows, and sliding bearing bushings.
How do brass, bronze, and cupronickel compare in electrical and thermal conductivity?
Brass generally has the highest electrical and thermal conductivity of the three because zinc causes less lattice distortion in copper than tin or nickel. Tin bronzes have moderate conductivity, and cupronickel has the lowest conductivity of common copper alloys because nickel is highly soluble in copper and causes strong solid-solution electron scattering, which is why cupronickels are used for resistance elements as well as corrosion-resistant tubing.

Recommended Reference Materials

ASM Handbook, Volume 2: Properties and Selection of Nonferrous Alloys

Comprehensive reference on copper alloy composition, phase diagrams, and property data used throughout this comparison.

View on Amazon

Copper and Copper Alloys: Casting, Classification and Characterization

Detailed treatment of brass, bronze, and cupronickel casting metallurgy and microstructure-property relationships.

View on Amazon

Callister’s Materials Science and Engineering

Foundational textbook covering solid-solution strengthening, phase diagrams, and corrosion mechanisms relevant to copper alloys.

View on Amazon

Uhlig’s Corrosion Handbook

Authoritative reference on dezincification, seawater corrosion, and galvanic behaviour of copper-base alloys.

View on Amazon

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