Modulus of elasticity and Poisson's coefficient of non-ferrous metals

The tables below show the values of Young's modulus (modulus of elasticity) and Poisson's ratio at room temperature for several nonferrous metals used in engineering. The material properties are expressed in average values or in ranges that can vary significantly depending on the processing and of the material's quality. The exact values can be measured by the non-destructive Sonelastic® Systems testing at room temperature, as well at low and high temperatures.

Aluminum alloys

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Aluminum alloys
Alloy 1100: 69 10 0.33
Alloy 2024: 72.4 10.5 0.33
Alloy 6061: 69 10 0.33
Alloy 7075: 71 10.3 0.33
Values for reference only. For exact values, characterize the material with the Sonelastic® Systems.

Main applications:
- 1100: equipment for chemical and food industries.
- 2024: aircraft structures, rivets and truck wheels.
- 6061: aluminum of naval use, also used in pipes and in ultrasonic transducers for cleaning.
- 7075: aircraft structures, applications subjected to high voltages and ultrasonic transducers for welding. It is usually available in plates or square bars. It is the most expensive aluminum alloy, worth about four times the value of alloy 6061.

The elastic moduli (Young's Modulus, shear modulus and Poisson's ratio) and damping of aluminum alloys can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at low and high temperatures. The knowledge of exact values is vital for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.

In the case of alloy 7075, when applied in the manufacturing of ultrasonic transducers, the knowledge of sonic velocity is also very important. Sonic velocity is characterized by the non-destructive Sonelastic® Systems testing.

Cooper alloys

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Copper alloys
C11000 (electrolytic tough pitch): 115 16.7 0.33
C17200 (beryllium-copper): 128 18.6 0.30
C26000 (cartridge brass): 110 16 0.35
Values for reference only. For exact values, characterize the material using the Sonelastic® Systems.

Main applications:
- C11000: wires and electrical cables.
- C17200: springs, bushings, valves and diaphragms.
- C26000: cartridge casings and automotive radiators.

The elastic moduli (Young's Modulus, Shear modulus and Poisson's ratio) and damping of copper alloys (for example, when estimating the stretching of wires under load) can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at low and high temperatures. The knowledge of exact values is vital for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.

Magnesium alloys

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Magnesium alloys:
Alloy AZ31B: 45 6.5 0.35
Alloy AZ91D: 45 6.5 0.35
Values for reference only. For exact values, characterize the material using the Sonelastic® Systems.

Main applications:
- AZ31B: structures, tubings and cathodic protection.
- AZ91D: die-cast parts for automobiles and electronic devices.

Magnesium alloys are also used in the manufacturing of automotive wheels.

The elastic moduli (Young's Modulus, Shear modulus and Poisson's ratio) and damping of magnesium alloys can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at low and high temperatures. The knowledge of exact values is fundamental vital for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.

Titanium alloys

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Titanium alloys
Commercially pure: 103 14.6 0.34
Alloy Ti-5A1-2.5Sn: 110 16 0.34
Alloy Ti- 6A1-4V: 114 16.5 0.34
Values for reference only. For exact values, characterize the material using the Sonelastic® Systems.

Main applications:
- Ti-5A1-2.5Sn: fuselage of aircraft and corrosion-resistant equipment.
- Ti-6A1-4V: surgical implants and aircraft structural elements.

One of the most common applications of Ti-6A1-4V is related to dental implants. In that case, titanium elements receive a surface treatment to improve the biocompatibility and osseointegration.

The elastic moduli (Young's Modulus, Shear modulus and Poisson's ratio) and damping of titanium alloys can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at low and high temperatures. The knowledge of the exact values is vital for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.

Noble metals

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Noble metals
Gold (Pure): 77 11.2 0.42
Platinum (Pure): 171 24.8 0.39
Values for reference only. For exact values, characterize the material using the Sonelastic® Systems.

Main applications:
- Gold: electrical contacts and dental restoration.
- Platinum: crucibles, catalyst and thermocouples for elevated temperatures.

The elastic moduli (Young's Modulus, Shear modulus and Poisson's ratio) and damping of noble metals can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at for low and high temperatures. The knowledge of the exact values is vital to for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.

Refractory metals

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Refractory metals
Molybdenum (pure): 320 46.4 0.32
Tantalum (pure): 185 27 0.35
Tungsten (pure): 400 58 0.28
Values for reference only. For exact values, characterize the material using Sonelastic® Systems.

Main applications:
- Molybdenum: extrusion dies and structural parts in space vehicles.
- Tantalum: corrosion-resistant material and chemical attack.
- Tungsten: incandescent light filaments, x-ray tubes and welding electrodes.

The elastic moduli (Young's Modulus, Shear modulus and Poisson's ratio) and damping of refractory metals can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at low and high temperatures. The knowledge of exact values is vital for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.

Miscellaneous non-ferrous alloys

Material Modulus of elasticity Poisson’s ratio
GPa 106 psi
Miscellaneous Nonferrous Alloys
Nikel 200: 204 29.6 0.31
Inconel 625: 207 30 0.31
Monel 400: 180 26 0.32
Haynes alloy 25: 236 34.2 -
Invar: 141 20.5 -
Super Invar: 144 21 -
Kovar: 207 30 -
Chemical Lead: 13.5 2 0.44
Tin (commercially pure): 44.3 6.4 0.33
Lead-tin solder (60Sn-40Pb):
(60Sn-40Pb):
30 4.4 -
Zinc (commercially pure): 104.5 15.2 0.25
Zirconium (reactor grade 702): 99.3 14.4 0.35
Values for reference only. For exact values, characterize the material using Sonelastic® Systems.

The elastic moduli (Young's Modulus, Shear modulus and Poisson's ratio) and damping of these nonferrous alloys can be accurately characterized by the non-destructive Sonelastic® Systems testing at room temperature, as well as at low and high temperatures. The knowledge of the exact values is vital for the optimization of the material's use and for the reliability of simulations via finite elements. Elastic moduli and damping characterizations are also employed in the engineering of new variations of these materials.


References

ASM Handbooks, Vol. 1 and 2, Engineered Materials Handbook, Vol. 1 and 4, Metals Handbook: Properties and Selection: Nonferrous Alloys and Pure Metals, Vol. 2, 9th edition, and Advance Materials and Processes, Vol. 146, No.4, ASM International, Materials Park, OH.