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Grade 250 Maraging Steel vs. 8090 Aluminum

Grade 250 maraging steel belongs to the iron alloys classification, while 8090 aluminum belongs to the aluminum alloys. There are 22 material properties with values for both materials. Properties with values for just one material (12, in this case) are not shown. Please note that the two materials have significantly dissimilar densities. This means that additional care is required when interpreting the data, because some material properties are based on units of mass, while others are based on units of area or volume.

For each property being compared, the top bar is grade 250 maraging steel and the bottom bar is 8090 aluminum.

Grade 250 Maraging Steel 8090 (AlLi2.5Cu1.5Mg1) Aluminum

Metric UnitsUS Customary Units

Mechanical Properties

Elastic (Young's, Tensile) Modulus, GPa		190
Elastic (Young's, Tensile) Modulus, GPa		67

Elongation at Break, %		7.3 to 17
Elongation at Break, %		3.5 to 13

Poisson's Ratio		0.3
Poisson's Ratio		0.33

Shear Modulus, GPa		75
Shear Modulus, GPa		25

Tensile Strength: Ultimate (UTS), MPa		970 to 1800
Tensile Strength: Ultimate (UTS), MPa		340 to 490

Tensile Strength: Yield (Proof), MPa		660 to 1740
Tensile Strength: Yield (Proof), MPa		210 to 420

Thermal Properties

Latent Heat of Fusion, J/g		270
Latent Heat of Fusion, J/g		400

Melting Completion (Liquidus), °C		1480
Melting Completion (Liquidus), °C		660

Melting Onset (Solidus), °C		1430
Melting Onset (Solidus), °C		600

Specific Heat Capacity, J/kg-K		450
Specific Heat Capacity, J/kg-K		960

Thermal Expansion, µm/m-K		12
Thermal Expansion, µm/m-K		24

Otherwise Unclassified Properties

Base Metal Price, % relative		32
Base Metal Price, % relative		18

Density, g/cm³		8.2
Density, g/cm³		2.7

Embodied Carbon, kg CO₂/kg material		4.9
Embodied Carbon, kg CO₂/kg material		8.6

Embodied Energy, MJ/kg		65
Embodied Energy, MJ/kg		170

Embodied Water, L/kg		140
Embodied Water, L/kg		1160

Common Calculations

Resilience: Ultimate (Unit Rupture Work), MJ/m³		130 to 150
Resilience: Ultimate (Unit Rupture Work), MJ/m³		16 to 41

Stiffness to Weight: Axial, points		13
Stiffness to Weight: Axial, points		14

Stiffness to Weight: Bending, points		23
Stiffness to Weight: Bending, points		50

Strength to Weight: Axial, points		33 to 61
Strength to Weight: Axial, points		34 to 49

Strength to Weight: Bending, points		26 to 40
Strength to Weight: Bending, points		39 to 50

Thermal Shock Resistance, points		29 to 54
Thermal Shock Resistance, points		15 to 22

Alloy Composition

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Aluminum (Al), %		0.050 to 0.15
Aluminum (Al), %		93 to 98.4

Boron (B), %		0 to 0.0030
Boron (B), %		0

Calcium (Ca), %		0 to 0.050
Calcium (Ca), %		0

Carbon (C), %		0 to 0.030
Carbon (C), %		0

Chromium (Cr), %		0
Chromium (Cr), %		0 to 0.1

Cobalt (Co), %		7.0 to 8.5
Cobalt (Co), %		0

Copper (Cu), %		0
Copper (Cu), %		1.0 to 1.6

Iron (Fe), %		66.3 to 71.1
Iron (Fe), %		0 to 0.3

Lithium (Li), %		0
Lithium (Li), %		2.2 to 2.7

Magnesium (Mg), %		0
Magnesium (Mg), %		0.6 to 1.3

Manganese (Mn), %		0 to 0.1
Manganese (Mn), %		0 to 0.1

Molybdenum (Mo), %		4.6 to 5.2
Molybdenum (Mo), %		0

Nickel (Ni), %		17 to 19
Nickel (Ni), %		0

Phosphorus (P), %		0 to 0.010
Phosphorus (P), %		0

Silicon (Si), %		0 to 0.1
Silicon (Si), %		0 to 0.2

Sulfur (S), %		0 to 0.010
Sulfur (S), %		0

Titanium (Ti), %		0.3 to 0.5
Titanium (Ti), %		0 to 0.1

Zinc (Zn), %		0
Zinc (Zn), %		0 to 0.25

Zirconium (Zr), %		0 to 0.020
Zirconium (Zr), %		0.040 to 0.16

Residuals, %		0
Residuals, %		0 to 0.15