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S36200 Stainless Steel vs. SAE-AISI 9310 Steel

Both S36200 stainless steel and SAE-AISI 9310 steel are iron alloys. They have 82% of their average alloy composition in common. There are 30 material properties with values for both materials. Properties with values for just one material (5, in this case) are not shown.

For each property being compared, the top bar is S36200 stainless steel and the bottom bar is SAE-AISI 9310 steel.

UNS S36200 (XM-9) Stainless Steel SAE-AISI 9310 (1.6657, G93106) Ni-Cr-Mo Steel

Metric UnitsUS Customary Units

Mechanical Properties

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

Elongation at Break, %		3.4 to 4.6
Elongation at Break, %		17 to 19

Fatigue Strength, MPa		450 to 570
Fatigue Strength, MPa		300 to 390

Poisson's Ratio		0.28
Poisson's Ratio		0.29

Shear Modulus, GPa		76
Shear Modulus, GPa		73

Shear Strength, MPa		680 to 810
Shear Strength, MPa		510 to 570

Tensile Strength: Ultimate (UTS), MPa		1180 to 1410
Tensile Strength: Ultimate (UTS), MPa		820 to 910

Tensile Strength: Yield (Proof), MPa		960 to 1240
Tensile Strength: Yield (Proof), MPa		450 to 570

Thermal Properties

Latent Heat of Fusion, J/g		280
Latent Heat of Fusion, J/g		250

Maximum Temperature: Mechanical, °C		820
Maximum Temperature: Mechanical, °C		440

Melting Completion (Liquidus), °C		1440
Melting Completion (Liquidus), °C		1460

Melting Onset (Solidus), °C		1400
Melting Onset (Solidus), °C		1420

Specific Heat Capacity, J/kg-K		480
Specific Heat Capacity, J/kg-K		470

Thermal Conductivity, W/m-K		16
Thermal Conductivity, W/m-K		48

Thermal Expansion, µm/m-K		11
Thermal Expansion, µm/m-K		13

Electrical Properties

Electrical Conductivity: Equal Volume, % IACS		2.3
Electrical Conductivity: Equal Volume, % IACS		7.7

Electrical Conductivity: Equal Weight (Specific), % IACS		2.6
Electrical Conductivity: Equal Weight (Specific), % IACS		8.9

Otherwise Unclassified Properties

Base Metal Price, % relative		12
Base Metal Price, % relative		4.4

Density, g/cm³		7.8
Density, g/cm³		7.9

Embodied Carbon, kg CO₂/kg material		2.8
Embodied Carbon, kg CO₂/kg material		1.8

Embodied Energy, MJ/kg		40
Embodied Energy, MJ/kg		24

Embodied Water, L/kg		120
Embodied Water, L/kg		57

Common Calculations

Resilience: Ultimate (Unit Rupture Work), MJ/m³		46 to 51
Resilience: Ultimate (Unit Rupture Work), MJ/m³		120 to 150

Resilience: Unit (Modulus of Resilience), kJ/m³		2380 to 3930
Resilience: Unit (Modulus of Resilience), kJ/m³		540 to 860

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

Stiffness to Weight: Bending, points		25
Stiffness to Weight: Bending, points		24

Strength to Weight: Axial, points		42 to 50
Strength to Weight: Axial, points		29 to 32

Strength to Weight: Bending, points		32 to 36
Strength to Weight: Bending, points		25 to 27

Thermal Diffusivity, mm²/s		4.3
Thermal Diffusivity, mm²/s		13

Thermal Shock Resistance, points		40 to 48
Thermal Shock Resistance, points		24 to 27

Alloy Composition

Aluminum (Al), %		0 to 0.1
Aluminum (Al), %		0

Carbon (C), %		0 to 0.050
Carbon (C), %		0.080 to 0.13

Chromium (Cr), %		14 to 14.5
Chromium (Cr), %		1.0 to 1.4

Iron (Fe), %		75.4 to 79.5
Iron (Fe), %		93.8 to 95.2

Manganese (Mn), %		0 to 0.5
Manganese (Mn), %		0.45 to 0.65

Molybdenum (Mo), %		0 to 0.3
Molybdenum (Mo), %		0.080 to 0.15

Nickel (Ni), %		6.5 to 7.0
Nickel (Ni), %		3.0 to 3.5

Phosphorus (P), %		0 to 0.030
Phosphorus (P), %		0 to 0.015

Silicon (Si), %		0 to 0.3
Silicon (Si), %		0.2 to 0.35

Sulfur (S), %		0 to 0.030
Sulfur (S), %		0 to 0.012

Titanium (Ti), %		0.6 to 0.9
Titanium (Ti), %		0

Comparable Variants

Annealed Condition