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[SpamAway]

In my spare time I defined some material properties for Titanium (commercially pure), Titanium Alloy (Ti 6Al-4V), Aluminum Alloy (7075), Uranium, Silicon Carbide, and Spring Steel (50CrV4).  The required ores are all available in game.  I have included the material definitions below for anyone who is interested.  These materials will completely change the way you play the game, making basic steel armor VERY vulnerable and sedimentary layers/flux completely optional.  Note that not all of the materials excel in all areas - silicon carbide blades will pierce anything except spring steel, but trying to make armor out of it would be extremely risky if you happen to face an opponent with a blunt impact weapon!

The definitions aren't perfect, especially in regards to the melting temperatures and impact strengths.  I didn't feel like deducing the conversion from real world temperatures to Urists, so I just made magma-safe things magma-safe.  Another source of difficulty was obtaining the impact strength numbers that Toady chose to use as his metric.  In my experience as a Mechanical Engineer, I've never seen impact strength classified that way and my literature searches didn't turn up anything along those lines either.  As such, I had to improvise.  For metals, I used the compressive strength as the impact strength and for silicon carbide I used its flexural strength.  As a result, the numbers are somewhat bogus, but no more bogus that the impact strengths of the game's standard materials.

Various Notes

Spoiler (click to show/hide)

To get density, multiple value in [g/cm^3] by 1000
To get Specific Heat, multiply value in [J/g K] by 1000
Molar masses are in g/kmol.
Strengths are in [kPa]
To get strains, divide strength [kPa] by modulus [GPa] and divide by 10.  This can give unusual results, however.

Titanium (commercially pure, Grade 3/Grade 4) - Obtain via smelting Rutile and Ilmenite

Spoiler (click to show/hide)

Based on grade 3 titanium (http://asm.matweb.com/search/SpecificMaterial.asp?bassnum=MTP642)
    and grade 4 titanium (http://asm.matweb.com/search/SpecificMaterial.asp?bassnum=MTU040)
[INORGANIC:TITANIUM]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:titanium]
   [STATE_NAME_ADJ:LIQUID:molten titanium]
   [STATE_NAME_ADJ:GAS:boiling titanium]
   [DISPLAY_COLOR:0:7:1]
   [MATERIAL_VALUE:25]
   [SPEC_HEAT:526]
   [MELTING_POINT:12768] used iron
   [BOILING_POINT:15150] used iron
   [ITEMS_WEAPON][ITEMS_WEAPON_RANGED][ITEMS_AMMO][ITEMS_DIGGER][ITEMS_ARMOR]
   [ITEMS_HARD]
   [ITEMS_METAL]
   [ITEMS_BARRED]
   [ITEMS_SCALED]
   [SOLID_DENSITY:4510]
   [LIQUID_DENSITY:4510]
   [MOLAR_MASS:47867]
   [IMPACT_YIELD:600000]
   [IMPACT_FRACTURE:700000]
   [IMPACT_STRAIN_AT_YIELD:545] used 110 [GPa]
   [COMPRESSIVE_YIELD:600000]
   [COMPRESSIVE_FRACTURE:700000]
   [COMPRESSIVE_STRAIN_AT_YIELD:545] used 110 [GPa]
   [TENSILE_YIELD:375000]
   [TENSILE_FRACTURE:450000]
   [TENSILE_STRAIN_AT_YIELD:357] used 105 [GPa]
   [TORSION_YIELD:375000]
   [TORSION_FRACTURE:450000]
   [TORSION_STRAIN_AT_YIELD:357]
   [SHEAR_YIELD:375000]
   [SHEAR_FRACTURE:450000]
   [SHEAR_STRAIN_AT_YIELD:937] used 40 [GPa]
   [BENDING_YIELD:375000]
   [BENDING_FRACTURE:450000]
   [BENDING_STRAIN_AT_YIELD:357]
   [MAX_EDGE:10000]

Titanium Alloy (Ti 6Al-4V/Grade 5, alloyed with Aluminum) - Obtained via smelting Titanium and Aluminum together

Spoiler (click to show/hide)

Based on grade 5 titanium (http://asm.matweb.com/search/SpecificMaterial.asp?bassnum=MTP642)
   Alloyed with Aluminum
[INORGANIC:TITANIUM_ALLOY]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:titanium alloy]
   [STATE_NAME_ADJ:LIQUID:molten titanium alloy]
   [STATE_NAME_ADJ:GAS:boiling titanium alloy]
   [DISPLAY_COLOR:0:7:1]
   [MATERIAL_VALUE:40]
   [SPEC_HEAT:526]
   [MELTING_POINT:12768] used iron
   [BOILING_POINT:15150] used iron
   [ITEMS_WEAPON][ITEMS_WEAPON_RANGED][ITEMS_AMMO][ITEMS_DIGGER][ITEMS_ARMOR]
   [ITEMS_HARD]
   [ITEMS_METAL]
   [ITEMS_BARRED]
   [ITEMS_SCALED]
   [SOLID_DENSITY:4510]
   [LIQUID_DENSITY:4510]
   [MOLAR_MASS:47867]
   [IMPACT_YIELD:1070000]
   [IMPACT_FRACTURE:1284000] Just increased yield by 20%
   [IMPACT_STRAIN_AT_YIELD:648] used 110*1.5 = 165 [GPa]
   [COMPRESSIVE_YIELD:1070000]
   [COMPRESSIVE_FRACTURE:1284000]
   [COMPRESSIVE_STRAIN_AT_YIELD:648] used 110*1.5 = 165 [GPa]
   [TENSILE_YIELD:1100000]
   [TENSILE_FRACTURE:1170000]
   [TENSILE_STRAIN_AT_YIELD:964] used 114 [GPa]
   [TORSION_YIELD:1100000]
   [TORSION_FRACTURE:1170000]
   [TORSION_STRAIN_AT_YIELD:964]
   [SHEAR_YIELD:760000]
   [SHEAR_FRACTURE:912000] Just increased yield by 20%
   [SHEAR_STRAIN_AT_YIELD:1700] used 44 [GPa]
   [BENDING_YIELD:1100000]
   [BENDING_FRACTURE:1170000]
   [BENDING_STRAIN_AT_YIELD:964]
   [MAX_EDGE:10000]

Aluminum Alloy (7075, alloyed with zinc) - Obtained via smelting Aluminum and Zinc

Spoiler (click to show/hide)

This is based off of 7075 aluminum alloy (http://asm.matweb.com/search/SpecificMaterial.asp?bassnum=MA7075T6)
   Alloyed with Zinc
[INORGANIC:ALUMINUM_ALLOY]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:aluminum alloy]
   [STATE_NAME_ADJ:LIQUID:molten aluminum alloy]
   [STATE_NAME_ADJ:GAS:boiling aluminum alloy]
   [DISPLAY_COLOR:7:7:1]
   [MATERIAL_VALUE:30]
   [SPEC_HEAT:960]
   [MELTING_POINT:11188]
   [BOILING_POINT:14534]
   [ITEMS_WEAPON][ITEMS_WEAPON_RANGED][ITEMS_AMMO][ITEMS_DIGGER][ITEMS_ARMOR]
   [ITEMS_HARD]
   [ITEMS_METAL]
   [ITEMS_BARRED]
   [ITEMS_SCALED]
   [SOLID_DENSITY:2700]
   [LIQUID_DENSITY:2375]
   [MOLAR_MASS:26981]
   [IMPACT_YIELD:576000]
   [IMPACT_FRACTURE:691000] Just increased yield by 20%
   [IMPACT_STRAIN_AT_YIELD:921]
   [COMPRESSIVE_YIELD:576000]
   [COMPRESSIVE_FRACTURE:691000]
   [COMPRESSIVE_STRAIN_AT_YIELD:921] 76
   [TENSILE_YIELD:503000]
   [TENSILE_FRACTURE:572000]
   [TENSILE_STRAIN_AT_YIELD:698] used 72 [GPa]
   [TORSION_YIELD:503000]
   [TORSION_FRACTURE:572000]
   [TORSION_STRAIN_AT_YIELD:698]
   [SHEAR_YIELD:331000]
   [SHEAR_FRACTURE:397000] Just increased yield by 20%
   [SHEAR_STRAIN_AT_YIELD:1230] used 26.9 [GPa]
   [BENDING_YIELD:503000]
   [BENDING_FRACTURE:572000]
   [BENDING_STRAIN_AT_YIELD:698]
   [MAX_EDGE:10000]

Uranium (material properties of depleted uranium alloys are secret, so I just used bronze for the strengths/strains) - Obtained via smelting Pitchblende

Spoiler (click to show/hide)

As the material properties of military grade depleted uranium are secret, I used bronze for the strength/strain values
[INORGANIC:URANIUM]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:uranium]
   [STATE_NAME_ADJ:LIQUID:molten uranium]
   [STATE_NAME_ADJ:GAS:boiling uranium]
   [DISPLAY_COLOR:0:7:1]
   [MATERIAL_VALUE:20]
   [SPEC_HEAT:120]
   [MELTING_POINT:13182] Used platinum
   [BOILING_POINT:16885] Used platinum
   [ITEMS_WEAPON][ITEMS_AMMO]
   [ITEMS_HARD]
   [ITEMS_METAL]
   [ITEMS_BARRED]
   [ITEMS_SCALED]
   [SOLID_DENSITY:18938]
   [LIQUID_DENSITY:18938]
   [MOLAR_MASS:238030]
   [IMPACT_YIELD:602000]
   [IMPACT_FRACTURE:843500]
   [IMPACT_STRAIN_AT_YIELD:547]
   [COMPRESSIVE_YIELD:602000]
   [COMPRESSIVE_FRACTURE:843500]
   [COMPRESSIVE_STRAIN_AT_YIELD:547]
   [TENSILE_YIELD:172000]
   [TENSILE_FRACTURE:241000]
   [TENSILE_STRAIN_AT_YIELD:156]
   [TORSION_YIELD:172000]
   [TORSION_FRACTURE:241000]
   [TORSION_STRAIN_AT_YIELD:156]
   [SHEAR_YIELD:172000]
   [SHEAR_FRACTURE:241000]
   [SHEAR_STRAIN_AT_YIELD:156]
   [BENDING_YIELD:172000]
   [BENDING_FRACTURE:241000]
   [BENDING_STRAIN_AT_YIELD:156]
   [MAX_EDGE:10000]

Silicon Carbide (material properties are very sample-specific, so  I just used a mishmash of what is readily available online) - Obtained by combining a silicon source such as Sand or Quartzite with a carbon source such as Charcoal or Coke

Spoiler (click to show/hide)

The material properties of Silicon Carbide are very dependent on the crystalline structure of the specific sample involved.  These
   values are a mishmash of what is available online:
      (1) - http://accuratus.com/silicar.html
      (2) - http://www.ceramics.nist.gov/srd/summary/scdscs.htm
      (3) - http://www.goodfellow.com/E/Silicon-Carbide-Hot-pressed.html
   
[INORGANIC:SILICON_CARBIDE]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:silicon carbide]
   [STATE_NAME_ADJ:LIQUID:molten silicon carbide]
   [STATE_NAME_ADJ:GAS:boiling silicon carbide]
   [DISPLAY_COLOR:7:0:1]
   [MATERIAL_VALUE:10]
   [SPEC_HEAT:750]
   [MELTING_POINT:13182] Used platinum
   [BOILING_POINT:16885] Used platinum
   [ITEMS_WEAPON][ITEMS_AMMO][ITEMS_DIGGER]
   [ITEMS_HARD]
   [ITEMS_SCALED]
   [SOLID_DENSITY:3100]
   [LIQUID_DENSITY:3100]
   [MOLAR_MASS:26981] Used aluminum alloy
   [IMPACT_YIELD:535000]   Used the flexural strength (bogus, but better than nothing)
   [IMPACT_FRACTURE:642000]
   [IMPACT_STRAIN_AT_YIELD:118]
   [COMPRESSIVE_YIELD:3900000]
   [COMPRESSIVE_FRACTURE:4680000] Just increased yield by 20%
   [COMPRESSIVE_STRAIN_AT_YIELD:130] Bulk modulus of 203 [GPa], 1300 was ridiculous so I used 130 instead
   [TENSILE_YIELD:250000]
   [TENSILE_FRACTURE:300000] Just increased yield by 20%
   [TENSILE_STRAIN_AT_YIELD:56] used Young's Modulus of 450 [GPa]
   [TORSION_YIELD:458000]
   [TORSION_FRACTURE:550000]
   [TORSION_STRAIN_AT_YIELD:102] used Young's Modulus of 450 [GPa]
   [SHEAR_YIELD:780000] Used a 5:1 Compressive:Shear ratio as shown in (3)
   [SHEAR_FRACTURE:936000]
   [SHEAR_STRAIN_AT_YIELD:156] used a Shear Modulus of 179 [GPa]
   [BENDING_YIELD:458000]
   [BENDING_FRACTURE:550000]
   [BENDING_STRAIN_AT_YIELD:102] used Young's Modulus of 450 [GPa]
   [MAX_EDGE:20000]

Spring Steel (50CrV4, alloyed with chromium and heat-treated) - Obtained via smelting Steel and Chromium

Spoiler (click to show/hide)

This is modeled after 50CrV4 Spring Steel.  There wasn't complete data on it, so I had to improvise some using multiple sources
   (1) - http://www.matbase.com/material/ferrous-metals/spring-steel/50crv4/properties
   (2) - http://www.anchorlamina.com/pdf.d/Punchrite-ShearStrength.pdf
   (3) - http://www.engineeringtoolbox.com/modulus-rigidity-d_946.html
   (4) - http://www.matweb.com/search/DataSheet.aspx?MatGUID=ee25302df4b34404b21ad67f8a83e858

   Alloy with Chromium (from Chromite)
   
[INORGANIC:SPRING_STEEL]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:spring steel]
   [STATE_NAME_ADJ:LIQUID:molten spring steel]
   [STATE_NAME_ADJ:GAS:boiling spring steel]
   [DISPLAY_COLOR:0:7:1]
   [MATERIAL_VALUE:50]
   [SPEC_HEAT:500]
   [MELTING_POINT:12718]
   [BOILING_POINT:14968]
   [ITEMS_WEAPON][ITEMS_WEAPON_RANGED][ITEMS_AMMO][ITEMS_DIGGER][ITEMS_ARMOR]
   [ITEMS_HARD]
   [ITEMS_METAL]
   [ITEMS_BARRED]
   [ITEMS_SCALED]
   [SOLID_DENSITY:7850]
   [LIQUID_DENSITY:6980]
   [MOLAR_MASS:55845]
   [IMPACT_YIELD:2200000]
   [IMPACT_FRACTURE:2600000]
   [IMPACT_STRAIN_AT_YIELD:1571]
   [COMPRESSIVE_YIELD:2200000] Just a guess
   [COMPRESSIVE_FRACTURE:2600000]
   [COMPRESSIVE_STRAIN_AT_YIELD:1571] 140
   [TENSILE_YIELD:1200000]
   [TENSILE_FRACTURE:14000000]
   [TENSILE_STRAIN_AT_YIELD:571] Young's Modulus of 210 [GPa]
   [TORSION_YIELD:1200000]
   [TORSION_FRACTURE:14000000]
   [TORSION_STRAIN_AT_YIELD:571]
   [SHEAR_YIELD:1000000] - Used 1.2:1 Tensile:Shear ratio seen in (2)
   [SHEAR_FRACTURE:1170000]
   [SHEAR_STRAIN_AT_YIELD:1300] Shear Modulus of 77 [GPa]
   [BENDING_YIELD:1200000]
   [BENDING_FRACTURE:14000000]
   [BENDING_STRAIN_AT_YIELD:571]

Chromium - Obtained via smelting Chromite

Spoiler (click to show/hide)

I just took the material definition of nickel and used it for chromium
[INORGANIC:CHROMIUM]
   [USE_MATERIAL_TEMPLATE:METAL_TEMPLATE]
   [STATE_NAME_ADJ:ALL_SOLID:chromium]
   [STATE_NAME_ADJ:LIQUID:molten chromium]
   [STATE_NAME_ADJ:GAS:boiling chromium]
   [DISPLAY_COLOR:7:3:0]
   [MATERIAL_VALUE:2]
   [SPEC_HEAT:444]
   [MELTING_POINT:12619]
   [BOILING_POINT:15243]
   [SOLID_DENSITY:8800]
   [LIQUID_DENSITY:7810]
   [MOLAR_MASS:58693]
   [IMPACT_YIELD:70000]
   [IMPACT_FRACTURE:560000]
   [IMPACT_STRAIN_AT_YIELD:39]
   [COMPRESSIVE_YIELD:70000]
   [COMPRESSIVE_FRACTURE:560000]
   [COMPRESSIVE_STRAIN_AT_YIELD:39] 180
   [TENSILE_YIELD:20000]
   [TENSILE_FRACTURE:160000]
   [TENSILE_STRAIN_AT_YIELD:10] 200
   [TORSION_YIELD:20000]
   [TORSION_FRACTURE:160000]
   [TORSION_STRAIN_AT_YIELD:26]
   [SHEAR_YIELD:20000]
   [SHEAR_FRACTURE:160000]
   [SHEAR_STRAIN_AT_YIELD:26] 76
   [BENDING_YIELD:20000]
   [BENDING_FRACTURE:160000]
   [BENDING_STRAIN_AT_YIELD:10]
   [MAX_EDGE:10000]
   [ITEMS_HARD]
   [ITEMS_METAL]
   [ITEMS_BARRED]
   [ITEMS_SCALED]

The game doesn't do a very good job of modeling certain aspects of materials (like hardness).  Therefore, Silicon Carbide (which is commonly used in military armor) represents its impact properties with its relatively low flexural strength rather than its extremely high hardness, making it an artificially inferior armor material. 

[darkflagrance]

I was thinking of creating silicon carbide on my own, thanks!

Tungsten carbide might be cool too.

[Alternatecash]

Now I just need to wait for an artifact uranium hammer...

[Deon]

Uranium (material properties of depleted uranium alloys are secret, so I just used bronze for the strengths/strains)

They are not secret, I just think that nobody who knows bothered to upload them on the public sites...

Or is there some source which claims they are secret? I am interested, because I can go in one of our laboratories and learn them .

[SpamAway]

They are not secret, I just think that nobody who knows bothered to upload them on the public sites...

Or is there some source which claims they are secret? I am interested, because I can go in one of our laboratories and learn them .

I guess I may have incorrectly assumed the material properties of uranium alloys such as Staballoy would be (at the very least) a trade secret...If you know the properties and would be willing to share them, it would be greatly appreciated!

[Deon]

Maybe you are right. I will ask anyway, just to make sure .