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The exception is the global atmosphere, which does not "contain" anything and can be said to have infinite volume<sup>[verification needed]</sup>.
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The exception is the global atmosphere, which is not contained and can be said to have infinite volume<sup>[verification needed]</sup>.
  
 
===Implications===
 
===Implications===

Revision as of 03:17, 1 June 2020

Stationeers models many of the real universe's physical laws, to simulate the behavior of things like gases, electricity, and stationeers. This is a reference guide to the underlying physical science concepts, and notes on how Stationeers is faithful or unfaithful them.

Measurement

Stationeers measures most properties using units standardized in the International System of Units ("SI"). This applies to the HUD and other visual displays, but it also applies to values used in logic circuitry, which is important to logic-based math.

Mass: "Can I Push That?"

Mass measures an amount of matter, in terms of its relationship to forces (e.g., gravity), inertia, and acceleration. Stationeers uses the SI unit gram (g) for mass.

Direct Measurement

Stationeers probably uses mass extensively behind the scenes, within the physics engine to calculate the movement of objects. In the player interface, however, only certain substances are given mass measurements:

Implications

Ores are not measured by mass, but each unit of ore always produces one gram of product (not counting off-gas byproducts) when smelted.

The recipe for an alloy is given as ratios between ingredients, not as exact amounts. These are ratios of mass, not of moles or volume. While this is faithful to real-world metallurgy, the recipes themselves are simplified from their real counterparts.

The total count of the ore units output from a Centrifuge always equals the mass in grams of the mix put in. This is not faithful[verification needed], because all ores in the game explicitly include impurities. The implication is that the Centrifuge somehow reintroduces the original impurities, and in fact this can be exploited to create those impurities from nothing, if you find them useful.

Moles: "Will It Blend?"

In chemical terms, "amounts" of substance are not measured as mass, but as counts of particles. In Stationeers, the particles in question are always molecules, and the game relates these counts using the SI unit mole. A mole is 6.0 × 1023 molecules (the Avogadro number). It is abbreviated as mol; Stationeers also uses kmol (one thousand moles) and Mmol (one million moles).

Moles Versus Mass

Although there is a direct relationship between moles and mass, the reason to use moles is because it makes chemistry equations less awkward. Take, for example, the combustion of hydrogen:

2H2 + O2 → 2H2O + a bunch of heat

To apply real amounts of substance to this equation, you can do it very simply as long as everything is expressed in moles.

2mol H2 + 1mol O2 → 2mol H2O

To express the same thing with mass, you would have to account for the very different mass per molecule of hydrogen gas, oxygen gas, and water.

4.032g H2 + 31.999g O2 → 36.031g H2O

The numbers add up (because mass is conserved), but they're odd-looking, and they obscure the fact that the reaction takes more hydrogen than oxygen, molecule for molecule.

Direct Measurement

Stationeers measures all gases and other bulk fluids in moles, so you will see molar readings on, for example, Pipe Analyzers and a Handheld Tablet running the Atmos Analyzer Cartridge. These fluids are found in:

Implications

The game does not include a reference to the molar masses of these fluids, but it should not normally be necessary. Ratios of one substance to another can be crucial (e.g., for Fuel), but these are always calculated by mole (see stoichiometry), not by mass or volume.

The game is not faithful to molar chemistry when it comes to the substance called "Volatiles". Volatiles behave in some chemical contexts like pure hydrogen gas (and are sometimes labeled "H2"), but when burned they behave more like a hydrocarbon.

Volume: "Where Can I Fit That?"

Volume is, simply, the amount of space occupied by a three-dimensional shape. If a substance can compress (like a gas), and a container is rigid, then the volume will remain constant even as you pump mass/moles into or out of the container.

Stationeers uses the SI unit liter (L) for volume. Some spaces are more practical to measure in thousands of liters; 1,000 L can be referred to as 1 kL (kiloliter), but it would more commonly be called a cubic meter (m3).

Direct Measurement

Stationeers calculates a volume for everything that can contain gases/fluids.

The exception is the global atmosphere, which is not contained and can be said to have infinite volume[verification needed].

Implications

The volume of plumbing and other components is not usually made obvious by the player interface, but it is a real and essential factor in calculations of pressure and other properties. Say you produce X mol of gas, and you connect it to a Tank for storage, with no active pumping components between. The more Pipes present between the source and the Tank, the lower the total pressure, because each Pipe adds 100L of volume.

Here are some important reference volumes.

Temperature: "Will That Cook Me?"

Temperature is the measurement of how hot or cold matter is. The precise thermodynamic definition is complex, but it can be roughly summarized as the amount of energy embedded into a substance. Thermal energy will tend to transfer through matter (conduction) from regions of high temperature to lower temperature. Temperature has a very direct effect on pressure, and vice versa.

Direct Measurement

Stationeers measures temperature on two scales. Fluids within plumbing (e.g., pipes, tanks, furnaces) are measured in kelvin (K), where 0K represents the theoretical complete absence of thermal energy ("absolute zero"). Fluids in enclosed spaces or in the atmosphere are measured in degrees Celsius (°C), where 0°C is the freezing point of water at standard atmospheric pressure (101.325 kPa). One kelvin is exactly equal to one degree Celsius, so you can easily convert from K to °C by subtracting 273.15.

Implications

Pressure, Absolute

Pressure, Differential

Phase

Energy