/tg/ Station 13 - Modules - TypesDefine Details

code/__DEFINES/reactions.dm

PRIORITY_PRE_FORMATIONThe prority used to indicate that a reaction should run immediately at the start of a reaction cycle. Currently used by a jumble of decomposition reactions and purgative reactions.
PRIORITY_FORMATIONThe priority used for reactions that produce a useful or more advanced product. Goes after purgative reactions so that the purgers can be slightly more useful.
PRIORITY_POST_FORMATIONThe priority used for indicate that a reactions should run immediately before most forms of combustion. Used by two decomposition reactions and steam condensation.
PRIORITY_FIREThe priority used to indicate that a reactions should run after all other types of reactions. Exclusively used for combustion reactions that produce fire or are freon.
ATMOS_RADIATION_VOLUME_EXPAn exponent used to make large volume gas mixtures significantly less likely to release rads. Used to prevent tritfires in distro from irradiating literally the entire station with no warning.
GAS_REACTION_MAXIMUM_RADIATION_PULSE_RANGEMaximum range a radiation pulse is allowed to be from a gas reaction.
WATER_VAPOR_CONDENSATION_POINTThe temperature required for water vapor to condense.
WATER_VAPOR_DEPOSITION_POINTThe temperature required for water vapor to condense as ice instead of water.
MIASTER_STERILIZATION_TEMPThe minimum temperature miasma begins being sterilized at.
MIASTER_STERILIZATION_MAX_HUMIDITYThe maximum ratio of water vapor to other gases miasma can be sterilized at.
MIASTER_STERILIZATION_RATE_BASEThe minimum amount of miasma that will be sterilized in a reaction tick.
MIASTER_STERILIZATION_RATE_SCALEThe temperature required to sterilize an additional mole of miasma in a reaction tick.
MIASTER_STERILIZATION_ENERGYThe amount of energy released when a mole of miasma is sterilized.
FIRE_CARBON_ENERGY_RELEASEDAmount of heat released per mole of burnt carbon into the tile
PLASMA_MINIMUM_BURN_TEMPERATUREMinimum temperature to burn plasma
PLASMA_UPPER_TEMPERATUREUpper temperature ceiling for plasmafire reaction calculations for fuel consumption
OXYGEN_BURN_RATIO_BASEThe maximum and default amount of plasma consumed as oxydizer per mole of plasma burnt.
PLASMA_OXYGEN_FULLBURNMultiplier for plasmafire with O2 moles * PLASMA_OXYGEN_FULLBURN for the maximum fuel consumption
SUPER_SATURATION_THRESHOLDThe minimum ratio of oxygen to plasma necessary to start producing tritium.
PLASMA_BURN_RATE_DELTAThe divisor for the maximum plasma burn rate. (1/9 of the plasma can burn in one reaction tick.)
FIRE_PLASMA_ENERGY_RELEASEDAmount of heat released per mole of burnt plasma into the tile
HYDROGEN_MINIMUM_BURN_TEMPERATUREThe minimum temperature hydrogen combusts at.
FIRE_HYDROGEN_ENERGY_RELEASEDThe amount of energy released by burning one mole of hydrogen.
HYDROGEN_OXYGEN_FULLBURNMultiplier for hydrogen fire with O2 moles * HYDROGEN_OXYGEN_FULLBURN for the maximum fuel consumption
FIRE_HYDROGEN_BURN_RATE_DELTAThe divisor for the maximum hydrogen burn rate. (1/2 of the hydrogen can burn in one reaction tick.)
TRITIUM_MINIMUM_BURN_TEMPERATUREThe minimum temperature tritium combusts at.
FIRE_TRITIUM_ENERGY_RELEASEDThe amount of energy released by burning one mole of tritium.
TRITIUM_OXYGEN_FULLBURNMultiplier for TRITIUM fire with O2 moles * TRITIUM_OXYGEN_FULLBURN for the maximum fuel consumption
FIRE_TRITIUM_BURN_RATE_DELTAThe divisor for the maximum tritium burn rate. (1/2 of the tritium can burn in one reaction tick.)
TRITIUM_RADIATION_MINIMUM_MOLESThe minimum number of moles of trit that must be burnt for a tritium fire reaction to produce a radiation pulse. (0.01 moles trit or 10 moles oxygen to start producing rads.)
TRITIUM_RADIATION_RELEASE_THRESHOLDThe minimum released energy necessary for tritium to release radiation during combustion. (at a mix volume of CELL_VOLUME).
TRITIUM_RADIATION_RANGE_DIVISORA scaling factor for the range of radiation pulses produced by tritium fires.
TRITIUM_RADIATION_THRESHOLDThe threshold of the tritium combustion's radiation. Lower values means it will be able to penetrate through more structures.
FREON_MAXIMUM_BURN_TEMPERATUREThe maximum temperature freon can combust at.
FREON_LOWER_TEMPERATUREMinimum temperature allowed for the burn to go at max speed, we would have negative pressure otherwise
FREON_TERMINAL_TEMPERATURETerminal temperature after wich we stop the reaction
FREON_OXYGEN_FULLBURNMultiplier for freonfire with O2 moles * FREON_OXYGEN_FULLBURN for the maximum fuel consumption
FREON_BURN_RATE_DELTAThe maximum fraction of the freon in a mix that can combust each reaction tick.
FIRE_FREON_ENERGY_CONSUMEDThe amount of heat absorbed per mole of freon burnt.
HOT_ICE_FORMATION_MAXIMUM_TEMPERATUREThe maximum temperature at which freon combustion can form hot ice.
HOT_ICE_FORMATION_MINIMUM_TEMPERATUREThe minimum temperature at which freon combustion can form hot ice.
HOT_ICE_FORMATION_PROBThe chance for hot ice to form when freon reacts on a turf.
N2O_FORMATION_MIN_TEMPERATUREThe minimum temperature N2O can form from nitrogen and oxygen in the presence of BZ at.
N2O_FORMATION_MAX_TEMPERATUREThe maximum temperature N2O can form from nitrogen and oxygen in the presence of BZ at.
N2O_FORMATION_ENERGYThe amount of energy released when a mole of N2O forms from nitrogen and oxygen in the presence of BZ.
N2O_DECOMPOSITION_MIN_TEMPERATUREThe minimum temperature N2O can decompose at.
N2O_DECOMPOSITION_MAX_TEMPERATUREThe maximum temperature N2O can decompose at.
N2O_DECOMPOSITION_RATE_DIVISORThe maximum portion of the N2O that can decompose each reaction tick. (50%)
N2O_DECOMPOSITION_MIN_SCALE_TEMPOne root of the parabola used to scale N2O decomposition rates.
N2O_DECOMPOSITION_MAX_SCALE_TEMPThe other root of the parabola used to scale N2O decomposition rates.
N2O_DECOMPOSITION_SCALE_DIVISORThe divisor used to normalize the N2O decomp scaling parabola. Basically the value of the apex/nadir of (x - N2O_DECOMPOSITION_MIN_SCALE_TEMP) * (x - N2O_DECOMPOSITION_MAX_SCALE_TEMP).
N2O_DECOMPOSITION_ENERGYThe amount of energy released when one mole of N2O decomposes into nitrogen and oxygen.
BZ_FORMATION_MAX_TEMPERATUREThe maximum temperature BZ can form at. Deliberately set lower than the minimum burn temperature for most combustible gases in an attempt to prevent long fuse singlecaps.
BZ_FORMATION_ENERGYThe amount of energy 1 mole of BZ forming from N2O and plasma releases.
PLUOXIUM_FORMATION_MIN_TEMPThe minimum temperature pluoxium can form from carbon dioxide, oxygen, and tritium at.
PLUOXIUM_FORMATION_MAX_TEMPThe maximum temperature pluoxium can form from carbon dioxide, oxygen, and tritium at.
PLUOXIUM_FORMATION_MAX_RATEThe maximum amount of pluoxium that can form from carbon dioxide, oxygen, and tritium per reaction tick.
PLUOXIUM_FORMATION_ENERGYThe amount of energy one mole of pluoxium forming from carbon dioxide, oxygen, and tritium releases.
NITRIUM_FORMATION_MIN_TEMPThe minimum temperature necessary for nitrium to form from tritium, nitrogen, and BZ.
NITRIUM_FORMATION_TEMP_DIVISORA scaling divisor for the rate of nitrium formation relative to mix temperature.
NITRIUM_FORMATION_ENERGYThe amount of thermal energy consumed when a mole of nitrium is formed from tritium, nitrogen, and BZ.
NITRIUM_DECOMPOSITION_MAX_TEMPThe maximum temperature nitrium can decompose into nitrogen and hydrogen at.
NITRIUM_DECOMPOSITION_TEMP_DIVISORA scaling divisor for the rate of nitrium decomposition relative to mix temperature.
NITRIUM_DECOMPOSITION_ENERGYThe amount of energy released when a mole of nitrium decomposes into nitrogen and hydrogen.
FREON_FORMATION_MIN_TEMPERATUREThe minimum temperature freon can form from plasma, CO2, and BZ at.
FREON_FORMATION_ENERGYThe amount of energy 2.5 moles of freon forming from plasma, CO2, and BZ consumes.
NOBLIUM_FORMATION_MIN_TEMPThe maximum temperature hyper-noblium can form from tritium and nitrogen at.
NOBLIUM_FORMATION_MAX_TEMPThe maximum temperature hyper-noblium can form from tritium and nitrogen at.
NOBLIUM_FORMATION_ENERGYThe amount of energy a single mole of hyper-noblium forming from tritium and nitrogen releases.
REACTION_OPPRESSION_THRESHOLDThe number of moles of hyper-noblium required to prevent reactions.
HALON_FORMATION_MIN_TEMPERATUREThe minimum temperature required for halon to form from tritium and BZ.
HALON_FORMATION_MAX_TEMPERATUREThe maximum temperature required for halon to form from tritium and BZ.
HALON_FORMATION_ENERGYThe amount of energy 4.25 moles of halon forming from tritium and BZ releases.
HALON_COMBUSTION_ENERGYHow much energy a mole of halon combusting consumes.
HEALIUM_FORMATION_MIN_TEMPThe minimum temperature healium can form from BZ and freon at.
HEALIUM_FORMATION_MAX_TEMPThe maximum temperature healium can form from BZ and freon at.
HEALIUM_FORMATION_ENERGYThe amount of energy three moles of healium forming from BZ and freon releases.
ZAUKER_FORMATION_MIN_TEMPERATUREThe minimum temperature zauker can form from hyper-noblium and nitrium at.
ZAUKER_FORMATION_MAX_TEMPERATUREThe maximum temperature zauker can form from hyper-noblium and nitrium at.
ZAUKER_FORMATION_TEMPERATURE_SCALEThe temperature scaling factor for zauker formation. At most this many moles of zauker can form per reaction tick per kelvin.
ZAUKER_FORMATION_ENERGYThe amount of energy half a mole of zauker forming from hypernoblium and nitrium consumes.
ZAUKER_DECOMPOSITION_MAX_RATEThe maximum number of moles of zauker that can decompose per reaction tick.
ZAUKER_DECOMPOSITION_ENERGYThe amount of energy a mole of zauker decomposing in the presence of nitrogen releases.
PN_FORMATION_MIN_TEMPERATUREThe minimum temperature proto-nitrate can form from pluoxium and hydrogen at.
PN_FORMATION_MAX_TEMPERATUREThe maximum temperature proto-nitrate can form from pluoxium and hydrogen at.
PN_FORMATION_TEMPERATURE_SCALEThe temperature scaling factor for proto-nitrate formation. At most this many moles of zauker can form per reaction tick per kelvin.
PN_FORMATION_ENERGYThe amount of energy 2.2 moles of proto-nitrate forming from pluoxium and hydrogen releases.
PN_HYDROGEN_CONVERSION_THRESHOLDThe amount of hydrogen necessary for proto-nitrate to start converting it to more proto-nitrate.
PN_HYDROGEN_CONVERSION_MAX_RATEThe maximum number of moles of hydrogen that can be converted into proto-nitrate in a single reaction tick.
PN_HYDROGEN_CONVERSION_ENERGYThe amount of energy converting a mole of hydrogen into half a mole of proto-nitrate consumes.
PN_TRITIUM_CONVERSION_MIN_TEMPThe minimum temperature proto-nitrate can convert tritium to hydrogen at.
PN_TRITIUM_CONVERSION_MAX_TEMPThe maximum temperature proto-nitrate can convert tritium to hydrogen at.
PN_TRITIUM_CONVERSION_ENERGYThe amount of energy proto-nitrate converting a mole of tritium into hydrogen releases.
PN_TRITIUM_CONVERSION_RAD_RELEASE_THRESHOLDThe minimum released energy necessary for proto-nitrate to release radiation when converting tritium. (With a reaction vessel volume of CELL_VOLUME)
PN_TRITIUM_RAD_RANGE_DIVISORA scaling factor for the range of the radiation pulses generated when proto-nitrate converts tritium to hydrogen.
PN_TRITIUM_RAD_THRESHOLDThe threshold of the radiation pulse released when proto-nitrate converts tritium into hydrogen. Lower values means it will be able to penetrate through more structures.
PN_BZASE_MIN_TEMPThe minimum temperature proto-nitrate can break BZ down at.
PN_BZASE_MAX_TEMPThe maximum temperature proto-nitrate can break BZ down at.
PN_BZASE_ENERGYThe amount of energy proto-nitrate breaking down a mole of BZ releases.
PN_BZASE_RAD_RELEASE_THRESHOLDThe minimum released energy necessary for proto-nitrate to release rads when breaking down BZ (at a mix volume of CELL_VOLUME).
PN_BZASE_RAD_RANGE_DIVISORA scaling factor for the range of the radiation pulses generated when proto-nitrate breaks down BZ.
PN_BZASE_RAD_THRESHOLDThe threshold of the radiation pulse released when proto-nitrate breaks down BZ. Lower values means it will be able to penetrate through more structures.
PN_BZASE_NUCLEAR_PARTICLE_DIVISORA scaling factor for the nuclear particle production generated when proto-nitrate breaks down BZ.
PN_BZASE_NUCLEAR_PARTICLE_MAXIMUMThe maximum amount of nuclear particles that can be produced from proto-nitrate breaking down BZ.
PN_BZASE_NUCLEAR_PARTICLE_RADIATION_ENERGY_CONVERSIONHow much radiation in consumed amount does a nuclear particle take from radiation when proto-nitrate breaks down BZ.

Define Details

ATMOS_RADIATION_VOLUME_EXP

An exponent used to make large volume gas mixtures significantly less likely to release rads. Used to prevent tritfires in distro from irradiating literally the entire station with no warning.

BZ_FORMATION_ENERGY

The amount of energy 1 mole of BZ forming from N2O and plasma releases.

BZ_FORMATION_MAX_TEMPERATURE

The maximum temperature BZ can form at. Deliberately set lower than the minimum burn temperature for most combustible gases in an attempt to prevent long fuse singlecaps.

FIRE_CARBON_ENERGY_RELEASED

Amount of heat released per mole of burnt carbon into the tile

FIRE_FREON_ENERGY_CONSUMED

The amount of heat absorbed per mole of freon burnt.

FIRE_HYDROGEN_BURN_RATE_DELTA

The divisor for the maximum hydrogen burn rate. (1/2 of the hydrogen can burn in one reaction tick.)

FIRE_HYDROGEN_ENERGY_RELEASED

The amount of energy released by burning one mole of hydrogen.

FIRE_PLASMA_ENERGY_RELEASED

Amount of heat released per mole of burnt plasma into the tile

FIRE_TRITIUM_BURN_RATE_DELTA

The divisor for the maximum tritium burn rate. (1/2 of the tritium can burn in one reaction tick.)

FIRE_TRITIUM_ENERGY_RELEASED

The amount of energy released by burning one mole of tritium.

FREON_BURN_RATE_DELTA

The maximum fraction of the freon in a mix that can combust each reaction tick.

FREON_FORMATION_ENERGY

The amount of energy 2.5 moles of freon forming from plasma, CO2, and BZ consumes.

FREON_FORMATION_MIN_TEMPERATURE

The minimum temperature freon can form from plasma, CO2, and BZ at.

FREON_LOWER_TEMPERATURE

Minimum temperature allowed for the burn to go at max speed, we would have negative pressure otherwise

FREON_MAXIMUM_BURN_TEMPERATURE

The maximum temperature freon can combust at.

FREON_OXYGEN_FULLBURN

Multiplier for freonfire with O2 moles * FREON_OXYGEN_FULLBURN for the maximum fuel consumption

FREON_TERMINAL_TEMPERATURE

Terminal temperature after wich we stop the reaction

GAS_REACTION_MAXIMUM_RADIATION_PULSE_RANGE

Maximum range a radiation pulse is allowed to be from a gas reaction.

HALON_COMBUSTION_ENERGY

How much energy a mole of halon combusting consumes.

HALON_FORMATION_ENERGY

The amount of energy 4.25 moles of halon forming from tritium and BZ releases.

HALON_FORMATION_MAX_TEMPERATURE

The maximum temperature required for halon to form from tritium and BZ.

HALON_FORMATION_MIN_TEMPERATURE

The minimum temperature required for halon to form from tritium and BZ.

HEALIUM_FORMATION_ENERGY

The amount of energy three moles of healium forming from BZ and freon releases.

HEALIUM_FORMATION_MAX_TEMP

The maximum temperature healium can form from BZ and freon at.

HEALIUM_FORMATION_MIN_TEMP

The minimum temperature healium can form from BZ and freon at.

HOT_ICE_FORMATION_MAXIMUM_TEMPERATURE

The maximum temperature at which freon combustion can form hot ice.

HOT_ICE_FORMATION_MINIMUM_TEMPERATURE

The minimum temperature at which freon combustion can form hot ice.

HOT_ICE_FORMATION_PROB

The chance for hot ice to form when freon reacts on a turf.

HYDROGEN_MINIMUM_BURN_TEMPERATURE

The minimum temperature hydrogen combusts at.

HYDROGEN_OXYGEN_FULLBURN

Multiplier for hydrogen fire with O2 moles * HYDROGEN_OXYGEN_FULLBURN for the maximum fuel consumption

MIASTER_STERILIZATION_ENERGY

The amount of energy released when a mole of miasma is sterilized.

MIASTER_STERILIZATION_MAX_HUMIDITY

The maximum ratio of water vapor to other gases miasma can be sterilized at.

MIASTER_STERILIZATION_RATE_BASE

The minimum amount of miasma that will be sterilized in a reaction tick.

MIASTER_STERILIZATION_RATE_SCALE

The temperature required to sterilize an additional mole of miasma in a reaction tick.

MIASTER_STERILIZATION_TEMP

The minimum temperature miasma begins being sterilized at.

N2O_DECOMPOSITION_ENERGY

The amount of energy released when one mole of N2O decomposes into nitrogen and oxygen.

N2O_DECOMPOSITION_MAX_SCALE_TEMP

The other root of the parabola used to scale N2O decomposition rates.

N2O_DECOMPOSITION_MAX_TEMPERATURE

The maximum temperature N2O can decompose at.

N2O_DECOMPOSITION_MIN_SCALE_TEMP

One root of the parabola used to scale N2O decomposition rates.

N2O_DECOMPOSITION_MIN_TEMPERATURE

The minimum temperature N2O can decompose at.

N2O_DECOMPOSITION_RATE_DIVISOR

The maximum portion of the N2O that can decompose each reaction tick. (50%)

N2O_DECOMPOSITION_SCALE_DIVISOR

The divisor used to normalize the N2O decomp scaling parabola. Basically the value of the apex/nadir of (x - N2O_DECOMPOSITION_MIN_SCALE_TEMP) * (x - N2O_DECOMPOSITION_MAX_SCALE_TEMP).

N2O_FORMATION_ENERGY

The amount of energy released when a mole of N2O forms from nitrogen and oxygen in the presence of BZ.

N2O_FORMATION_MAX_TEMPERATURE

The maximum temperature N2O can form from nitrogen and oxygen in the presence of BZ at.

N2O_FORMATION_MIN_TEMPERATURE

The minimum temperature N2O can form from nitrogen and oxygen in the presence of BZ at.

NITRIUM_DECOMPOSITION_ENERGY

The amount of energy released when a mole of nitrium decomposes into nitrogen and hydrogen.

NITRIUM_DECOMPOSITION_MAX_TEMP

The maximum temperature nitrium can decompose into nitrogen and hydrogen at.

NITRIUM_DECOMPOSITION_TEMP_DIVISOR

A scaling divisor for the rate of nitrium decomposition relative to mix temperature.

NITRIUM_FORMATION_ENERGY

The amount of thermal energy consumed when a mole of nitrium is formed from tritium, nitrogen, and BZ.

NITRIUM_FORMATION_MIN_TEMP

The minimum temperature necessary for nitrium to form from tritium, nitrogen, and BZ.

NITRIUM_FORMATION_TEMP_DIVISOR

A scaling divisor for the rate of nitrium formation relative to mix temperature.

NOBLIUM_FORMATION_ENERGY

The amount of energy a single mole of hyper-noblium forming from tritium and nitrogen releases.

NOBLIUM_FORMATION_MAX_TEMP

The maximum temperature hyper-noblium can form from tritium and nitrogen at.

NOBLIUM_FORMATION_MIN_TEMP

The maximum temperature hyper-noblium can form from tritium and nitrogen at.

OXYGEN_BURN_RATIO_BASE

The maximum and default amount of plasma consumed as oxydizer per mole of plasma burnt.

PLASMA_BURN_RATE_DELTA

The divisor for the maximum plasma burn rate. (1/9 of the plasma can burn in one reaction tick.)

PLASMA_MINIMUM_BURN_TEMPERATURE

Minimum temperature to burn plasma

PLASMA_OXYGEN_FULLBURN

Multiplier for plasmafire with O2 moles * PLASMA_OXYGEN_FULLBURN for the maximum fuel consumption

PLASMA_UPPER_TEMPERATURE

Upper temperature ceiling for plasmafire reaction calculations for fuel consumption

PLUOXIUM_FORMATION_ENERGY

The amount of energy one mole of pluoxium forming from carbon dioxide, oxygen, and tritium releases.

PLUOXIUM_FORMATION_MAX_RATE

The maximum amount of pluoxium that can form from carbon dioxide, oxygen, and tritium per reaction tick.

PLUOXIUM_FORMATION_MAX_TEMP

The maximum temperature pluoxium can form from carbon dioxide, oxygen, and tritium at.

PLUOXIUM_FORMATION_MIN_TEMP

The minimum temperature pluoxium can form from carbon dioxide, oxygen, and tritium at.

PN_BZASE_ENERGY

The amount of energy proto-nitrate breaking down a mole of BZ releases.

PN_BZASE_MAX_TEMP

The maximum temperature proto-nitrate can break BZ down at.

PN_BZASE_MIN_TEMP

The minimum temperature proto-nitrate can break BZ down at.

PN_BZASE_NUCLEAR_PARTICLE_DIVISOR

A scaling factor for the nuclear particle production generated when proto-nitrate breaks down BZ.

PN_BZASE_NUCLEAR_PARTICLE_MAXIMUM

The maximum amount of nuclear particles that can be produced from proto-nitrate breaking down BZ.

PN_BZASE_NUCLEAR_PARTICLE_RADIATION_ENERGY_CONVERSION

How much radiation in consumed amount does a nuclear particle take from radiation when proto-nitrate breaks down BZ.

PN_BZASE_RAD_RANGE_DIVISOR

A scaling factor for the range of the radiation pulses generated when proto-nitrate breaks down BZ.

PN_BZASE_RAD_RELEASE_THRESHOLD

The minimum released energy necessary for proto-nitrate to release rads when breaking down BZ (at a mix volume of CELL_VOLUME).

PN_BZASE_RAD_THRESHOLD

The threshold of the radiation pulse released when proto-nitrate breaks down BZ. Lower values means it will be able to penetrate through more structures.

PN_FORMATION_ENERGY

The amount of energy 2.2 moles of proto-nitrate forming from pluoxium and hydrogen releases.

PN_FORMATION_MAX_TEMPERATURE

The maximum temperature proto-nitrate can form from pluoxium and hydrogen at.

PN_FORMATION_MIN_TEMPERATURE

The minimum temperature proto-nitrate can form from pluoxium and hydrogen at.

PN_FORMATION_TEMPERATURE_SCALE

The temperature scaling factor for proto-nitrate formation. At most this many moles of zauker can form per reaction tick per kelvin.

PN_HYDROGEN_CONVERSION_ENERGY

The amount of energy converting a mole of hydrogen into half a mole of proto-nitrate consumes.

PN_HYDROGEN_CONVERSION_MAX_RATE

The maximum number of moles of hydrogen that can be converted into proto-nitrate in a single reaction tick.

PN_HYDROGEN_CONVERSION_THRESHOLD

The amount of hydrogen necessary for proto-nitrate to start converting it to more proto-nitrate.

PN_TRITIUM_CONVERSION_ENERGY

The amount of energy proto-nitrate converting a mole of tritium into hydrogen releases.

PN_TRITIUM_CONVERSION_MAX_TEMP

The maximum temperature proto-nitrate can convert tritium to hydrogen at.

PN_TRITIUM_CONVERSION_MIN_TEMP

The minimum temperature proto-nitrate can convert tritium to hydrogen at.

PN_TRITIUM_CONVERSION_RAD_RELEASE_THRESHOLD

The minimum released energy necessary for proto-nitrate to release radiation when converting tritium. (With a reaction vessel volume of CELL_VOLUME)

PN_TRITIUM_RAD_RANGE_DIVISOR

A scaling factor for the range of the radiation pulses generated when proto-nitrate converts tritium to hydrogen.

PN_TRITIUM_RAD_THRESHOLD

The threshold of the radiation pulse released when proto-nitrate converts tritium into hydrogen. Lower values means it will be able to penetrate through more structures.

PRIORITY_FIRE

The priority used to indicate that a reactions should run after all other types of reactions. Exclusively used for combustion reactions that produce fire or are freon.

PRIORITY_FORMATION

The priority used for reactions that produce a useful or more advanced product. Goes after purgative reactions so that the purgers can be slightly more useful.

PRIORITY_POST_FORMATION

The priority used for indicate that a reactions should run immediately before most forms of combustion. Used by two decomposition reactions and steam condensation.

PRIORITY_PRE_FORMATION

The prority used to indicate that a reaction should run immediately at the start of a reaction cycle. Currently used by a jumble of decomposition reactions and purgative reactions.

REACTION_OPPRESSION_THRESHOLD

The number of moles of hyper-noblium required to prevent reactions.

SUPER_SATURATION_THRESHOLD

The minimum ratio of oxygen to plasma necessary to start producing tritium.

TRITIUM_MINIMUM_BURN_TEMPERATURE

The minimum temperature tritium combusts at.

TRITIUM_OXYGEN_FULLBURN

Multiplier for TRITIUM fire with O2 moles * TRITIUM_OXYGEN_FULLBURN for the maximum fuel consumption

TRITIUM_RADIATION_MINIMUM_MOLES

The minimum number of moles of trit that must be burnt for a tritium fire reaction to produce a radiation pulse. (0.01 moles trit or 10 moles oxygen to start producing rads.)

TRITIUM_RADIATION_RANGE_DIVISOR

A scaling factor for the range of radiation pulses produced by tritium fires.

TRITIUM_RADIATION_RELEASE_THRESHOLD

The minimum released energy necessary for tritium to release radiation during combustion. (at a mix volume of CELL_VOLUME).

TRITIUM_RADIATION_THRESHOLD

The threshold of the tritium combustion's radiation. Lower values means it will be able to penetrate through more structures.

WATER_VAPOR_CONDENSATION_POINT

The temperature required for water vapor to condense.

WATER_VAPOR_DEPOSITION_POINT

The temperature required for water vapor to condense as ice instead of water.

ZAUKER_DECOMPOSITION_ENERGY

The amount of energy a mole of zauker decomposing in the presence of nitrogen releases.

ZAUKER_DECOMPOSITION_MAX_RATE

The maximum number of moles of zauker that can decompose per reaction tick.

ZAUKER_FORMATION_ENERGY

The amount of energy half a mole of zauker forming from hypernoblium and nitrium consumes.

ZAUKER_FORMATION_MAX_TEMPERATURE

The maximum temperature zauker can form from hyper-noblium and nitrium at.

ZAUKER_FORMATION_MIN_TEMPERATURE

The minimum temperature zauker can form from hyper-noblium and nitrium at.

ZAUKER_FORMATION_TEMPERATURE_SCALE

The temperature scaling factor for zauker formation. At most this many moles of zauker can form per reaction tick per kelvin.