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@@ -223,13 +223,14 @@
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var/list/cached_scan_results = air.analyzer_results
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var/old_heat_capacity = air.heat_capacity()
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var/reaction_energy = 0 //Reaction energy can be negative or positive, for both exothermic and endothermic reactions.
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var/initial_plasma = cached_gases[/datum/gas/plasma][MOLES]
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var/initial_carbon = cached_gases[/datum/gas/carbon_dioxide][MOLES]
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var/initial_plasma = cached_gases[/datum/gas/plasma]
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var/initial_carbon = cached_gases[/datum/gas/carbon_dioxide]
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var/scale_factor = (air.volume)/(PI) //We scale it down by volume/Pi because for fusion conditions, moles roughly = 2*volume, but we want it to be based off something constant between reactions.
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var/toroidal_size = (2*PI)+TORADIANS(arctan((air.volume-TOROID_VOLUME_BREAKEVEN)/TOROID_VOLUME_BREAKEVEN)) //The size of the phase space hypertorus
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var/gas_power = 0
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var/list/gas_fusion_powers = GLOB.meta_gas_fusions
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for (var/gas_id in cached_gases)
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gas_power += (cached_gases[gas_id][GAS_META][META_GAS_FUSION_POWER]*cached_gases[gas_id][MOLES])
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gas_power += (gas_fusion_powers[gas_id]*cached_gases[gas_id])
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var/instability = MODULUS((gas_power*INSTABILITY_GAS_POWER_FACTOR)**2,toroidal_size) //Instability effects how chaotic the behavior of the reaction is
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cached_scan_results[id] = instability//used for analyzer feedback
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@@ -241,9 +242,9 @@
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carbon = MODULUS(carbon - plasma, toroidal_size)
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cached_gases[/datum/gas/plasma][MOLES] = plasma*scale_factor + FUSION_MOLE_THRESHOLD //Scales the gases back up
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cached_gases[/datum/gas/carbon_dioxide][MOLES] = carbon*scale_factor + FUSION_MOLE_THRESHOLD
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var/delta_plasma = initial_plasma - cached_gases[/datum/gas/plasma][MOLES]
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cached_gases[/datum/gas/plasma] = plasma*scale_factor + FUSION_MOLE_THRESHOLD //Scales the gases back up
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cached_gases[/datum/gas/carbon_dioxide] = carbon*scale_factor + FUSION_MOLE_THRESHOLD
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var/delta_plasma = initial_plasma - cached_gases[/datum/gas/plasma]
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reaction_energy += delta_plasma*PLASMA_BINDING_ENERGY //Energy is gained or lost corresponding to the creation or destruction of mass.
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if(instability < FUSION_INSTABILITY_ENDOTHERMALITY)
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@@ -252,19 +253,17 @@
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reaction_energy *= (instability-FUSION_INSTABILITY_ENDOTHERMALITY)**0.5
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if(air.thermal_energy() + reaction_energy < 0) //No using energy that doesn't exist.
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cached_gases[/datum/gas/plasma][MOLES] = initial_plasma
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cached_gases[/datum/gas/carbon_dioxide][MOLES] = initial_carbon
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cached_gases[/datum/gas/plasma] = initial_plasma
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cached_gases[/datum/gas/carbon_dioxide] = initial_carbon
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return NO_REACTION
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cached_gases[/datum/gas/tritium][MOLES] -= FUSION_TRITIUM_MOLES_USED
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cached_gases[/datum/gas/tritium] -= FUSION_TRITIUM_MOLES_USED
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//The decay of the tritium and the reaction's energy produces waste gases, different ones depending on whether the reaction is endo or exothermic
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if(reaction_energy > 0)
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air.assert_gases(/datum/gas/oxygen,/datum/gas/nitrous_oxide)
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cached_gases[/datum/gas/oxygen][MOLES] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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cached_gases[/datum/gas/nitrous_oxide][MOLES] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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cached_gases[/datum/gas/oxygen] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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cached_gases[/datum/gas/nitrous_oxide] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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else
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air.assert_gases(/datum/gas/bz,/datum/gas/nitryl)
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cached_gases[/datum/gas/bz][MOLES] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*-FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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cached_gases[/datum/gas/nitryl][MOLES] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*-FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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cached_gases[/datum/gas/bz] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*-FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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cached_gases[/datum/gas/nitryl] += FUSION_TRITIUM_MOLES_USED*(reaction_energy*-FUSION_TRITIUM_CONVERSION_COEFFICIENT)
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if(reaction_energy)
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if(location)
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@@ -3,10 +3,9 @@
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name = "nuclear particle"
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icon_state = "nuclear_particle"
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pass_flags = PASSTABLE | PASSGLASS | PASSGRILLE
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damage = 20
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damage_type = TOX
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irradiate = 2500 //enough to knockdown and induce vomiting
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speed = 0.4
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flag = "rad"
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irradiate = 5000
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speed = 0.4
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hitsound = 'sound/weapons/emitter2.ogg'
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impact_type = /obj/effect/projectile/impact/xray
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var/static/list/particle_colors = list(
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@@ -25,22 +24,6 @@
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add_atom_colour(particle_colors[our_color], FIXED_COLOUR_PRIORITY)
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set_light(4, 3, particle_colors[our_color]) //Range of 4, brightness of 3 - Same range as a flashlight
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/atom/proc/fire_nuclear_particles(power_ratio) //used by fusion to fire random # of nuclear particles - power ratio determines about how many are fired
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var/random_particles = rand(3,6)
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var/particles_to_fire
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var/particles_fired
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switch(power_ratio) //multiply random_particles * factor for whatever tier
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if(0 to FUSION_MID_TIER_THRESHOLD)
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particles_to_fire = random_particles * FUSION_PARTICLE_FACTOR_LOW
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if(FUSION_MID_TIER_THRESHOLD to FUSION_HIGH_TIER_THRESHOLD)
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particles_to_fire = random_particles * FUSION_PARTICLE_FACTOR_MID
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if(FUSION_HIGH_TIER_THRESHOLD to FUSION_SUPER_TIER_THRESHOLD)
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particles_to_fire = random_particles * FUSION_PARTICLE_FACTOR_HIGH
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if(FUSION_SUPER_TIER_THRESHOLD to INFINITY)
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particles_to_fire = random_particles * FUSION_PARTICLE_FACTOR_SUPER
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while(particles_to_fire)
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particles_fired++
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var/angle = rand(0,360)
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var/obj/item/projectile/energy/nuclear_particle/P = new /obj/item/projectile/energy/nuclear_particle(src)
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addtimer(CALLBACK(P, /obj/item/projectile.proc/fire, angle), particles_fired) //multiply particles fired * delay so the particles end up stagnated (once every decisecond)
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particles_to_fire--
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/atom/proc/fire_nuclear_particle(angle = rand(0,360)) //used by fusion to fire random nuclear particles. Fires one particle in a random direction.
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var/obj/item/projectile/energy/nuclear_particle/P = new /obj/item/projectile/energy/nuclear_particle(src)
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P.fire(angle)
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