Deuterium: Difference between revisions

Latest revision as of 20:35, 19 January 2024

Deuterium

Material, Fuel

A stable isotope of hydrogen. Rarely exists under natural conditions. Most of them come from the reprocessing of hydrogen and the collection from the Gas Giant.

Fuel Type		Chemical
Energy		9.00 MJ
Fuel Chamber Gen.		+100%
Made In		Fractionator, Particle Collider Cannot make in replicator
Gathered From		Gas Giant Orbit
Stack Size		20

5

2.5 s

10

1

1%

1

?

Summary

Deuterium is stable heavier isotope of Hydrogen. Rarely exists under natural conditions. Most comes from the reprocessing of hydrogen and collection from Gas Giants via Orbital Collectors.

Production Chain

Recipe	Building	Replicator?	Technology
1 1 % 1		✖
5 2.5 s 10		✖
1 ?		⛏️

Production Progression Chart

For more information on reading and using these charts, see Production Progression Chart.

Click here to show or hide the Production Progression Charts.

Critical Photon-based production
Stage 1	Stage 2	Stage 3
2	2 2	2 2

Fire Ice-based production
Stage 1	Stage 2	Stage 3
2	1 2	1 2

Crude Oil-based production
Stage 1	Stage 2	Stage 3	Stage 4
2	1 2	3 2	3 2

Note: Hydrogen created during Crude Oil-based production must be recycled through the system to ensure full efficiency. Final stage quantities are remaining surplus available for distribution.

Used In

Recipe	Building	Replicator?	Technology
2 12 s 1 20 1		✔
1 8 s 2 2 10		✖
1 2 s 1 2 10		✔

Player Tips & Tricks

Using Fractionators to produce Deuterium is roughly 2.5 times more energy efficient (using Mk.III Conveyor Belts) than Particle Colliders. It takes more space to set up but works in a simple loop (with a buffer liquid storage slowly refilled with Hydrogen). A Fractionator processing Hydrogen piled four times using the Automatic Piler consumes 1.375 times as much energy per Deuterium as a normal Fractionator, with throughput closer to the Particle Collider's Deuterium production, and it can be a middle ground on energy usage and space while retaining the 1:1 Hydrogen to Deuterium conversion.

Comparative Data
Units	Fractionator	Particle Collider	Fractionator 4-stack
kW (kJ/s)	720	12000	3960
Deuterium /s	0.3	2	1.2
kJ per Deuterium	2400	6000	3300

@@ Line 29: / Line 29: @@
      |Out1=Deuterium
      |Out1Qty=5
-     |CraftTime=5 s
+     |CraftTime=2.5 s
      |In1=Hydrogen
      |In1Qty=10
@@ Line 37: / Line 37: @@
 {{ProductionChain
 |Building=Orbital Collector
-|Replicator=No
+|Replicator=Mine
 |Technology=Gas Giants Exploitation
 |Recipe=
@@ Line 43: / Line 43: @@
      |Out1=Deuterium
      |Out1Qty=1
+    |In1=Gas Giant
+    |In1Qty=
      |CraftTime=?
    }}
@@ Line 49: / Line 51: @@
 ==Production Progression Chart==
+{{ProgressionChartCollapsible/begin}}
 {| class="wikitable" style="text-align:center; background-color:#0b161c
 |+Critical Photon-based production
@@ Line 81: / Line 84: @@
 | {{riq|Deuterium|3}} {{riq|Energetic Graphite|2}}
 |}
-'''Note:''' [[Hydrogen]] created during Crude Oil-based production must be recycled through the system to ensure full efficiency.  Final stage quantities are remaining surplus available for distribution.
+'''Note:''' [[Hydrogen]] created during [[Crude Oil]]-based production must be recycled through the system to ensure full efficiency.  Final stage quantities are remaining surplus available for distribution.
+{{ProgressionChartCollapsible/end}}
 ==Used In==
@@ Line 92: / Line 96: @@
    {{ItemRecipe
      |Out1=Deuteron Fuel Rod
-     |Out1Qty=1
+     |Out1Qty=2
-     |CraftTime=6 s
+     |CraftTime=12 s
      |In1=Titanium Alloy
      |In1Qty=1
      |In2=Deuterium
-     |In2Qty=10
+     |In2Qty=20
      |In3=Super-Magnetic Ring
      |In3Qty=1
@@ Line 120: / Line 124: @@
    }}
 }}
+|-
+{{ProductionChain
+|Building=Assembler
+|Replicator=Yes
+|Technology=Plasma Turret
+|Recipe=
+  {{ItemRecipe
+    |Out1=Plasma Capsule
+    |Out1Qty=1
+    |CraftTime=2 s
+    |In1=Graphene
+    |In1Qty=1
+    |In2=Magnet
+    |In2Qty=2
+    |In3=Deuterium
+    |In3Qty=10
+    }}
+  }}
 |}
 ==Player Tips & Tricks==
-*Using Fractionators to produce Deuterium is roughly five times more energy efficient (using [[Conveyor Belt Mk.III|Mk.III Conveyor Belts]]) than [[Miniature Particle Collider|Particle Colliders]]. It takes more space to setup, but works in a simple loop (with a buffer liquid storage slowly refilled with Hydrogen).
+*Using [[Fractionator|Fractionators]] to produce Deuterium is roughly 2.5 times more energy efficient (using [[Conveyor Belt Mk.III|Mk.III Conveyor Belts]]) than [[Miniature Particle Collider|Particle Colliders]]. It takes more space to set up but works in a simple loop (with a buffer liquid storage slowly refilled with Hydrogen).  A Fractionator processing Hydrogen piled four times using the [[Automatic Piler]] consumes 1.375 times as much energy per Deuterium as a normal Fractionator, with throughput closer to the Particle Collider's Deuterium production, and it can be a middle ground on energy usage and space while retaining the 1:1 Hydrogen to Deuterium conversion.
 {| class="wikitable"
 |+ Comparative Data
 |-
-! Units !! Fractionator !! Particle Collider
+! Units !! Fractionator !! Particle Collider !! Fractionator 4-stack
 |-
-| kW (kJ/s) || 720 || 12000
+| kW (kJ/s) || 720 || 12000 || 3960
 |-
-| Deuterium /s|| 0.3 || 1
+| Deuterium /s|| 0.3 || 2 || 1.2
 |-
-| kJ per Deuterium || 2400 || 12000
+| kJ per Deuterium || 2400 || 6000 || 3300
 |}
+{{Item Navbox}}
 [[Category:Item]]
 [[Category:Components]]