Thorium Glow Reactor[Time: 3 Progress: 3 Cost: 3]
Every organism needs energy, and the organisms that will be created will need more energy that most naturally occurring organisms could ever hope to achieve through typical organic reactions. Weaving something more potent, however, is not beyond our abilities. A challenge, yes, and one that shall tax us- but not one that shall break us.
Thorium Glow Reactor: 0/12 [2] | 100T + 250O + 50M | Rushed 0 Times | Nothing invested
Prototype[Efficacy: 3]
The working models we've been able to develop of an organic method 'digesting' Thorium are feasible, albeit perhaps more bulky than we had originally envisioned. The trick of the thing was to allow the organs to gain more energy from the material than was lost regenerating the tissues damaged by the reaction, and once that was achieved we had only to increase scale to make it viable power source. The actual reaction chamber is an area of dead tissue, similar in structure to that of dead coral, though the cellular walls encouraged to take on a variety of metallic elements to allow for the structural stability necessary to withstand the reactor's inner temperature. Through this chamber the reactor fluid flows, an organic but non-living slurry that pulses through a series of cooling channel into a substructure of organs which is responsible for transmuting the irradiated matter into usable energy before channeling the flow back to begin again. It's an effective first step at a bio-nuclear reactor, and there is a significant amount of protective tissue around the organ, but a breach would still cause the organ to 'bleed' harmful radiation into the surrounding tissues.
Thorium Glow Reactor: 150T 400O 50M 50E 0S | Capacity -25 | Power +125 | A bio-reactor capable of utilizing a thorium reaction to generate power. A bit on the large side, as necessitated by the tissue isolation, and capable of leaking poison when significantly damaged, but otherwise effective.
Sublight Drive Organ[Time: 2 Progress: 4 Cost: 3]
The troubles we encounter here are not of the basic question 'how do we do this' that is simple, and a young student of bio-weaving could likely devise something functional. The trick is how do we do it *well*. How can we use this to move at speed, without exhausting the biological systems or tearing them to pieces. It's an interesting problem, and one deserving of deep thought.
Sublight Drive Organ: 0/9 [2] 150O + 150E | Rushed 0 Times | Nothing invested
Prototype[Efficacy: 5]
From that deep thought, we've been able to extract a most elegant solution to the problem. Each SDO is of relatively small scale, capable of channeling a relatively small amount of organic gas into an excitement chamber- that excitement chamber can either eject it into the vacuum to provide reaction thrust, or it can inject it into another, larger, SDO to energize it further. In this manner, each SDO is actually composed of dozens of much smaller organs, branching downwards and pulsing with life. While the 'units' we've designed to integrate into the biology of a vessel are quite small by themselves, many of these highly efficient units can be added to increase the thrust and maneuverability of a vessel.
Sublight Drive Organ: | 75O + 50E | Capacity -4 | Power -4 | A small organelle, created from hundreds of small repeating structures that produce and energize gas, working together to create a sublight propulsion system for an organic craft. Acceleration is limited, and it's recommended to add multiple SDOs to a vessel, as their effects are additive and they work very well together.
Regenerating Chitinous Hull Plating[Time: 3 Progress: 3 Cost: 3]
Again, the questions we must ask ourselves are ones of optimization and efficacy. We know that we can do these things, but in what manner would generate the greatest effects. What materials must we give to these cells, what mitotic freedoms and self-discretion can we enable, and how can we control them to hold the shape we wish and rebuild only that when damaged.
Regenerating Chitinous Hull Plating: 0/7 [2] 175O + 75M | Rushed 0 Times | Nothing invested
Prototype[Efficacy: 4]
The outcome of our work is a favorable specimen, resilient to a hard-vacuum environment, and possessed of marvelous regenerative properties. The living tissue itself isn't terribly resilient to bombardment, but it is capable of forming complex lattice structures of a form of chitin that we've been able to impregnate with various strength and density enhancing materials. The resulting material is capable of absorbing a considerable amount of punishment, although it is still comparatively soft when compared to hardened metals. However, unlike hardened metals, this armor can regenerate in a combat relevant timeframe, allowing an equipped vessel the ability to regenerate somewhat from wounds if it can get breathing room.
Regenerating Chitinous Plating: | 20M +100O | Capacity -5 | A layer of soft pulp tissue, capability of generating a reinforced chitinous lattice to protect various sections of a ship. Capillary bloodflow limits the thickness of chitin a single layer of this tissue can generate, so multiple layers are advised for added protection.
Revision Phase of Year -5ResourcesDice: 1
T: 2500 + 2500
O: 7500 + 7500
M: 7500 + 7500
E: 5000 + 5000
S: 500 + 500
Advanced Bio-Modification: 2/7 [2] | 300 Organics + 100 Energetics | Rushed 0 Times | Nothing Invested
Telepathic Organ: 2/10 [2] | 175 Organics + 20 Metals +100 Energetics | Rushed 0 Times | Nothing Invested
Regenerating Chitinous Hull Plating: 0/7 [2] 175O + 75M | Rushed 0 Times | Nothing invested
Sublight Drive Organ: 0/9 [2] 150O + 150E | Rushed 0 Times | Nothing invested
Thorium Glow Reactor: 0/12 [2] | 100T + 250O + 50M | Rushed 0 Times | Nothing invested
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Topic: The Liir Biocollective Empire Thread | Liir | GalactiRace (Read 29639 times)