Quantum evaporation
Quantum evaporation represents a significant leap in the manipulation of matter on a grand scale, fundamentally altering the boundaries of thermodynamics and energy transfer. Unlike standard evaporation, where phase change occurs at the molecular or atomic level, Quantum evaporation involves the simultaneous removal of mass and energy from large-scale structures. This process is facilitated by advanced control over quantum vacuum energy fields and high-energy particle flux to destabilise the molecular cohesion of a material, causing its rapid dispersal without the traditional heat gradient required in conventional evaporation.
Research
| Tier | 6.500 | A decimal number between 0.0 and ~12.0 indicating the overall level of "advancement" of the science |
|---|---|---|
| Type | Pure | Pure sciences are focused on research and the improvement of knowledge. Applied sciences are too, but to a lesser extent and grant access to more concrete outcomes such as blueprints, governance, and others. |
Aspects
| Physical | Abstract | |
|---|---|---|
| Natural | 14 | 0 |
| Artificial | 3 | 1 |
Aspect tiers heatmap
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Blueprints
Coming soon.