Nullspace physics
Nullspace physics explores the interaction between standard spacetime and regions where conventional physical laws break down or cease to apply, because of their lack of measurable energy, matter, or spatial dimensions.
Central to the study of nullspace physics is the development of nullspace mapping algorithms, which attempt to chart these regions in relation to the fabric of spacetime. These maps are often built using quantum resonance techniques, detecting the subtle quantum noise emitted at the boundaries between nullspace and our universe. Matter behaves unpredictably near nullspace boundaries; its wavefunction tends to experience spontaneous collapse, leading to particle disintegration or total dephasing of quantum states.
The key challenge in this field is understanding how quantum fields, particles, and forces behave - or fail to behave - when they encounter these null-like regions.
Research
| Tier | 8.600 | 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 | 15 | 1 |
| Artificial | 7 | 1 |
Aspect tiers heatmap
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Blueprints
Coming soon.