Conserved Causality Theory

A theoretical hypothesis proposing that faster-than-light (FTL) phenomena, including warp drives and communications outside normal spacetime, preserve causality by appearing to observers within spacetime as if they were traveling at luminal speeds. This hypothesis extends the conserved causality principle to FTL scenarios by suggesting that spacetime functions like a computer plane: spectators (entities outside spacetime) perceive and maintain the causal relationships that observers (entities within spacetime) experience as potentially paradoxical. In practical terms, a warp drive doesn't violate causality because from the perspective of any observer within spacetime, its effects propagate exactly as if constrained by light speed—even though "outside," something else is happening. This elegantly resolves FTL paradoxes (like the tachyonic antitelephone) by proposing that causality is preserved not within spacetime but by the larger dimensional context in which spacetime is embedded.

A hypothesis in theoretical physics and FTL research that states that even with faster‑than‑light travel or communication, causality would not be violated because some underlying mechanism would prevent messages from being received before they are sent. This could be due to the topology of spacetime (e.g., wormholes that are time‑like but still globally causal), limits on the kinds of trajectories that can be realized, or quantum effects that enforce temporal ordering. The hypothesis is essential for making FTL concepts physically plausible, as the standard argument against FTL is that it would allow backward time travel and paradoxes. If causality is preserved in all FTL scenarios, then such paradoxes would be impossible.

A bold extension of Preserved Causality, proposing that causality itself has elastic properties—that causal relationships can be stretched, compressed, or warped without breaking. Causality Elasticity suggests that the causal order of events is not rigidly fixed but can be manipulated within limits, much like spacetime. This could allow for novel information processing (causal computers), communication schemes, or even a deeper understanding of quantum mechanics where causal order is superposed. It's the idea that causality, like spacetime, is a field—and fields can be engineered.

A principle proposing that causality is subject to a conservation law—that the total amount of causal structure in the universe remains constant. Conservation of Causality suggests that you can't create new causes or destroy old effects; you can only rearrange causal relationships. This has implications for time travel (you can't create paradoxes because causality is conserved), for quantum mechanics (entanglement redistributes causality), and for free will (our choices are causal transactions, not violations). It's causality as a budget: you can spend it, but you can't print it.

A framework emphasizing that causality is preserved across all physical interactions, no matter how extreme. Preservation of Causality suggests that cause and effect are not just regularities but inviolable structures of reality. Even in quantum mechanics, even in general relativity, even in speculative physics—causes precede effects. The theory doesn't explain how; it posits that preservation is fundamental. It's the physicist's article of faith: causality holds, always and everywhere.

A fundamental principle proposing that causality is conserved—like energy, momentum, or charge—across all physical interactions. Theory of Conservation of Causality suggests that cause-effect relationships cannot be created or destroyed, only transformed or redistributed. In this framework, apparent causality violations (quantum indeterminacy, time travel paradoxes) are actually transformations: causality moves elsewhere, changes form, but the total causal structure remains constant. The theory provides a budget for reality: you can spend causal influence, but you can't print it. Every effect must be paid for by a cause somewhere, sometime.