Interdimensional Mechanics

The branch of physics describing how objects move through the spaces between dimensions, navigating the gaps where normal physical laws don't quite apply. This field explains phenomena like teleportation (briefly exiting our dimensional framework and re-entering at a different point), invisibility (shifting into the gap between dimensions where light doesn't interact), and that weird moment when you walk into a room and forget why (your intention momentarily slipped into the interdimensional gap and hasn't returned). Interdimensional mechanics requires a new kind of mathematics, one that can handle undefined spaces and non-existent coordinates, which is challenging for a field that likes things to be, you know, defined.

The branch of physics describing how objects move through all dimensions simultaneously, accounting for the fact that every object exists not just in 3D space but across the entire dimensional spectrum. In multidimensional mechanics, your position isn't a point—it's a vector with components in every dimension, most of which you can't perceive. Your movement through 3D space is just the visible projection of a much more complex multidimensional trajectory. This explains why you sometimes feel like you're going in circles even when you're walking straight—your multidimensional vector is looping through higher dimensions while your 3D projection plods along.

The branch of physics describing motion through hyperdimensional space—realms with so many dimensions that the very concept of "motion" becomes meaningless, since you're already everywhere at once. In hyperdimensional mechanics, objects don't move; they simply are, in all possible configurations simultaneously. Position, velocity, acceleration—these are 3D concepts that don't apply in hyperdimensional contexts. What does apply is a kind of pure mathematical existence, where objects are defined not by coordinates but by relationships, and motion is replaced by "reconfiguration." This is either profound physics or a really fancy way of saying "stuff is complicated."

The branch of six-dimensional physics describing how objects move and change through the combined manifold of space, time, probability, and initial conditions. In 6D mechanics, every object has a trajectory determined not just by its current position and momentum (3D), not just by its evolution through time (4D), not just by its probability branch (5D), but by its complete initial state—the full specification of its beginning. This mechanics explains why systems with identical current states can evolve differently if their initial conditions differed (the paths converged temporarily but will diverge again). It explains why history is encoded in present behavior—the initial conditions are still active, still shaping motion. And it explains why prediction requires knowing not just where something is now, but where it started.

The integration of quantum mechanics with spacetime, treating quantum phenomena as occurring within the four-dimensional fabric of relativity. In spacetime quantum mechanics, particles are not point-like objects moving through time but four-dimensional worldlines with quantum properties—they exist in superpositions across spacetime, entangle across distances without signal, and pop in and out of existence in ways that respect relativistic causality. This framework is the foundation of quantum field theory, where particles are excitations of fields that permeate spacetime, and where the vacuum itself is alive with virtual particles. Spacetime quantum mechanics explains why empty space isn't really empty, why particles can appear from nowhere (briefly), and why the universe at its smallest scales is a frothing, probabilistic mess.

The extension of quantum mechanics into five dimensions, where quantum phenomena are understood as interactions across probability space as well as spacetime. In this framework, superposition is not just a particle being in multiple states at once but a particle existing across multiple probability branches simultaneously. Entanglement is not just correlation across distance but connection across probability space—particles share probability coordinates. Wavefunction collapse is not a mysterious physical process but the synchronization of observation across probability branches. Spacetime-probability quantum mechanics explains why quantum phenomena seem so strange: we're only seeing the spacetime slice of a five-dimensional reality. The weirdness is in the projection, not the reality.

The full six-dimensional quantum framework, where quantum phenomena are understood as unfolding across space, time, probability, and the full spectrum of initial conditions. In this framework, the quantum state of a system includes not just its spacetime coordinates and probability branches but its complete history—the initial conditions that shaped its evolution. This theory explains why quantum systems retain information about their past, why measurements can reveal not just current state but historical trajectory, and why the universe at its most fundamental level is a record of everything that ever happened. Spacetime-probability-initial conditions quantum mechanics is the physics of memory at the quantum level, where the past is not lost but encoded in the present.