Definitions by Dumuabzu

A speculative framework extending the macroatom concept to truly macroscopic scales—objects large enough to see and touch that behave as if they were single "atoms" in a higher-level physics. The Hypothesis of Hyperatoms suggests that with sufficient engineering, we could create macroscopic entities with quantized states, discrete energy levels, and the ability to bond into larger structures—a kind of "chemistry" at the human scale. Hyperatoms would be the ultimate expression of modular design: everything built from identical, interchangeable units that themselves have internal structure but function as atoms in a larger system. It's Lego at the atomic level, but with real physics.

A speculative framework proposing that structures larger than atoms—molecules, nanoparticles, even engineered materials—can behave as if they were individual "atoms" in a larger-scale physics. The Hypothesis of Macroatoms suggests that under certain conditions, collections of atoms can act as unified entities, exhibiting properties (quantized states, bonding, energy levels) analogous to those of individual atoms. These macroatoms could form the basis for a new kind of chemistry and physics at larger scales—where "molecules" are made of macroatoms, and "materials" are crystal lattices of these larger units. The hypothesis opens the door to engineering matter at every scale, not just the atomic.

A speculative framework proposing that classical physics itself might emerge from quantum mechanics in ways that allow "hyperquantum" phenomena—quantum-like effects appearing in classical systems under certain conditions. The Hypothesis of Hyperquantum Mechanics suggests that the boundary between quantum and classical is not sharp but fuzzy, and that classical systems might exhibit behaviors that look quantum if viewed appropriately. This could include analogies to superposition in classical waves, entanglement-like correlations in complex systems, or tunneling in classical potentials. Hyperquantum mechanics doesn't claim that classical systems are quantum; it claims that the mathematics of quantum mechanics might have classical analogues that reveal deeper unity in physics.

A speculative framework proposing that quantum phenomena—superposition, entanglement, tunneling—can occur at macroscopic scales, not just in the atomic realm. The Hypothesis of Macroquantum Mechanics suggests that there is no fundamental size limit to quantum behavior; with the right conditions (extreme isolation, low temperature, careful preparation), macroscopic objects could exhibit quantum properties. This would mean Schrödinger's cat is not just a thought experiment but a real possibility—objects large enough to see could be in superpositions, entangled with each other, tunneling through barriers. Macroquantum mechanics would bridge the gap between quantum weirdness and classical reality, showing that the strange rules of the small can scale up to the large.

A speculative framework proposing that retrocausality—future events influencing the past—is a real physical phenomenon, not just a mathematical curiosity. The Hypothesis of Retrocausality suggests that time's arrow is not fundamental but emergent, and that at deeper levels, causation flows both ways. This could resolve quantum paradoxes (like wavefunction collapse), explain non-locality, and even open possibilities for time-symmetric physics. The hypothesis is not yet proven, but it offers a elegant way to think about quantum mechanics: the future and past are in dialogue, each shaping the other. It's a radical reimagining of causality itself.

A hypothetical phenomenon where effects precede their causes—where the future influences the past, rather than the other way around. Retrocausality challenges our most fundamental intuition about time: that cause always comes before effect. In retrocausal scenarios, an event in the present could be caused by something in the future; decisions yet to be made could shape history already written. While this sounds like science fiction, certain interpretations of quantum mechanics (the transactional interpretation, Wheeler's delayed-choice experiments) hint that retrocausality might be real at the quantum level. Particles seem to "decide" their past based on future measurements. Retrocausality asks: what if time's arrow is not as fixed as we think? What if the future is already influencing the present, and we just can't see it?

The dilemma that all evidence is interpreted through pre-existing frameworks (theories, biases, cultural narratives). There is no such thing as a "brute fact." A piece of data only becomes evidence for or against something within a specific story about how the world works. Changing someone's mind therefore requires not just new facts, but a change in their entire interpretive framework—a much harder task.