Stas Rutkowski

The universe doesn’t start as matter. It starts as possibility. Waves first. Reality second. What we call “matter” isn’t the starting point, it’s what’s left after interactions settle things down. At the fundamental level, physics doesn’t deal in solid objects. It deals in fields, amplitudes, and probabilities. Not things, but ways things could be. Before interaction, a system isn’t “this or that.” It’s a spread of possibilities described by a wavefunction. And then something happens. Interaction. Measurement. Coupling. Call it what you want, but that’s the moment where possibilities stop being interchangeable and start producing outcomes. Not everything survives that process. Most of it cancels out, decoheres, or never becomes accessible at all. What we observe is the tiny slice that makes it through. That’s what we call reality. So it’s not that the universe is made of solid building blocks that occasionally behave like waves. It’s the opposite. The wave-like structure is the full description. “Particles” are what emerge when that structure is filtered through interaction. That’s why you don’t observe reality directly. You observe what survives contact with your measurement. Everything else is still there in the math but it’s no longer part of your accessible world. So when people ask “what is the universe made of?” they’re already skipping a step. It’s not made of things. It’s made of possibilities that get reduced into things. Waves first. Reality second.

🚨 BREAKING: Electronics just survived near absolute zero… and didn’t fail. That shouldn’t be possible. Most semiconductors die below -173°C (100K) Quantum computers run at ~4K → That gap has been a hard wall. Until now. Scientists built working transistors using gallium oxide (β-Ga₂O₃) that operate down to: 2 Kelvin (-271°C) Almost absolute zero. Here’s why this matters: Normal chips fail because of “freeze-out”: • Electrons stop moving • Dopants can’t release charge • Circuits basically go dead Cold = no carriers = no electronics But this material breaks that rule: • Ultra-wide bandgap → stable structure • Low leakage → clean signals • No freeze-out → electrons still move Meaning: Electronics can now operate where physics normally shuts them down Why this is huge: • Quantum computers → control electronics can sit closer to qubits • Space tech → deep-space probes won’t freeze • Sensors → extreme environments become usable The deeper shift: We’ve always designed electronics for heat limits Now we’re engineering for cold limits That’s a completely different frontier. Follow me I track where physics becomes engineering.