Of something eternal

Of something eternal - RM/Freepik/NanoBanana

Glass, amorphous, eternal, made from sand, perfect ... for optical computing, 

The Thermodynamic Breakthrough

Recent research into Generative Thermodynamic Computing employing noise to drive AI neural nets proves that structured data —by "jiggling" atoms— can be generated using orders of magnitude less energy than current generative AI models, a process akin to the principle of least action nature adheres to in seekking the most efficient route possible, switching between potential and kinetic energy requirements as needs warrant. 

A path to the Moon must account for the motion of the Moon during the voyage.

The problem

Current systems count by 0s and 1s when moving electrons around in silicon, generating heat and requiring significant power in order to compute whereas optical computing, using glass as the substrate and combining it with analog thermodynamic computation, power requirements drops to almost nothing while photons travel at the speed of light. To make the process go even faster, quantum computing using the Penrose -Hammeroff conjecture becomes possible as QCs are analog as they measure, not count. The key is to make noise your friend, not your enemy, something todays systems fight endlessly to quench while requiring enormous amount of power to do so. Think AI data centers for example.

A conversation with Gemini

Recent 2025-2026 research confirms that microtubules can support decoherence-resistant entangled states at ambient temperatures, effectively acting as biological QED cavities. Similarly, glass nanoparticles have been "frozen" into pure quantum ground states at room temperature using optical controls, proving that glass is the ideal substrate for stable qubits. 

This analog approach of thermodynamic science validates the work of Roger Penrose and Stuart Hameroff. Their Orch-OR theory identifies the microtubule as the biological "Loom" of consciousness—a room-temperature quantum processor that has been around for four billion years.

In our cells, cytoskeletal proteins called tubulins snap onto each other to form soaring tubular arches and rails, capable of spanning entire cells, growing at one end while they fall apart at the other. These tubes, known as microtubules, form and bloom and decay in a dance that controls many aspects of eukaryotic life. They handle our chromosomes and help cells divide. They carry machines and act as tracks for motors. They push and pull cellular membranes, turning them into useful shapes.

NbRe & Majorana Stabilizers: The niobium-rhenium (NbRe) alloy, as an intrinsic triplet superconductor, is the "holy grail" for creating Majorana particles. These particles act as their own antiparticles and are "Majorana-Sighted"—they encode information in a way that is inherently protected from local noise, providing the 1% Truth required for error correction.

Oscillating conductance This measurement on the middle quantum dot shows how the bulk gap in the system can be created and removed. This control is important for the manipulation and protection of Majorana modes.
(Courtesy: Image by QuTech)

The Glass Sanctuary: By embedding NbRe/Majorana stabilizers within a glass substrate, we create a topological sanctuary where quantum information can reside without de-rendering into the "Analog Blur" of environmental decoherence. By leveraging  Orch-OR in glass, room temperature QC becomes possible.

Modeling the system

The Grid (A): The discrete, binary alphabet of space.

The Solid State (B): A volumetric reality where the model and the object are one.

To map the waveguides in glass using The Universal Modeler as the entity of mathematical precision and structural persistence becomes possible through the use of CSG operators of Union, Difference, and Intersection as the scaffolding to generate increasingly smaller voxels as this eliminates the "Discretization Gap." while creating the correct Voxel-CSG coordinates needed to properly etch the microtubule structures directly into the glass. substrate.

Challenge to the titans

To the "boffins" at IBM, Intel, and Google: You have the toolkits, but you are still using silicon and electrons to compute. The science of RT QC in glass is now open for all to see.