I would like to detail the design of GMT layer by layer, explaining the reasoning behind them by the laws of physics and calculations. Finally, how GMT can be manufactured with today’s technologies. Let’s start from the lowest layer where the GMT is attached to the heat source and move up to the collector where the electricity is harvested.
The Source: This is forms the base of the GMT structure. GMT manufacturing requires atom by atom building of layers. Therefore, Chemical Mechanical Polished wafer is used for extreme smoothness. The system requires the heat from the heat source to travel inside the GMT. Therefore, Silicon wafer will be highly doped with Nickel and have a thick Ni coating on its bottom. Ni doped Silicon create a metallic-like conductivity in the wafer. This ensures that when the electrons are "pulled" from the ground into the GMT-X, there is minimal resistive heating at the interface. Also, the Nickel-rich interface provides a sharp change in impedance. Nickel creates a Degenerate Semiconductor state. This means the Silicon behaves like a metal because the "Fermi level" is pushed into the conduction band. This is what helps reflect the 10 GHz electromagnetic wave back through the stack to maintain the Self-Sustaining Oscillation (SSO).
Additionally, growing the first layer of h-BN directly on this doped wafer creates the initial energy barrier. Only the "hottest" electrons from the Si have the kinetic energy to tunnel into that first h-BN layer. Nickel has a relatively low lattice mismatch with hexagonal Boron Nitride. This helps the h-BN grow with high crystallinity, ensuring the "floor" of the device is smooth and defect-free. The doped wafer acts as a massive, uniform reservoir of electrons. Whether a CNT grows at point A or point B on the wafer, it sees the exact same "ground" potential.
Starting with h-BN on the wafer prevents the wafer lattice (the vibrations) from stealing the electron energy. It acts as a thermal insulator for phonons while remaining a quantum "tunnel" for electrons. It turns the wafer from a "heat sponge" into a "one-way electron injector". It also provides the hexagonal template that encourages the CNTs to grow vertically rather than tangling horizontally.
The GMT Stages: These stages are made of SWCNT (Single Walled Carbon Nano Tube) and h-BN (hexagonal Boron nitride) layers.
GMT-X surface is not a single machine, but a stadium with millions of turnstiles. It doesn't matter if some turnstiles are a few millimeters to the left or right of where they should be.
What matters is that every turnstile operates at the same 100ps speed and has the same 13-stage gate. By growing the h-BN first (on the wafer), we ensure every turnstile is bolted to a perfectly level floor.
GMT stages only require vertical perfection (just 100 nm). This is where the physics happens. Every stage must be aligned, and the thickness must be precise to maintain the 10 GHz resonance and the tunneling probability. If a single stage is too thick, the electron loses its phase and the system fails. In quantum mechanics, this is called Phase Coherence Length. Because GMT has 13 stages, the electron must travel the entire 100 nm without "bumping" into an atom (scattering). If a layer is too thick, the electron scatters, loses its "memory" of the 10 GHz pulse, and turns back into random heat. In the horizontal axis each CNT acts as an independent quantum channel, it doesn't matter if the density of the "forest" varies or if the tubes aren't perfectly spaced. As long as they are all upright and parallel to the electrical field, they will all contribute to the total current.
Each GMT stage is composed of a "Filter" (h-BN) and then to the "Express Lane" (SWCNT).
I chose h-BN (hexagonal Boron Nitride) because it is the only material that satisfies contradictory requirements for a "Quantum Gatekeeper" simultaneously:
1. The "Goldilocks" Dielectric Strength: To gate electrons at 10 GHz, the material should be able to withstand intense local electric fields without breaking down. h-BN has a dielectric strength of roughly 0.8 V/nm. Because the layers are only 0.66 nm thick, h-BN can hold the "gate" closed against "cold" electrons without suffering from electron avalanche (sparking through the material), which would destroy a standard oxide.
2. Atomic Flatness and Lattice Matching: h-BN is a 2D crystal. It provides a perfectly hexagonal "floor" that matches the carbon lattice of the CNTs. Standard insulators have "dangling bonds" at the surface that "trap" electrons and create noise. h-BN is chemically inert and "slick" at the atomic level, meaning it doesn't "grab" the ballistic electrons as they tunnel through.
3. The Phonon-Electron Separator: Most good electrical insulators are also good thermal insulators, but h-BN is unique. It conducts heat very well. Because the layers are only held together by weak Van der Waals forces, it is a poor conductor of vertical heat. By using two layers with a 1.1° twist, a "poor" thermal conductor is turned into a "zero" thermal conductor for specific phonon frequencies, effectively creating a thermal mirror while remaining an electronic window.
4. Chemical and Thermal Stability: Since GMT-X might be mounted on high-heat sources, we need a filter that won't melt or oxidize. h-BN is stable in air up to nearly 1000°C, far exceeding the limits of polymer-based insulators or even some metals.
In GMT design, the 1.1° twist of h-BN layers isn't just a geometric detail; it’s a Phonon Trap. At a 1.1° angle (the "Magic Angle"), the atomic lattices of the two h-BN layers create a massive Moiré superlattice. This periodically varying potential creates Phonon Bandgaps. Lattice vibrations (heat) that would normally zip through the material at the speed of sound get "stuck" or reflected by this interference pattern. This is how heat is slowed to be gated at 10 GHz. To be technically precise, the 1.1° twist creates a Phonon Bandgap. In standard materials, phonons move at the speed of sound. In twisted h-BN, certain "heat frequencies" are literally forbidden from passing through, which is why the 10 GHz gate can "outrun" them.
h-BN layer thickness is only 0.66nm. Quantum tunneling probability decays exponentially with thickness. At 0.66 nm (two atomic layers), the barrier is thin enough for a "hot" electron to "teleport" through almost instantly. If a third layer (~1.0 nm) is added, the "opacity" to electrons increases significantly. We would lose the current density. 0.66 nm is the "Sweet Spot" where phonon blocking is maximized but electron transparency remains high.
GMT requires a material with a mean free path longer than the total device thickness (100 nm). Carbon Nanotubes are one of the few materials where electrons can travel hundreds of nanometers without a single collision (Ballistic Transport).
The thickness of the SWCNT layer is 7 nm. This relates to the RC Time Constant and Vertical Coherence. If the SWCNT stages are too long, the electron spends too much time in the "express lane," and the 10 GHz gating pulse might change state before the electron reaches the next barrier. At 7 nm, the "flight time" of a ballistic electron is perfectly synchronized with the 100ps window.
The GMT stages have a limit of 100 nm. It is dictated by the wavelength of the 10 GHz gating signal and the Phase Coherence of the electrons. In physics, this is the boundary where the device stops acting like a collection of parts and starts acting like a single, synchronized quantum system.
A 10 GHz signal has a very specific period (100ps). For the gating to be effective, every one of the 13 stages must "feel" the same electric field at the same time. If the total stack were much thicker (e.g., 1000 nm), the electromagnetic wave would take too long to travel from the bottom to the top. This creates a phase shift. At 100 nm, the entire stack is well within the "near-field" of the 10 GHz pulse. This ensures the "Quantum Gatekeeper" closes all 13 doors simultaneously.
Even in a perfect material like a SWCNT, electrons eventually "forget" their initial energy and direction due to rare interactions with the lattice. The Mean Free Path (the distance an electron travels before "bumping" into something) for ballistic transport in high-quality CNTs is typically around 100 nm to 200 nm at room temperature. By keeping the total GMT-13 stack at 100 nm, we ensure the electron completes its entire journey from the wafer to the collector as a "ballistic bullet" without losing its kinetic energy to the lattice.
For the Self-Sustaining Oscillation (SSO) to work, the reflected wave from the Tungsten layer must arrive back at the first stage while the next group of electrons is ready. This 100 nm distance is the "sweet spot" where the time it takes for the electron to fly up and the reflected pulse to fly down is perfectly tuned. If the stack were thicker, the "echo" (reflection) would arrive too late, and the system would lose its rhythm.
Final note: Each GMT layer is 7.66 nm. For a 100nm limit, 13 layers is the maximum. That's why GMT has 13 GMT stages stacked one above the other between the Source and the Collector/Gate.
Collector / Gate: In the GMT architecture, the top layer acts as both the Energy Harvester (Collector) and the Signal Generator (Gate). This dual-purpose design is what allows the system to be "monolithic" (self-contained).
The Collector (DC Path): It must capture the high-energy ballistic electrons that have successfully sprinted through the 13 stages. These electrons accumulate here, creating the high-potential side of the "quantum battery."
The Gate (RF Path): Simultaneously, this layer must act as a high-frequency antenna. It reflects the 10 GHz electromagnetic wave back down the stack. This "echo" provides the field that gates the h-BN barriers for the next incoming wave of electrons.
The collector is a combination of Tungsten and Polycrystalline Silicon (Poly-Si) for very specific physical reasons. Tungsten (W) is chosen for reflection. To create a "Self-Sustaining Oscillation," we need a sharp Impedance Mismatch. Tungsten is a dense metal with a high electron density. When the 10 GHz signal hits the interface between the CNTs and the Tungsten, it doesn't just pass through—it reflects. Like a mirror reflecting light, the Tungsten reflects the electric field pulse back toward the wafer. Poly-Si is chosen for work function matching. Directly contacting CNTs with metal can sometimes create "Schottky Barriers" (electrical speed bumps). A thin layer of highly doped Poly-Si between the CNTs and the Tungsten acts as a "buffer," ensuring the electrons slide into the collector with zero resistance (Ohmic contact). The Tungsten layer itself must be thicker than the skin depth of a 10 GHz signal (which is about 500–700 nm for W) to ensure 100% of the signal is reflected and none leaks out the top.
At the very top of the GMT module, there would be copper for its lower resistance. It would be plated with Nickel to prevent oxidation and allow good solder adhesion.
The GMT would be started by an external pulse. Likely an of /off pulse from a capacitor. These pulses would be repeated to ensure the proper start of the system. Once the oscillations are sustained, GMT would generate power from its collector output. The critical thing is, after every part the collector should be shorted to a capacitor and then flushed to the system. GMT requires its excess electrons to be removed from its Collector and returned back to the Source as cold electrons. This completes the Quantum Circuit. It ensures the device doesn't "clog up" with charge, which would create a counter-electromotive force (back-EMF) and stop the tunneling.
The power output estimate of a 13-layer GMT module is: 5.85V (0.45V x 13) and 20 A/cm², resulting in a design-rated output of 117 W/cm². If the heat source provides 122 W/cm², the GMT achieves 96% efficiency. The remaining 4% represents the unavoidable energy consumed by the gating process and thermal leakage through leads and insulation.
