From Cannabis Fund to Nuclear Power: The Audacious Pivot of Nuclear Diamond Batteries, Inc.

MESQUITE, NV – December 29, 2025 – In a corporate transformation that signals a seismic shift in strategy, Nuclear Diamond Batteries, Inc. has officially completed its rebranding, a move that formally distances the company from its past and stakes its future on one of the most advanced and ambitious energy technologies today. Trading on OTC Markets under its existing ticker symbol, WEDG, the company's new name crystallizes a pivot that began with the acquisition of a controlling interest in Atomiq, Inc., a firm holding key patents for so-called "never charge" nuclear diamond batteries.

This isn't just a name change; it's a declaration of intent. The company, formerly known as Weed Growth Fund Inc., has shed its speculative past to pursue a future in deep technology. The move aims to position the firm at the vanguard of a niche but potentially transformative market for ultra-long-duration power sources, targeting high-value sectors from aerospace to implantable medical devices. While the promise is immense—miniature power cells that can last for thousands of years—the path is fraught with technical, regulatory, and commercial challenges.

A Strategic Metamorphosis

The journey to becoming Nuclear Diamond Batteries, Inc. is a story of radical corporate reinvention. Public records indicate the company's previous incarnation, Weed Growth Fund Inc., had a vastly different focus. The transition underscores a calculated decision to enter the high-stakes world of advanced energy by acquiring specialized intellectual property.

The linchpin of this strategy is Atomiq, Inc. This subsidiary, formed in late 2024 by Kronos Advanced Technologies, Inc. (OTC: KNOS), was created specifically to commercialize a portfolio of patents related to betavoltaic power. In March 2025, Atomiq announced a major milestone: a Notice of Allowance from the U.S. Patent and Trademark Office for an application titled "NUCLEAR VOLTAIC POWER-SOURCE." This patent is central to the company's plans to develop solid-state energy systems that offer maintenance-free power for years, or even decades.

By acquiring a controlling stake in Atomiq, Nuclear Diamond Batteries, Inc. has effectively bought its way into a new technological domain. This move mirrors a broader trend of smaller, agile companies leveraging unique intellectual property to tackle complex engineering problems that were once the exclusive purview of government labs and massive corporations.

The Science of 'Never-Charge' Energy

The technology at the heart of the company's new identity is as fascinating as it is futuristic. Nuclear diamond batteries are not miniature nuclear reactors. They do not use nuclear fission or fusion. Instead, they are betavoltaic devices, which operate on a principle of non-thermal energy conversion.

The process begins with a radioactive isotope, such as Carbon-14, which has a half-life of approximately 5,730 years. As Carbon-14 decays, it emits low-energy beta particles (electrons). These particles are captured within a semiconductor—in this case, a synthetic, lab-grown diamond. When a beta particle strikes the diamond lattice, it creates a shower of electron-hole pairs, generating a small but continuous electrical current.

The diamond serves a dual purpose: it is both the energy converter and a highly effective containment vessel. Its extreme hardness and durability create a robust, built-in shield that safely encapsulates the radioactive material, preventing any radiation leakage. The beta particles from Carbon-14 are so low in energy they cannot penetrate human skin, making the technology inherently safer than many other nuclear applications.

However, the technology's primary limitation is its low power density. Current prototypes produce power in the microwatt range, making them unsuitable for energy-hungry devices like smartphones or laptops. Their strength lies in longevity, not intensity. They are designed for low-power applications where reliability and the impossibility of replacement are the most critical factors.

Targeting a Billion-Dollar Niche

While they won't be powering electric cars anytime soon, nuclear diamond batteries are aimed at a specialized, high-value market projected to exceed $1.5 billion by 2028. The demand comes from industries where replacing or recharging a battery is impractical, dangerous, or simply impossible.

Key target applications include:

• Medical Technology: Powering pacemakers, defibrillators, and other critical medical implants for the entire lifetime of a patient, eliminating the need for replacement surgeries.
• Aerospace and Space Exploration: Providing continuous power for satellites, deep-space probes, and remote sensor systems in the harsh environment of space.
• Industrial IoT and Remote Sensing: Energizing sensors in hard-to-reach locations like subsea oil pipelines, structural monitoring systems inside bridges, or environmental trackers in polar regions.
• Defense: Enabling extended operational lifetimes for unattended sensors, secure communication nodes, and other military hardware.

The company is not alone in this pursuit. The Chinese startup Betavolt made headlines in early 2024 by announcing a miniature betavoltaic battery using Nickel-63. In the U.S., City Labs has long produced its own tritium-based betavoltaic power sources. Meanwhile, academic institutions like the University of Bristol in the UK are also making significant progress on Carbon-14 diamond battery prototypes, highlighting a growing global interest in the technology.

Navigating the 'Nuclear' Hurdle

Perhaps the greatest challenge for Nuclear Diamond Batteries, Inc. will not be technical, but perceptual. Adopting the word "nuclear" in a company name invites immediate public scrutiny and regulatory oversight. The company's success will depend heavily on its ability to educate the public, regulators, and investors on the profound differences between its technology and traditional nuclear power.

Proponents of the technology are quick to highlight its safety profile and even its environmental benefits. A key selling point is the potential to use Carbon-14 harvested from the irradiated graphite blocks of decommissioned nuclear reactors. This process would turn a long-lived, problematic form of nuclear waste into a valuable resource, creating a circular economy for nuclear materials.

Nonetheless, the path to market will involve navigating a complex regulatory landscape overseen by bodies like the U.S. Nuclear Regulatory Commission (NRC). Gaining approval for use in consumer-adjacent products, especially medical implants, will require exhaustive testing and a transparent approach to safety validation.

By rebranding so boldly, the company has placed its bet. It has a compelling technological narrative, a foundational patent, and a clear vision for a future powered by eternal energy. Now, it faces the monumental task of turning that vision into a commercial reality, one microwatt at a time.