“We can’t own worlds beyond Earth.

But using their resources? That’s the gray zone humanity is just beginning to define.”

What Is Helium-3 (He-3)?

Helium-3 is a rare isotope of helium with massive potential for nuclear fusion.

Unlike traditional nuclear fission:

• Minimal radioactive waste
• No long-lived nuclear byproducts
• Potentially safer fusion reactions (aneutronic)

On Earth? Extremely scarce.
Mostly recovered as a byproduct of nuclear weapons maintenance.

On the Moon?

It’s embedded in the regolith after billions of years of solar wind bombardment.

Estimates suggest millions of tons may exist in lunar soil at concentrations of 10–50 parts per billion.

Why the Moon Has It

The Moon has no atmosphere.

Solar wind particles directly implant helium ions into surface layers.

Over geological time, this created a diffuse but widespread Helium-3 deposit across the lunar surface — especially near the poles.

How Would Mining Work?

Helium-3 isn’t sitting in tanks.

It’s trapped inside lunar soil.

Extraction requires:

1️⃣ Excavation + Heating

Robotic miners collect regolith and heat it to 600–800°C to release the gas.

Concept designs like the “Mark-3” miner propose:
• 1,200+ tons of soil processed per hour
• ~33 kg of He-3 per year from 1 km²

That’s enormous industrial scale.

2️⃣ Detection & Refinement

Advanced systems:
• Mass spectrometers
• Neutron detectors
• Imaging scanners

Used to locate higher-concentration zones before large-scale excavation.

Several companies are patenting full detection-to-purification architectures.

3️⃣ ISRU Integration (In-Situ Resource Utilization)

Mining could integrate with:

• Oxygen extraction
• Water production
• Lunar infrastructure
• Long-term human settlement

Helium-3 could become part of a broader lunar industrial ecosystem.

Who’s Trying to Do This?

🚀 NASA

Through Artemis, building lunar infrastructure that could support future resource extraction.

🛰 Interlune

Founded by former Blue Origin executive Rob Meyerson.

Developing the SILT excavator prototype.

Goals:
• 10 kg annually in 2030s
• Scaling toward 100 kg/year
• DOE contracts for future supply

🌍 European Space Agency

Exploring lunar resource frameworks.

🇨🇳 China National Space Administration

Including He-3 in long-term cislunar economic strategy.

🚀 SpaceX

Has discussed lunar infrastructure and self-sustaining cities, where resource extraction could become an economic driver.

Why Is He-3 So Valuable?

Estimated value: ~$20 million per kilogram

Beyond fusion, uses include:
• Quantum computing cryogenics
• Medical imaging
• Scientific research

But the real prize?

Fusion energy.

If aneutronic He-3 fusion becomes viable, it could power cities with minimal radioactive waste.

The Major Challenges

⚙ Technical Reality

Processing millions of tons of soil for kilograms of gas.

Dust. Radiation. Vacuum. Low gravity.

All must be automated.

💰 Economics

Launch costs + infrastructure costs.

Fusion reactors are not yet commercially operational.

Profitability depends on fusion breakthroughs.

🌐 Geopolitics

The 1967 Outer Space Treaty says no nation can claim the Moon.

But resource extraction rights remain legally ambiguous.

U.S., China, and others are moving quickly.

Taiwan is today’s semiconductor chokepoint.

Tomorrow’s?

Possibly lunar resources.

The Fusion Bottleneck

He-3 enables cleaner fusion.

But commercial fusion power itself is still experimental.

Without fusion, large-scale lunar He-3 mining doesn’t make economic sense.

The Bigger Picture

Helium-3 mining isn’t just about energy.

It’s about:

• Industrializing space
• Creating off-Earth supply chains
• Establishing lunar economic zones
• Redefining property rights in space

The Moon may become:

Not just a scientific outpost.

But humanity’s first extraterrestrial industrial site.

The rules aren’t fully written yet.

And whoever writes them will shape the next energy era. 🌕