Level 1 — Absolute Beginner
Scientists in Canada found something amazing. Old rocks under the ground make hydrogen gas. This gas is called white hydrogen.
The rocks are very, very old. They are about one billion years old. They are in the Canadian Shield. This is a big area of old rock in Canada.
Hydrogen is a type of clean fuel. When you burn hydrogen, it makes only water. It does not make pollution. This is very good for the planet.
Scientists from two universities did this study. They think Canada has a lot of natural hydrogen. This could help make clean energy in the future.
- hydrogen
- a light gas that can be used as a clean fuel
- white hydrogen
- hydrogen gas that forms naturally inside old rocks in the ground
- clean fuel
- a type of energy source that does not create pollution when used
- pollution
- harmful substances that damage the air, water, or land
- rock
- a hard, solid material that makes up the ground and mountains
- billion
- one thousand million; a very large number (1,000,000,000)
- natural
- made by nature, not by people
- energy
- the power that makes things work or move
Level 2 — Elementary
Scientists in Canada have discovered that billion-year-old rocks underground are naturally producing hydrogen gas. This gas is called 'white hydrogen' or 'natural hydrogen.' The study was published in the journal Proceedings of the National Academy of Sciences.
Researchers from the University of Toronto and the University of Ottawa measured hydrogen gas coming out of a mine near Timmins, in the province of Ontario. They found that the mine releases more than 140 metric tons of hydrogen per year. This amount could provide electricity for more than 400 homes annually.
The hydrogen is created through a natural chemical reaction. Water seeps deep into the rock and reacts with iron-rich minerals. This process releases hydrogen gas, which then rises to the surface. The Canadian Shield contains some of the oldest rocks on Earth, and many of them have the right minerals for this reaction.
This discovery is exciting because hydrogen is a clean fuel. When used to generate electricity, it produces only water as a byproduct. Unlike coal, oil, or gas, it does not release carbon dioxide. Scientist Barbara Sherwood Lollar of the University of Toronto said this could represent a 'made in Canada' energy source to support local industry.
- geochemist
- a scientist who studies the chemical composition of Earth's rocks and soils
- metric ton
- a unit of weight equal to 1,000 kilograms
- byproduct
- a secondary product produced when making or doing something else
- carbon dioxide
- a greenhouse gas produced when fuels are burned; a major cause of climate change
- mineral
- a natural solid substance found in rocks and the ground
- chemical reaction
- a process in which substances change and form new substances
- seep
- to flow slowly through small openings in rock or soil
- domestic
- relating to or within a particular country; produced at home rather than imported
Level 3 — Intermediate
Geochemists at the University of Toronto and the University of Ottawa have published findings in the Proceedings of the National Academy of Sciences showing that naturally occurring hydrogen gas is steadily accumulating and discharging from billion-year-old Precambrian rocks of the Canadian Shield in northern Ontario. The discovery, led by Professor Barbara Sherwood Lollar, is drawing significant attention as a potential new source of clean energy.
The research team conducted measurements at an operating mine near Timmins, Ontario, recording sustained hydrogen discharge from thousands of boreholes that penetrate the ancient rock. Across the site's nearly 15,000 boreholes, the total annual hydrogen discharge exceeds 140 metric tons, enough to generate approximately 4.7 million kilowatts of energy per year -- sufficient to meet the energy needs of more than 400 households at a single location.
The mechanism behind the production is a geological process called serpentinization. Deep underground, water interacts with iron-rich minerals, releasing hydrogen gas through a chemical reaction. Because the Canadian Shield contains extensive ancient igneous and metamorphic rock formations, it has exactly the conditions needed for sustained hydrogen production over vast geological timescales.
White hydrogen differs from other forms of clean hydrogen. Green hydrogen is made by splitting water molecules using electricity from renewable sources. White hydrogen, by contrast, is produced naturally underground at no energy cost. Scientists caution that large-scale extraction would require new infrastructure and further economic study, but describe the Timmins data as a critical first step in assessing Canada's untapped hydrogen potential.
- serpentinization
- a geological process in which water reacts with iron and magnesium minerals to produce hydrogen gas and heat
- borehole
- a narrow hole drilled deep into the ground, used for mining or scientific measurement
- precambrian
- relating to the vast span of geological time before complex animal life appeared, roughly 4 billion to 541 million years ago
- igneous rock
- rock formed from cooled and solidified lava or magma
- metamorphic rock
- rock that has been changed by intense heat and pressure deep underground
- green hydrogen
- hydrogen produced by electrolysis powered by renewable energy, considered fully clean
- extraction
- the process of removing a resource from the ground
- geological timescale
- the vast timeline of Earth's history, measured in millions or billions of years
Level 4 — Advanced
A study published in the Proceedings of the National Academy of Sciences by geochemist Barbara Sherwood Lollar (University of Toronto) and colleagues at the University of Ottawa represents the first sustained, site-specific measurement of natural or 'white' hydrogen discharge from the Canadian Shield -- the vast Archean and Paleoproterozoic craton underlying roughly half of Canada's landmass. Research conducted at an operating hard-rock mine near Timmins in the Superior Province of northern Ontario documents continuous hydrogen accumulation and periodic discharge, with an annual borehole-aggregate yield exceeding 140 metric tons. Modeled through a proton-exchange-membrane fuel cell at 50% efficiency, this volume is sufficient to supply approximately 4.7 million kilowatts of useful electricity from a single site's borehole inventory.
The geochemical driver is iron-silicate hydration -- specifically the serpentinization of mafic and ultramafic rocks when meteoric and deep-saline groundwaters interact with olivine and pyroxene minerals at temperatures between 100 and 400 degrees Celsius. This low-temperature serpentinization pathway has been established across multiple decades of Sherwood Lollar's saline-fracture-water research, generating molecular hydrogen alongside methane and helium. The Canadian Shield's extensive Archean greenstone belt terranes provide the lithological conditions for sustained serpentinization at scale, as do analogous Precambrian cratons in Mali, Oman, and Australia, where active exploration licenses for white hydrogen are now being issued.
The strategic implications for Canada's energy transition are significant but conditional. White hydrogen, if extractable at commercial volumes, represents a zero-carbon fuel requiring no upstream electrolysis energy input -- a material cost advantage over green hydrogen, whose levelized cost remains tied to renewable electricity pricing. The primary obstacles are infrastructure (the Timmins locality lacks pipeline and compression facilities for regional distribution), grade uncertainty (hydrogen concentration varies markedly between boreholes and with seasonal groundwater-table fluctuations), and a nascent regulatory framework for wellhead-hydrogen extraction on Crown mineral lands.
Sherwood Lollar's team has explicitly positioned the Timmins study as a proof-of-concept for a new class of energy-resource assessment, drawing on the analytical toolkit developed for saline paleowater studies -- noble-gas isotope dating, dissolved-gas chromatography, and stable-isotope fingerprinting -- to characterize the age, origin, and flow rates of hydrogen-bearing fracture fluids. The paper frames Precambrian rock hydrogen not as a geological curiosity but as a quantifiable, domestically controlled resource potentially relevant to Canada's G7 Climate Compact hydrogen-strategy commitments, capable of supporting both decarbonization of northern Ontario's existing mining clusters and a broader export corridor to the United States and Europe.
- craton
