Earth’s core may contain vast hidden reserves of hydrogen, reshaping theories about planet’s water origins. Beneath our feet lies a hidden reservoir that could dwarf all of Earth’s oceans. The discovery could transform our understanding of how Earth formed and where its water came from.
Far below the crust and mantle, at depths unreachable by drilling technology, Earth’s core remains one of the least accessible regions of our planet. Yet new scientific findings suggest that this remote and extreme environment may hold an extraordinary secret: a vast store of hydrogen potentially equivalent to several times the volume contained in all of Earth’s oceans. Researchers recently proposed that the core could harbor the equivalent of at least nine global oceans’ worth of hydrogen, and possibly as many as 45. If confirmed, this would make the core the largest hydrogen reservoir on Earth and significantly reshape prevailing theories about the planet’s early development and the origin of its water.
Hydrogen, the lightest and most abundant element in the universe, stands as a fundamental component in the chemistry of life and the evolution of planets. On Earth’s surface, it is most commonly encountered combined with oxygen in water. Yet, recent assessments suggest that large reserves of hydrogen could be sequestered deep within the metallic core, representing about 0.36% to 0.7% of its total mass. While that share might seem small, the core’s extraordinary scale and density ensure that even a tiny proportion corresponds to a vast amount of hydrogen.
These findings carry significant implications for understanding when and how Earth acquired its water. A long-standing scientific debate centers on whether most of the planet’s water arrived after its formation through impacts from comets and water-rich asteroids, or whether hydrogen was already incorporated into Earth’s building materials during its earliest stages. The new research lends support to the latter possibility, suggesting that hydrogen was present as the planet formed and became integrated into the core during its earliest phases.
Rethinking the origins of Earth’s water
Over 4.6 billion years ago, the early solar system existed as a chaotic realm of swirling gas, dust and rocky fragments encircling a youthful sun, and over time these elements collided repeatedly and slowly merged, giving rise to increasingly larger bodies that ultimately became the terrestrial planets, including Earth. As this process unfolded, the planet underwent differentiation, with its dense metallic core descending to the interior while lighter substances spread outward to create the mantle and the crust above.
For hydrogen to remain in the core today, it would have had to exist during that crucial phase of planetary development, when molten metal peeled away from silicate material and sank toward the center. During this descent, hydrogen needed to blend into the liquid iron alloy that ultimately formed the core, a step possible only if the element had already been embedded in the planet’s initial constituents or delivered early enough to join the core‑forming process.
If the majority of Earth’s hydrogen existed from the outset, it indicates that water and volatile elements were likely not just late arrivals brought by cosmic collisions. Rather, they may have formed essential ingredients of the primordial materials that came together to build the planet. In this view, the core would have drawn in a substantial share of the hydrogen within the first million years of Earth’s evolution, well before stable surface oceans emerged.
This interpretation questions models that place heavy emphasis on comet-driven bombardment as the dominant origin of Earth’s water, suggesting instead that although impacts from icy bodies probably supplied some moisture and volatile materials, the updated estimates indicate that a significant portion of hydrogen was already incorporated into the planet’s deep interior during its earliest formation stages.
Exploring a frontier long beyond reach
Studying the makeup of Earth’s core poses immense difficulties, as it starts about 3,000 kilometers below the surface and reaches the planet’s center, a realm where sun‑like temperatures and pressures millions of times greater than those at the surface prevail. Because direct sampling remains beyond today’s technological capabilities, scientists must depend on indirect investigative techniques and controlled laboratory experiments.
Hydrogen poses a particularly difficult measurement problem. Because it is the smallest and lightest element, it can easily escape from materials during experiments. Its tiny atomic size also makes it challenging to detect with conventional analytical tools. For decades, researchers attempted to infer the presence of hydrogen in the core by examining the density of iron under high pressures. The core’s density is slightly lower than that of pure iron and nickel, indicating that lighter elements must be present. Silicon and oxygen have long been considered leading candidates, but hydrogen has also been suspected.
Previous experimental approaches often relied on X-ray diffraction to analyze changes in the crystal structure of iron when hydrogen is incorporated. When hydrogen enters iron’s atomic lattice, it causes measurable expansion. However, interpreting these changes has led to widely varying estimates, ranging from trace amounts to extremely high concentrations equivalent to more than 100 ocean volumes. The uncertainty stemmed from the limitations of the techniques and the difficulty of replicating true core conditions.
An innovative approach crafted at the atomic scale
Researchers refined these estimates by employing a technique that allows materials to be examined at the atomic scale; in controlled laboratory settings, they reproduced the immense pressures and temperatures thought to prevail in Earth’s deep interior, using a diamond anvil cell to squeeze iron samples to staggering pressures and then heating them with lasers until they liquefied, effectively simulating the molten metal of the planet’s early core.
After the samples cooled, scientists turned to atom probe tomography, a technique capable of producing near-atomic-resolution three-dimensional images and detailed chemical profiles. The materials were crafted into extremely fine, needle-shaped specimens measuring only a few dozen nanometers across. Through the use of precisely regulated voltage pulses, individual atoms were ionized and captured sequentially, allowing researchers to directly quantify hydrogen and map its distribution alongside elements like silicon and oxygen.
This approach differs fundamentally from earlier methods because it counts atoms directly rather than inferring hydrogen content from structural changes. The experiments revealed that hydrogen interacts closely with silicon and oxygen within iron under high-pressure conditions. Notably, the observed ratio between hydrogen and silicon in the experimental samples was approximately one to one.
By integrating this atomic-scale data with separate geophysical assessments of how much silicon is present in the core, the researchers derived a revised interval for hydrogen abundance, and their findings indicate that hydrogen comprises roughly 0.36% to 0.7% of the core’s mass, an amount that equates to several ocean volumes when described in more familiar terms.
Consequences for the magnetic field and the potential for planetary habitability
The presence of hydrogen in the core does more than reshape theories of water delivery. It may also influence how scientists understand the evolution of Earth’s magnetic field. The core’s outer layer consists of molten metal that convects as heat escapes from the interior. This movement generates the geomagnetic field, which shields the planet from harmful solar and cosmic radiation.
The interplay between hydrogen, silicon and oxygen in the core could affect how heat was transferred from the core to the mantle in the planet’s early history. The distribution of light elements influences density gradients, phase transitions and the dynamics of core convection. If hydrogen played a significant role in these processes, it may have contributed to establishing the long-lived magnetic field that made Earth more hospitable to life.
Understanding the distribution of volatile elements such as hydrogen also informs broader models of planetary formation. Hydrogen, along with carbon, nitrogen, oxygen, sulfur and phosphorus, belongs to a group of elements considered essential for life. Their behavior during planetary accretion determines whether a world develops surface water, an atmosphere and the chemical ingredients necessary for biology.
Assessing unknowns and exploring potential paths ahead
Despite the advanced nature of these new experimental techniques, some uncertainties persist. While laboratory simulations can mirror conditions in Earth’s deep interior, they cannot fully duplicate them. Moreover, hydrogen may be lost from samples during decompression, which could result in lower measured values. Additional chemical processes within the core, not entirely reflected in the experiments, might also influence hydrogen levels.
Some researchers point out that independent analyses have yielded hydrogen estimates in a comparable range, sometimes trending higher. Variations in experimental frameworks, assumptions regarding core makeup, and approaches to accounting for hydrogen loss can produce shifts in the resulting calculations. As analytical methods progress, upcoming studies may sharpen these estimates and further reduce existing uncertainties.
Geophysical observations may also provide indirect constraints. Seismic wave measurements, which reveal density and elastic properties of the core, can help test whether proposed hydrogen concentrations are consistent with observed data. Integrating laboratory results with seismic models will be crucial for building a comprehensive picture of the core’s composition.
An expanded view of Earth’s origins
If these projected hydrogen concentrations prove correct, they bolster the idea that Earth’s volatile reserves formed early and became widely dispersed within its interior, suggesting that hydrogen was not merely a late addition from icy impactors but may have existed within the planet’s original building materials, with gas from the solar nebula and inputs from asteroids and comets each contributing to different degrees.
Scientists now reconsider how water is distributed inside the planet, as the notion that the core holds most of Earth’s hydrogen reshapes this understanding. Although oceans visually and biologically dominate the surface, they might account for only a minor portion of Earth’s overall hydrogen reserves. The mantle is thought to store more, and the core may contain the greatest amount of all.
This perspective emphasizes that Earth’s deep interior is not merely a static foundation beneath the crust but an active participant in the planet’s chemical and thermal evolution. The processes that unfolded during the first million years of Earth’s existence continue to influence its structure, magnetic field and capacity to support life.
As research progresses, the emerging picture is one of a planet whose defining characteristics were shaped from the inside out. By peering into the atomic architecture of iron under extreme conditions, scientists are gradually revealing how the smallest element in the periodic table may have played an outsized role in shaping Earth’s destiny.
