Deep beneath our feet, at a staggering depth of over 5,100 kilometers, lies Earth’s inner core – a solid ball of iron and nickel that plays a crucial role in shaping the conditions we experience on the surface. Without this inner core, life as we know it might not even exist. Despite its significance, the formation and development of this hidden world remain shrouded in mystery. Even its age is unknown. Fortunately, the field of mineral physics is bringing us closer to unlocking these secrets.
The inner core is responsible for Earth’s magnetic field, acting as a protective shield against harmful solar radiation. This magnetic field is believed to have been crucial in creating the conditions that allowed life to thrive billions of years ago. Imagine a time when the inner core was liquid, gradually turning solid over time. As Earth cools, the inner core expands outwards, causing the surrounding iron-rich liquid to “freeze.” Despite its solid state, the inner core remains incredibly hot, at least 5,000 Kelvin (4726.85 degrees Celsius). This freezing process releases elements like oxygen and carbon, incompatible with the hot solid, creating a buoyant liquid at the bottom of the outer core. This liquid rises, mixes with the outer core, and generates electric currents through “dynamo action,” ultimately creating our magnetic field. Ever wondered why the northern lights dance across the sky? Thank the inner core!
To understand how Earth’s magnetic field has evolved over its history, geophysicists use models that simulate the thermal state of the core and mantle. These models help us comprehend how heat is distributed and transferred within Earth. The traditional assumption is that the solid inner core first appeared when the liquid cooled to its melting point, marking the beginning of freezing. However, this simplistic view doesn’t accurately reflect the actual freezing process.
Scientists are now exploring the phenomenon of “supercooling.” This occurs when a liquid is cooled below its freezing point without turning solid. Imagine water in the atmosphere, sometimes reaching minus 30 degrees Celsius before forming hail. This same phenomenon happens with iron in Earth’s core. Calculations suggest that up to 1,000 Kelvin of supercooling is required to freeze pure iron in the Earth’s core. Considering the core’s conductivity and its cooling rate of 100-200 Kelvin per billion years, this presents a significant challenge.
This level of supercooling implies that the core would have needed to be below its melting point for the entirety of its history – a period of 1,000 to 500 million years – leading to further complications. As we cannot physically access the core (humans have only drilled 12 kilometers into Earth), we rely almost entirely on seismology to understand our planet’s interior. The inner core was discovered in 1936, and its size (about 20% of Earth’s radius) is one of the best-understood aspects of the deep Earth. We use this information to estimate the core’s temperature, assuming the boundary between the solid and liquid represents the intersection of the melting point and core temperature. This assumption also helps us estimate the maximum extent of supercooling that could have occurred before the inner core began to form.
If the core froze relatively recently, the current thermal state at the inner core-outer core boundary indicates how much the combined core might have been below its melting point when the inner core first began to freeze. This suggests that, at most, the core could have been supercooled by about 400 Kelvin. This is at least double what seismology allows. If the core was supercooled by 1,000 Kelvin before freezing, the inner core should be much larger than observed. Conversely, if 1,000 Kelvin is necessary for freezing and was never achieved, the inner core shouldn’t exist at all. Clearly, neither scenario is accurate, leaving us searching for a better explanation.
Mineral physicists have been investigating pure iron and other mixtures to determine the amount of supercooling needed to initiate the inner core’s formation. While these studies haven’t provided a definitive answer, there are promising advancements. For example, we’ve learned that unexpected crystal structures and the presence of carbon may influence supercooling. These findings suggest that certain chemistry or structure, not previously considered, might eliminate the need for such extreme supercooling. If the core could freeze at less than 400 Kelvin of supercooling, it would explain the presence of the inner core as we observe it today.
The implications of not fully understanding the formation of the inner core are far-reaching. Previous estimates of the inner core’s age ranged from 500 to 1,000 million years. However, these estimates don’t account for the supercooling issue. Even a modest supercooling of 100 Kelvin could mean the inner core is several hundred million years younger than previously thought.
Understanding the signature of inner core formation in the paleomagnetic rock record – an archive of Earth’s magnetic field – is crucial for scientists studying the impact of solar radiation on mass extinctions. Until we gain a deeper understanding of the magnetic field’s history, we cannot fully determine its role in the emergence of habitable conditions and life. This intricate dance of supercooling, crystal structures, and the inner core’s formation continues to fascinate scientists, promising to unlock even more secrets about our planet’s history and the conditions that led to life’s existence.