If confirmed, the new research could help scientists pin down the origins of life.
ByKorey Haynes | Published: March 6, 2020
Although about 70 percent of Earth’s surface is currently covered in water, new research suggests ancient Earth might not have had any land at all.
NASA Earth Observatory
New research suggests ancient Earth was a water world, with little to no land in sight. And that could have major implications for the origin and evolution of life.
While modern Earth’s surface is about 70 percent water-covered, the new research indicates that our planet was a true ocean world some 3 billion years ago. At this point, only scattered archipelagos breached our global ocean’s briny surface. That is, if any land existed at all.
The scientists based their findings on unique rock samples found in Western Australia’s Panorama district. Because rocks carry imprints of the environments they formed in, the researchers determined the rocks formed in a hydrothermal vent system on the sea floor about 3.24 billion years ago. Over the eons, the rocks were turned on their side and exposed, which allowed scientists to investigate Earth’s watery past from the convenience of dry land. This led them to conclude that ancient Earth may have been a waterlogged planet without any significant landmass.
“An early Earth without emergent continents may have resembled a ‘water world,’ providing an important environmental constraint on the origin and evolution of life on Earth, as well as its possible existence elsewhere,” wrote the authors of the new study, which was published March 2 in Nature Geoscience.
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Water water everywhere
Despite Earth’s abundant present-day oceans, many mysteries remain about their origins. Did Earth always contain water, or was it delivered later? If later, how much later? And was the source of the water comets, asteroids, or something else?
Scientists are still pondering these questions and more. This is because the evidence — like ancient minerals called zircons that seem to have formed in a watery environment — clearly implies that Earth sported water since about 4.4 billion years ago, just after our planet came to be. That’s a long oceanic history.
However, it’s less clear how much water early Earth actually had. And by studying their chunk of the ancient seafloor, the researchers were able to probe that question.
The oxygen network
When rocks form in water, that water imprints its story in stone. Water, or H2O, is always made of hydrogen and oxygen. But the isotope, or type of oxygen, within the water also reveals something about the environment that water formed in. For example, how warm it was, or how the water cycled between land, sea, and air over time.
There are two common isotopes of oxygen. A light version, oxygen-16 (O16), which has eight protons and eight neutrons. And its heavier cousin, oxygen-18 (O18), which has eight protons and ten neutrons. Those two extra neutrons give O18 extra weight, which means water molecules containing O16 evaporate more readily than the heavier O18 versions. Additionally, rocks and dry land are more likely to capture and absorb O18, removing it from the sea stores.
When the authors of the new study examined their chunk of ancient seafloor, they found a lot of O18 — more, on average, than is found in our modern oceans. And because dry land is a huge reservoir of heavy oxygen, an abundance of O18 in Earth’s early days hints that such a reservoir simply didn’t exist. The researchers determined that the most likely reason for the excess of heavy oxygen in their sample is that dry land hadn’t yet emerged from the ancient ocean.
Implications for life
Scientists often debate the origins of Earth’s earliest single-celled organisms. Did life first emerge near hydrothermal vents in the ocean, where both of heat and mineral-rich water were prevalent? Or did life instead first form on land, perhaps near Darwin’s proposed warm little pond? There are a wide range of theories, and so far, scientists just don’t know for sure.
However, if further research confirms that early Earth really was entirely covered in water, then that knowledge could help researchers further refine their theories of how life came into existence.
“The history of life on Earth tracks available niches,” Boswell Wing, a geology professor at the University of Colorado Boulder, said in a statement. “If you’ve got a water world, a world covered by ocean, then dry niches are just not going to be available.”
In other words, if Earth was entirely covered in water when life first got its start, then life couldn’t have formed on land at all. And if that turns out to be the case, then it would suggest exoplanets entirely blanketed in water might be ideal locations to search for extraterrestrial life. But let’s not get ahead of ourselves just yet.
Although this Australian seafloor sample marks just a single point in time, it also covers a large and well-preserved area. So, to track the emergence of the continents, the researchers hope to perform similar research on rock samples spanning Earth’s history. These samples await in Africa, Canada, New Mexico, and Arizona, stretching across a few billion years of Earth’s timeline. Together, they’ll tell the story of when Earth stopped being an aquatic world and started offering up the dry land we inhabit today.
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I'm an expert in geoscience and planetary evolution with a deep understanding of the concepts discussed in the article. My expertise in earth sciences, particularly the geological processes shaping our planet, allows me to analyze and interpret the evidence presented in the research on ancient Earth being a water world.
The article discusses groundbreaking research indicating that ancient Earth might have been a water world, devoid of significant landmasses. The evidence comes from unique rock samples found in Western Australia's Panorama district, showcasing imprints of a hydrothermal vent system on the seafloor approximately 3.24 billion years ago.
The researchers utilized these rocks to draw conclusions about the early Earth's topography. They focused on oxygen isotopes (O16 and O18) within the rocks and compared them to modern oceans. The presence of a higher-than-expected amount of O18 in the ancient seafloor samples suggests a lack of emerged dry land, supporting the hypothesis of a waterlogged planet.
This discovery has significant implications for understanding the origins and evolution of life on Earth. If early Earth was entirely covered in water, it could challenge existing theories about the emergence of life, particularly the debate on whether it started near hydrothermal vents in the ocean or on land.
The article touches upon the longstanding mystery of Earth's water sources and raises questions about the timing and origin of our planet's abundant oceans. It also emphasizes the importance of studying ancient rocks to unravel the history of Earth's transition from a water world to one with continents.
The oxygen isotope analysis is a key aspect of the research, demonstrating how water imprints its story in stone. The difference in evaporation rates between O16 and O18, along with the affinity of dry land for the heavier O18, provides valuable insights into the ancient Earth's landscape.
Looking ahead, the researchers plan to extend their investigation by studying rock samples from various locations, such as Africa, Canada, New Mexico, and Arizona, covering different periods in Earth's history. This broader approach aims to piece together the narrative of when Earth transitioned from an aquatic world to the planet we know today, with dry land supporting complex life forms.
In conclusion, the findings from this research not only contribute to our understanding of Earth's geological history but also have broader implications for the search for extraterrestrial life, particularly on exoplanets with extensive water coverage.
