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Deep-sea trenches are deep depressions at the bottom of the Earth’s oceans, which are unique features of our planet in the Solar System. They were formed as a result of the movement of tectonic plates and can reach depths of 10-11 km, creating one of the most amazing landscapes on our planet – the hadal zone.

What do you know about deep-sea trenches?

Source: geographical.co.uk

Space at the bottom

There are places on our planet whose gloomy mystery can rival the darkness of space itself. Usually, these include Antarctic glaciers, where life is almost impossible, or the polar deserts on some islands of the Canadian Arctic Archipelago, which are often compared to Mars.

However, there are places on Earth that are almost as inaccessible to humans as outer space, even though they are as far away from it as possible. These are deep-sea trenches – narrow and long depressions at the bottom of the world’s oceans, whose bottoms are never reached by sunlight. Their landscape resembles that of a celestial body, and their few inhabitants resemble aliens.

However, to truly understand the depth of the trenches, you need to observe what happens when you gradually walk along the seabed, going deeper and deeper.

Littoral zone.

Source: Wikipedia

First, they determine the area between the highest point that gets underwater during high tide and the one that remains dry during low tide. This is called the littoral zone, and it is usually a narrow strip along the coast that sometimes gets a few kilometers wide. A great example of a littoral zone is a bunch of Ukrainian estuaries: looking at them, it is clear that the littoral zone is an area that makes any other part of the seabed seem deep.

Next comes the continental shelf – a section of the seabed where the depth slowly decreases to 200 m. The northern part of the Black Sea or the English Channel area, where the depth may not exceed hundreds of meters, tens of kilometers from the coast, are typical example. In essence, the shelf is part of the continental mass submerged by the ocean. Between the sedimentary rocks and basalt, as in much drier places, there is a layer of granite.

If you continue further, you will reach the continental slope, where the bottom descends at a much greater angle and quickly reaches a depth of 2-3 km. The continental slopes are particularly pronounced. For example, off the coast of North America.

The bottom of the World Ocean.

Source: Wikipedia

Further down, the angle of the seabed decreases again, and abyssal plains stretch to depths of 4-5 km. These are huge depressions, comparable in size to entire countries, bounded by continental slopes. Sunlight rarely reaches their bottom, and despite the fact that bathyscaphes have repeatedly descended there, we still know less about these areas than we do about the surface of the Moon.

Deep-sea trenches are located even deeper than abyssal plains. The term “hadal zone” is used to describe the fauna of this landscape. There is no need to talk about flora, as it is practically non-existent at depths greater than 5 km. These are truly abysses, where the bottom slopes steeply downward and no light penetrates.

Formation of oceanic trenches

The fact that all the deepest areas of the ocean are shaped like narrow, elongated strips stretching along the coasts of continents or island arcs can be explained by the peculiarities of their formation. As is well known, the Earth’s crust consists of large blocks – tectonic plates. They move along the viscous, relatively plastic outer layer of our planet’s mantle, and it is this movement that causes earthquakes and volcanic eruptions.

Formation of an oceanic trench

The crust of plates can be continental, i.e., contain the aforementioned layer of granite, or oceanic, i.e., consist only of basalt and sedimentary rocks. Some plates consist of both types, while others consist only of oceanic crust.

In most cases, the transition from the continental slope to the ocean depths involves the same tectonic plate. However, sometimes two different lithospheric blocks are encountered here: one with a continental crust and the other with an oceanic crust. In this case, the oceanic plate begins to subduct beneath the continental plate and partially melts. As a result, a deep depression is formed.

Its slopes are always gentler on the side of the subducting oceanic plate and steeper on the continental side. This is the structure we call a deep-sea oceanic trench. At the same time, the plate subducts very slowly, so from the outside it may seem like a completely calm place.

Pacific Ring of Fire.

Source: Wikipedia

The way deep-sea trenches are formed determines their extremely uneven distribution across the surface of our planet. They are always located in tectonically active zones, mainly in the so-called Pacific Ring of Fire, which surrounds the largest ocean on our planet.

Mariana Trench

In fact, all ten of the deepest ocean trenches are located in the Pacific Ocean. There are more than thirty of them in total. For comparison, there are only three large trenches in the Indian and Atlantic Oceans, and none at all in the Arctic Ocean.

However, the most famous of the Pacific trenches is the Mariana Trench, which is also considered the deepest in the world. Its depth is estimated differently, but usually the value of 11,022 m is given. It is located in the western part of the Pacific Ocean, near the islands of the same name. Its bottom is so inaccessible that humans first reached it only in 1960, just a year before they first set foot on the surface of the Moon. Until recently, the number of people who had visited the bottom of this trench was smaller than the number who had visited our natural satellite.

Mariana Trench.

Source: Wikipedia

The water pressure at this depth is 108.6 MPa, which is 1,072 times greater than normal atmospheric pressure at sea level. However, microorganisms, crustaceans, and even fish have been found there. None of them is found anywhere else except this place, and they have never seen the light of the sun or stars. Their living conditions resemble those in space.

In addition, despite its inaccessibility, the Mariana Trench already bears the negative traces of human activity. Heavy toxic waste settles there and, together with river water, flows into the oceans.

Other trenches

Everyone knows about the Mariana Trench. However, the rest are no less amazing than it. Tonga, Philippine, Kermadec, Izu Ogasawara, Kuril-Kamchatka, North New Hebridean, Bougainville, and Japan – all of them are deep enough to completely submerge Mount Everest.

The landscape of the Puerto Rico Trench.

Source: www.wired.com

Although the Mariana Trench is the deepest, the title of the longest on Earth belongs to another Pacific structure – the Peru-Chile Trench. It stretches along the coast of South America for 5,900 km, where the Nazca Plate dives under the South American Plate.

The deepest and largest trench in the Indian Ocean is the Sunda Trench, which stretches for 4-5 thousand km along the coast of Indonesia. Its maximum depth is 7,729 m near the island of Bali.

The ocean trenches of the Atlantic Ocean are generally relatively short in length, as they are formed by small tectonic plates. The deepest of these is the Puerto Rico Trench, with a maximum depth of 8,742 m. This is only slightly less than the height of Mount Everest.

It would seem that ocean trenches have nothing to do with astronomy. However, when considering the planets of the Solar System, among the unique phenomena available only on Earth, along with the biosphere, it is worth mentioning them. After all, nowhere else do lithospheric plates move, and even more so, there are no places where they collide under a layer of liquid.

It looks like NASA's Mars Sample Return (MSR) mission has come to a bureaucratic end. The mission was to be the crowning achievement in the study of Mars and all the questions surrounding its ancient habitability. But the US Congress has drastically cut the mission's funding.

Despite decades of study and technological improvement and innovation, the issue of Martian habitability has been difficult to solve. MSL Curiosity and Perseverance have widened and deepened our understanding of the planet, and have provided tantalizing evidence for warm, wet periods on Mars conducive to life. But the next step was to return Martian rock samples to Earth, where the investigative power of modern labs could be brought to bear on them.

As far back as 2011, returning samples from Mars was recognized as a high priority in NASA's planetary science endeavours. Even today, NASA's webpage for MSR states that "Mars Sample Return (MSR) would be NASA's and ESA’s (European Space Agency) ambitious, multi-mission campaign to bring carefully selected samples to Earth. MSR would fulfill one of the highest priority solar system exploration goals from the science community. Returned samples would revolutionize our understanding of Mars, our solar system and prepare for human explorers to the Red Planet."

The Perseverance rover was the first stage of the mission, and it has performed exceptionally well. The rover has gathered and cached 33 sample tubes of interesting rocks and dust, ready for retrieval by the MSR. Now, the fate of those samples is unclear.

NASA knew that they were in tough territory. The estimated cost to retrieve the samples ballooned to 11 billion dollars. After working on new mission architectures, they were able to get the estimated cost down to about 7 billion dollars. But those were just estimates, and because it's such an unprecedented mission, there was a clear lack of certainty around those numbers.

The issue is money. There's heavy pressure on NASA to reduce its budget, and although Congress refused to reduce it as severely as the President wanted, something had to give. Since the MSR still required large amounts of money, and since the technology to achieve it still wasn't clear, it was the obvious choice for cancellation. It became a high-profile political football, not just a science mission.

The mission was extremely complex. The current design involved sending a lander to the surface. Perseverance would deliver the sample tubes to the lander, and if that were not possible, a pair of small sample return helicopters would do the job. The lander also had a rocket which would carry the samples to Martian orbit. From there, it would rendezvous with an orbiting spacecraft that would send the samples back to Earth. To say this was a complex undertaking is an understatement.

*This artwork from 2022 shows the conceived mission architecture.

Image Credit: By NASA/ESA/JPL-Caltech

- https://photojournal.jpl.nasa.gov/catalog/PIA25326 (image link), Public Domain, https://commons.wikimedia.org/w/index.php?curid=121171927*

But isn't NASA all about American ingenuity and the spirit of exploration and adventure? You can't lead in science without money, and it's hard to argue that President Trump's request to inflate the USA's military budget to an unprecedented degree didn't have something do with NASA's budget cuts. He asked for 1.5 trillion dollars of military spending, a profligate 50% increase.

The budget still provides some money for developing technology related to further exploration of Mars, but only a small amount.

The wording is clear in a document titled DIVISION A - COMMERCE, JUSTICE, SCIENCE, AND RELATED AGENCIES APPROPRIATIONS ACT, 2026.

"As proposed in the budget, the agreement does not support the existing Mars Sample Return (MSR) program. However, the technological capabilities being developed in the MSR program are not only critical to the success of future science missions but also to human exploration of the Moon and Mars."

It continues: "Therefore. the agreement provides the request of $110,000,000 for the Mars Future Missions program, including existing MSR efforts, to support radar, spectroscopy, entry, descent, and landing systems, and translational precursor technologies that will enable science missions for the next decade, including lunar and Mars missions."

*Perseverance's cached samples await retrieval on the Martian surface.

Image Credit: NASA/JPL-Caltech/MSSS*

It's possible that some of that money will lead to new technologies, and a more budget-friendly way of retrieving the cached samples. But that is far from certain. It's also possible that technology will be developed that can study the samples effectively on the surface and returning them to Earth won't be necessary. But the technology in Earthly labs will advance at the same rate. It's difficult to conceive how studying them on Mars will ever be as effective as studying them on Earth.

Politics can't be ignored in this issue. NASA was teaming up with the ESA on this mission. But with the current administration's threats against European countries and the EU, which include using military force to sieze Greenland—otherwise known as war—that cooperation is likely dead. Maybe never to be revived.

The future is always unwritten and unknown. Maybe the MSR will be revived at some point in the future. Maybe the ESA will go it alone. China has plans for a Mars sample return mission, and now the path is clear for them to be the first to return Martian samples to Earth. However, their mission is not as sophisticated as the NASA/ESA mission. While Perseverance's samples are carefully chosen for maximum science benefit, China's mission is more of a grab and go endeavour.

Fortunately, the sample tubes are likely to sit there waiting for a long time, unlikely to be degraded in Mars' cold, dry environment. But for scientists who have put their hearts and minds into this ambitious mission, the news must be crushing.