Tag Archives: Canyons

Researchers Discover That “Linear Dune Canyons” on Mars Were Formed by Sliding Carbon Dioxide Ice Blocks

Posted on by
Reply

Parallel channels known as linear dune canyons can be observed within some of Mars’ dunes. Contrary to what their name suggests, these canyons are frequently quite winding. It was previously believed that these landforms were created through debris flow processes influenced by liquid water. However, recent satellite imagery has revealed that they are active during the local spring due to processes involving carbon dioxide ice. During the Martian winter, ice accumulates on the dunes, breaking off at the top as temperatures rise in early spring. In new experiments conducted in the Mars Chamber, planetary researchers from Utrecht University, the University of Le Mans, the University of Nantes, the Grenoble Institute of Astrophysics, and the Open University have demonstrated that linear dune canyons form when blocks of carbon dioxide and ice slide or submerge into the sandy slopes of dunes, or shift downwards with considerable force, draining the nearby sand. This drilling action is triggered by a powerful gas flow generated by the sublimation of carbon dioxide ice, as it transitions into carbon dioxide gas. The movement of sliding carbon dioxide ice blocks contributes to the formation of shallow channels, while the excavation of carbon dioxide ice results in the development of deep, winding channels in Martian dunes.

Two examples of Martian dunes with linear dune gullies: (a) linear dune gullies in the dune field of Gall Crater; (b) A linear dune canyon in the dune field of an unnamed crater in the center of the Hellas Plain. Image credit: Roelofs et al., doi:10.1029/2024GL112860.

Linear dune canyons are remarkable and enigmatic formations located in the mid-latitude sand dune regions of Mars.

Despite their designation, these parallel and often meandering waterways, characterized by sharp bends, limited source areas, distinct banks, and hole-like channel terminations, have no equivalent on Earth.

They differ significantly from the conventional canyon topography found on steep slopes both on Mars and Earth, which typically features erosional alcoves, channels, and sedimentary aprons that are often larger than linear dune canyons.

“In our simulations, we observed how high gas pressures cause the sand to shift in all directions around the blocks,” stated Loneke Roelofs, a researcher at Utrecht University and lead author of the study.

“Consequently, the blocks become lodged into the slope and get trapped within cavities, surrounded by small ridges of settled sand.”

“However, the sublimation process persists, leading to continued sand displacement in all directions.”

“This phenomenon drives the block to gradually descend, resulting in a long, deep canyon flanked by small sand ridges on either side.”

“This is precisely the kind of canyon we find on Mars.”

In their research, Dr. Roelofs and colleagues merged laboratory experiments that let blocks of carbon dioxide and ice slide down sandy slopes under Martian atmospheric pressure with observations of the linear dune canyons located within the Russell Crater Giant Dunes.

“We experimented by simulating dune slopes of varying steepness.”

“We released chunks of carbon dioxide ice down a slope and observed the outcomes.”

“Once we discovered an appropriate slope, we began to see significant effects. The carbon dioxide ice chunks started to penetrate the slope and move downwards, resembling burrowing moles or dune sandworms. It was quite an unusual sight.”

“But how exactly do these ice blocks originate? They form in the desert dunes located in the midlands of Mars’ southern hemisphere.”

“During winter, a layer of carbon dioxide ice develops across the entire surface of the dunes, reaching thicknesses of up to 70 cm. As spring arrives, this ice begins to warm and sublimate.”

“The last remnants of the ice persist on the shaded side of the dune’s summit, where blocks will break off once temperatures rise sufficiently.”

“When a block reaches the base of the slope and halts its movement, sublimation continues until all carbon dioxide evaporates, leaving behind a cavity filled with sand at the dune’s base.”

This study was published in the October 8th issue of Geophysical Research Letters.

_____

Loneke Roelofs et al. 2025. Particle transport driven by explosive sublimation causes blocks of CO2 to slide and burrow, forming winding “linear dune valleys” in Martian dunes. Geophysical Research Letters 52 (19): e2024GL112860; doi: 10.1029/2024GL112860

Source: www.sci.news

Researchers Document Submarine Canyons in Antarctica

Posted on by
Reply

Submarine canyons are vast, deep formations located on the majority of the world’s continental margins. Antarctica plays a pivotal role in marine processes that significantly influence global climate and ocean circulation. The understanding of oceanographic, climatic, geological, and ecological importance is often hindered by the limitations in Canyon data. In a recent study, researchers from University College Cork and the University of Barcelona aimed to develop the most comprehensive catalogue of Antarctic submarine canyons and gullies. They discovered 332 drainage networks consisting of 3,291 river segments, which is nearly five times the number of canyons recorded in earlier research.

This map shows a network of 332 submarine canyons on the seabed of Antarctica. Image credits: Riccardo Arosio & David Amblas, doi: 10.1016/j.margeo.2025.107608.

Submarine canyons are prevalent features found along all continental margins.

These canyons are typically V-shaped valleys with narrow, flexible morphology, beginning at the edge of the continental shelf or continental slope and extending into either the continental rise or abyssal plains.

Short channels less than 10 km in length are referred to as submarine gullies, and they are commonly found within canyon systems on continental slopes.

Submarine canyons are crucial for transporting sediments and nutrients from coastal areas to deeper waters, establishing biodiverse habitats by linking shallow and deep marine environments.

While approximately 10,000 submarine canyons exist globally, only 27% of the ocean floor is mapped at high resolution, indicating a likely higher total number of canyons.

Despite their ecological, oceanographic, and geological significance, submarine canyons are often underrepresented, especially in polar regions.

“Similar to the submarine canyons in the Arctic, those in Antarctica mirror canyons found elsewhere in the world,” stated Dr. David Amblàs, a researcher at the University of Barcelona.

“Yet, they tend to be larger and deeper due to the prolonged effects of polar ice and the considerable volume of sediment that glaciers deposit onto the continental shelf.”

For their research, the authors utilized version 2 of the International Bathymetric Chart of the Southern Ocean (IBCSO V2), the most comprehensive and detailed seabed map for the region.

They employed new high-resolution seabed data alongside semi-automated methods to identify and analyze these canyons.

Overall, they described 15 morphometric parameters that displayed notable differences between the southeastern and western canyons.

“Some of the submarine canyons we examined exceed depths of 4,000 meters,” remarked Dr. Amblàs.

“The most impressive among them is located in East Antarctica and consists of a complex, divergent canyon system.”

“It originates from multiple canyons near the edge of the continental shelf and converges into a single main channel that descends steeply into deep water.”

Dr. Ricardo Arosio from Cork University commented:

“The canyons in East Antarctica exhibit more complexity and branching patterns, forming varied canyon channel systems characterized by the often typical U-shaped cross sections.”

“This indicates a significant influence of long-term development under persistent glacial activity alongside erosion and sediment deposition processes.”

“On the contrary, West Antarctic canyons are short and steep, featuring a V-shaped cross section.”

“This morphological distinction supports the hypothesis that the East Antarctic ice sheet developed earlier and underwent a longer maturation process,” explained Dr. Amblàs.

“This was previously suggested by studies of sedimentary records but lacked explanation through large-scale seabed geomorphology.”

“Thanks to the high resolution of the new seabed measurement database—500 m per pixel, compared to 1-2 km per pixel in earlier maps—we can effectively apply semi-automated technology for canyon identification, profiling, and analysis,” Dr. Arosio stated.

“The strength of our research lies in the integration of various methods previously used but now brought together into robust and systematic protocols.”

“We’ve also developed a GIS software script that enables the calculation of numerous canyon-specific morphometric parameters with just a few clicks.”

The team’s research will be featured in the journal Marine Geology.

____

Riccardo Arosio & David Amblas. 2025. Topographic measurements of the Antarctic Submarine Canyon. Marine Geology 488:107608; doi:10.1016/j.margeo.2025.107608

Source: www.sci.news