Sunday Sand: dunes, uniformitarianism, and recycling in Utah

 

There’s only one major sand dune field on the Colorado Plateau, and that can be found at the Coral Pink Sand Dunes State Park, way down in the southwest corner of Utah, not far from Zion National Park. And are these dunes really coral pink? Or reddish orange? Or orangey pink? Opinions vary – as do the colours of the sand depending on the light and the time of day. But their true colour hardly matters – they are impressive dunes.

Formed perhaps 10,000 years ago, as the northern ice was beginning to recede, their sands are home to a diversity of plants and animals, including the charming – but severely threatened – Coral Pink Sand Dunes tiger beetle, Cicindela albissima, only recently promoted to a species in its own right, and which is only found in these dunes.

The sand grains are typical of a windblown heritage, smoothed, frosted, and rounded by the endless mutual abrasion as they are buffeted by the wind. And they are all more or less of the same size – the finer grains are blown onwards, the coarser ones left behind; and they are essentially all quartz.

 

It’s the local winds that explain why these dunes are where they are. Just to the north-east of the dunes is a significant “notch” in the ranges of the plateau. The prevailing winds blast sand south-westwards, are funnelled through the notch, and, as they emerge and diminish, can no longer carry the sand, dropping it to feed the dunes. If you look at this on Google Earth, you can almost feel the sands streaming through the gap in the hills:

 

And why is that gap there? Well, because one of the great geo-architectural features of the Colorado Plateau, the Sevier Fault, cuts through it. The fault is a huge fracture in the earth’s crust, over a hundred kilometres long, and almost vertical; everything to the west of the fault has dropped down 700 meters (2300 feet) relative to the rocks on the east. The fault is clearly visible on the satellite image below, right, as a scar slicing across the landscape:

 

On the left is exactly the same area but shown as a geological map, the rocks of different ages appearing in different colours, the faults as black lines. To the east of the Sevier fault, the landscape is dominated by the light blue rocks of the Navajo Sandstone, to the west, the green of the Carmel Formation, mostly made up of limestones. The Navajo was deposited during the Lower Jurassic, around 185 million years ago, the Carmel later, on top of it, around 165 million years ago. So the map shows clearly that the movement on the Sevier fault is down to the west – the rocks of the Carmel are younger than the Navajo in the hills to the east, and have been completely removed by erosion on the uplifted side of the fault.

It’s a big and complex fault system, and the grinding of fault movement would have pulverised the rock along the fault zone, leaving it weaker and exposed to erosion – hence the gap through which the sands blow. And the Sevier fault is still on the move – it has been seismically active for a long time, part of the so-called intermontane seismic belt.

So, we have figured out why all those sand grains are piled up where they are, but what’s their story? The photo below shows the dunes in the foreground and, in background, the pink sandstones of the Navajo Sandstone on the east side of the fault. Look carefully and you will recognise dunes ancient and modern.

 

The Navajo is an iconic formation, the star of the landscapes of many of Utah’s national and state parks. It represents an enormous erg, a large sand sea that extended over most of Utah as well as parts of New Mexico, Arizona, Colorado and Wyoming. Look carefully at the bluffs in the photo, and you can see gigantic scale cross-bedding, signalling wind-blown sand, dunes. Excavate the dunes of the Coral Pink Sand Dunes (in your imagination), and exactly the same structures will be revealed – the vital principle of uniformitarianism at work. That principle derives from the observations of James Hutton in the late 18th century, that the processes we see today sculpting the surface of our planet have always operated, and always will. Commonly summarised as “the present is the key to the past,” it has been debated and refined ever since – for example, the rates at which a process, e.g., global volcanism, operated have varied over time – but the principle is, indeed, the key to our being able to read the ledgers of earth’s history. Winds have always blown, sand has always been on the move, dunes have always been built in the same way.

The bluffs of ancient Navajo dunes in south-western Utah have been exposed to the attack of weathering and erosion for a long time, disintegrating and liberating the tough little sand grains. Those grains have been swept along by rivers, left in sand banks, dried out, and picked up by the wind for the next stage of their travels – to the Coral Pink Sand Dunes State Park. There they rest, for a while, on their never-ending journey, and what you see in those dunes today are re-cycled grains from a desert nearly two hundred million years ago.

 

[Heartfelt thanks to Myrna and Charles Gifford for collecting and sending the sand, and for the photographs.

Beetle image from the US Fish and Wildlife Service; geological map from the superb Utah Geological Survey interactive map site; for resources on the Coral Pink Sand Dunes State Park, see here, here, and here.]

Iconic Beach Resorts May Not Survive Sea Level Rises, Warns Ulster Coastal Scientist

This from a University of Ulster news release last month:

Some of the world’s best known beach resorts may not survive projected sea level rises, a leading coastal scientist at the University of Ulster has warned.

 Professor Andrew Cooper, Professor of Coastal Studies in the School of Environmental Sciences at the University, said a rise in sea level of even a few feet could threaten some of the world’s most iconic resorts like West Palm Beach in the US, Cancun in Mexico, Cannes in the south of France, Torremolinos in Spain and Dubai in the United Arab Emirates.

 And he also claimed the problems caused by changing sea levels are compounded by a lack of political will and a lack of short-term coastal management initiatives.

 Professor Cooper has investigated and reported on the world’s coasts in a research and teaching career that has taken him to more than 50 countries on six continents over the past quarter century.  

 He co-authored the book 'The World’s Beaches: a global guide to the science of the shoreline' last year.

 The Coleraine-based academic said that while the most pervasive driver of coastal change at present is global sea level rise, rising sea levels alone do not necessarily threaten beaches. The problem arises when beaches are artificially hemmed in and not given room to move.

 “Beaches have survived 120 m of sea level rise over the last ten thousand years. Problems only arise if we don’t give beaches room to move and to adjust to the changing sea level.” 

 Professor Cooper explained: “A key attractor in most of the world’s examples of coastal resort cities has been the presence of an adjacent beach. 

 "Some well-known examples are Benidorm, Torremolinos, (Spain), Cannes (France), West Palm Beach, Florida, Atlantic City, New Jersey (USA), Myrtle Beach, South Carolina (USA), Virginia Beach, Virginia (USA), Cancun (Mexico) and the most rapidly developed of all coastal resort cities, Dubai (United Arab Emirates). In all of these resorts the challenge is to preserve the real estate behind the beach and still save the beaches, which are being pushed landwards by rising sea level.  

 “All around the world, people are responding to the threat of rising sea level by building concrete walls to protect valuable beachfront property.  When sea level rises, the beach wants to move, generally further landward, but the wall stops it so eventually, the beach gets squeezed out. When the rising water reaches this protective wall, as it inevitably does, the beach is drowned.”

He continued: “Coastal defences built to protect valuable developments along shoreline are stopping beaches from moving landward which is where they want to go. That’s really the Achilles heel of coastal resorts as beaches must be allowed to ‘move’.” 

 Beach replenishment or nourishment is sometimes seen as panacea for disappearing beaches but, according to Professor Cooper, this is not a solution either.

 “There are a lot of issues with beach nourishment - not least the cost – but  beach nourishment would not be needed if developments were properly planned in the first place to give beaches room to move.  Maintaining resort beaches by nourishment is a major challenge with rising sea level." 

 Professor Cooper recently published the results of a study along Australia’s Gold Coast to assess adaption options for coastal resort cities. The study, believed to be the first of its kind to specifically assess adaptation options for coastal resorts, could become a blueprint for other resorts around the world.

 “On developed coasts, human activities dominate over natural processes in shaping the coastline. Beach resort cities are mostly artificial creations on the shoreline that rely on beach nourishment to sustain them and on their reputation for a clean and safe environment.  To maintain this during rapid sea level rise will be near impossible. To hold beaches stationary while sea level rise is pushing them landwards will require a massive increase in the amount of sand being pumped onto beaches.

 “Our study of resorts along the Gold Coast of Australia suggests that with advance planning, we might just cope with a 1metre sea level rise but not even careful planning beforehand could enable resorts to survive more than that. 

 “The problems are the volume of additional sand required to hold the beach in place and the engineering requirements for protection of low-lying developments and infrastructure.  These problems are compounded by a lack of political will to adapt, uncertainty regarding how much sea level will rise, short-term coastal management initiatives, and the climate change skeptics.”

[Photos: Soil Science, D. Lindbo.]