Geology of the National Parks in Pictures - John D. Rockefeller Jr. Memorial Parkway

My next post about the Geology of the National Parks Through Pictures is from our move across the country from Utah to New York. Along the way we visited 13 National Parks as well as some other sites. This was the 2nd National Park along the way.

You can find more Geology of the National Parks Through Pictures as well as my Geological State Symbols Across America series at my website Dinojim.com.

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John D. Rockefeller, Jr. Memorial Parkway

Obligatory entrance sign. 

This is one of the more "unique" entries in the National Park list, since there is not much to it. They wanted a park to connect Yellowstone NP with Grand Teton NP, so they made this one. There is only one place to stop and that is this "visitor's center". When we came through back in 2010, we stopped here however the mosquitoes were so bad here I literally jumped out of the car, snapped some pictures, went inside the building for 5 second, then left. The park doesn't even have its own webpage, they use part of the Grand Teton NP webpage. 

Looking north across the park

The park itself is a changeover from the tectonic expansion seen that formed the Teton Mountains (as we talked about in the Grand Teton National Park post) to the volcanic effects of the Yellowstone hotspot (as we will talk about in the next post). Even though the park is dominated by Yellowstone volcanism some of the very northern extents of the rocks that make up the Teton mountains can be seen within the southern edges of the park, mainly in the form of Jurassic and Cretaceous sandstone and shale. The topography here is also much more smoothed out as compared to the rugged peaks within Grand Teton NP. 

Yellowstone volcano movement through North America. Image courtesy of NPS.gov.

Of the two neighboring influences, the Yellowstone volcano has a much larger impact within the park. As will be discussed in post covering Yellowstone National Park, Yellowstone is a hotspot volcano, meaning the volcano essentially stays in one place while the plate moves over the top of it. In this instance, it is the North American plate. This is a similar type of volcano as the Hawaiian hotspot. Over the past several millions of years, the path of the Yellowstone hotspot can be tracked by historical eruptions, and previous volcano calderas. The caldera is the depression on the top of a volcano, from which most eruptions emanate from. Craters of the Moon National Monument and Preserve is also a remnant of past Yellowstone eruptive activity. 

The most recent Yellowstone calderas, within and surrounding the current boundaries to Yellowstone National Park. Image courtesy of NPS.gov.

Within, and just outside, the current Yellowstone National Park can be seen the remnants of three calderas, ranging in age from 2.1 million years old to 631 hundred thousand years old. The oldest of these three calderas dates to 2.1 million years old and is known as the Huckleberry Ridge Eruption. The remnants of the Huckleberry Ridge caldera extend down into the John D. Rockefeller Jr. Memorial Parkway in the form of Lewis Canyon Rhyolite (the large pink mass in the geological map below). 

Geological map of the John D. Rockefeller Jr. Memorial Parkway. Image courtesy of NPS.gov. A map key can also be found below.

The initial 2.1 million year old eruption produced the Huckleberry Ridge Tuff, which is a rock formed from the consolidation of the erupted ash. Immediately following the deposition of the Huckleberry Ridge Tuff, several bulbous, rhyolitic lava flows were erupted which then formed the Lewis Canyon Rhyolite. Rhyolitic lavas are much more rich in silica (AKA quartz), than the Hawaiian lavas (AKA basaltic lavas) and therefore produces a much thicker (more viscous) lava flow. 

References

https://www.nps.gov/articles/000/stratotype-inventory-jodr.htm

https://www.nps.gov/yell/learn/nature/volcano.htm

https://isu.pressbooks.pub/dynamicearth/chapter/13-5-yellowstone-eruptive-history-and-the-typical-eruptions-sequence/

https://pubs.usgs.gov/pp/0729b/report.pdf

Geological Map key to the John D. Rockefeller Jr. Memorial Parkway geological map posted above. Image courtesy of NPS.gov.

Geology of the National Parks in Pictures - Grand Teton National Park

My next post about the Geology of the National Parks Through Pictures is from our move across the country from Utah to New York. Along the way we visited 13 National Parks as well as some other sites. This was the first National Park along the way.

You can find more Geology of the National Parks Through Pictures as well as my Geological State Symbols Across America series at my website Dinojim.com.

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Grand Teton National Park

Obligatory entrance sign photo. This specific photo however is from our first trip there in 2010.

Geological stratigraphic column of the Teton Range within Grand Teton National Park. Image courtesy of the USGS. 

The rocks that form the Teton Range, the mountains that make up the central focus of Grand Teton NP, date back hundreds of millions to billions of years. The oldest rocks within the part, at the bottom of the stratigraphic column, are 2.7 billion year old (Ga) gneiss. These were formed from the metamorphism of seafloor sediments and volcanic debris caught within a continental collision. 

View of the mountains towards the southern entrance near Jackson Hole, WY.

After the metamorphism of the gneiss, the rocks were infiltrated by magma bodies 2.5 billion years ago. These magma bodies slowly cooled forming the granites that top many of the mountains within the park including Grand Teton, Middle Teton, and Mount Owen. These mountains (pictured below and maybe above if the clouds weren't covering the peaks) form the middle part of Grand Teton National Park. 

Me in front of Grand Teton (the prominent point in the middle), Middle Teton (I believe the sheltered point to the left), and Mount Owen (the short point to the right of Grand Teton) along the Taggart Lake Trail.  

The last of the basement rocks formed 775 million years ago (Ma) when the region started to stretch, resulting in cracks running through the gneiss and granites. Basaltic magma flowed upwards through the cracks and cooled forming dikes of an igneous rock known as diabase. 

Along the shores of Jenny Lake.

After the formation of the igneous and metamorphic bedrocks, sea level rose and allowed for the deposition of a suite of sedimentary rocks starting with beach sands (the Flathead Sandstone at 510 Ma), then deeper water mudstones and limestones. While that was the origin of the rocks within the mountains, we now get to the formation of the mountains themselves. 

This great geological history diagram of the Tetons is located along the shores of Jenny Lake.  

As shown in the geological diagram above, the region that became the Teton Mountains started to expand yet again. This expansion started around 10 million years ago and created the Teton Fault, a normal fault. 

A normal fault

This relatively young age for the mountains makes them far younger than the nearby Rockies, which started to be formed 50 to 80 million years ago. Like the nearby Wasatch Mountains in Utah, the extensional forces that formed the Teton Mountains are related to the extensional pressures from the Basin and Range expansion. 

Extensional activity in the Basin and Range Province. Image courtesy of Miracosta.edu.

What happens in this type of expansion is that while the blocks of crust are being pulled apart, they start to rotate. This rotation is what produces the mountain peaks. Think of a row of blocks all sitting next to each other, then rotate each of them on their corner so that you have a corner sticking up, that is your mountains. The "V" that is formed between the mountains is your valleys, or basins, which begin to fill up with eroded sediment from the new mountains. These areas become nice flat plains in relation to the nearby jagged peaks. The mountains are still being uplifted through this process. Overall, the blocks have moved almost 30,000 feet along the Teton Fault and continue to move with each earthquake. 

Glacial boulders in Taggart Creek along the Taggart Lake Trail.

While the mountains are built up, erosion wears them down. There is erosion through water activity, like rain and streams, but also glacial activity. While water erosion can carve out phenomenal features over time, it has a tendency to smooth over landscape features. Glaciers on the other hand have a tendency to produce jagged, awe-inspiring landscape features. Many of the striking landscapes were formed during the last few glacial events over the previous 2 million years. Glacial erosion carved out many of the valleys within the Tetons from their "V" shaped stream profile to a "U" shaped valley, and also dug out many of the lakes within the park. Jackson Lake, by far the largest lake in the park, is over 400 feet deep carved out during the Pinedale glacial period 50,000 to 14,000 years ago.

Jackson Lake

After the glaciers eroded the mountains and carried their debris down, the material was deposited along the flanks of the mountains in piles known as moraines. Hiking up the lower slopes of the Tetons brings you through these glacial deposits where you can see many boulders such as seen along the Taggart Lake Trail above. 

Glacial pebbles

Glaciers also tend to mix up sediments from a wide variety of sources, so you end up with the awesome amalgamation of colorful pebbles in the surrounding lakes. While glaciers formed many of the lakes and moraines within the park in the geological past, there actual glaciers still within the park, although much smaller than in the geological past and shrinking ever faster with a warming climate.   

Grand Teton National Park is one of the most awe-inspiring geologically related places on the planet and just an absolutely gorgeous place to visit. 

References

https://www.usgs.gov/geology-and-ecology-of-national-parks/geology-grand-teton-national-park

https://www.nps.gov/grte/learn/nature/geology.htm

https://www.whitecoatinvestor.com/how-mere-mortals-can-do-the-cathedral-traverse-in-a-day/
https://www.nps.gov/parkhistory/online_books/grte/grte_geology/sec1.htm

https://www.discovergrandteton.org/teton-geology/geologic-timeline/

DINOSAURS!: From Cultural to Pop Culture - 1823: Mary Anning's Plesiosaur

DINOSAURS! From Cultural to Pop Culture

Modern Times

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1823: Mary Anning's Plesiosaur

Letter from Mary Anning to Sir Henry Bunbury illustrating her Plesiosaurus find. December 26th, 1823. Image courtesy of Show.me.uk.

Note: Plesiosaurs are not "dinosaurs", however since their discovery is important to the history of paleontology, they are included within this series.

In December of 1823, Mary Anning, despite having little formal training in the areas of geology, biology, or paleontology, discovered, prepared, illustrated, and described the first nearly complete Plesiosaurus specimen. Mary Anning had long been dismissed by history as an amateur fossil hunter, however within the last few decades she is achieving the accolades for which she rightly deserves. Born in 1799 and growing up fossil hunting along the "Jurassic Coast" (as it is known now), more formally known as Lyme Regis, in the southwest English county of Dorset, Mary had long been known as a superior fossil hunter, despite rarely getting the scientific accolades she deserved at the time. 

In 1811, Mary's older brother Joseph discovered the skull of an unknown animal. Upon continued searching and digging for the animal, Mary managed to unearth the entire 5.2 meter long skeleton of what turned out to be the first complete skeleton of an ichthyosaur. Prior to this discovery only fragments of ichthyosaur skeletons had been discovered and were thought to be some variety of fish vertebrae.

While that was a historical discovery, Mary's most notable discovery was yet to occur. In 1823, Mary Anning discovered a nearly complete specimen of a previously identified animal known as a plesiosaur. Having been previously described by by De la Beche & Conybeare (1821), Plesiosaurus was assumed to have been an aquatic tie between the already known Ichthyosaurus and modern day crocodiles.  However this initial description was based on a flipper and some vertebrae. It wasn't until Mary's 1823  discovery of a nearly complete specimen, which included the very important skull, that a more complete understanding was possible. After discovering the fossil, Anning then prepped, illustrated, and described it in the hopes it would be purchased by someone. She wrote a letter to Sir Henry Bunbury, as pictured above, requesting the purchase of the fossil. 

The letter read:

Sir

I have endeavoured in a rough sketch to give you some idea of what it is like. Sir, you understand me right in thinking that I said it was the supposed Plesiosaurus, but its remarkable long neck and small head shows that it does not in the least (?resemble) their (unclear, possibly another type of dinosaur?) in its analogy to the Ichthyosaurus. It is large and heavy, but one thing I may venture to assure you it is the first and only one discovered in Europe. Colonel Birch offered one hundred guineas for it unseen, but your letter came one days post before. I consider your claim to an answer prior to his. Should you like it

the price I ask for it is one hundred and ten pounds. One hundred guineas was my intended price, but if [I] take the same sum as Col B is offered he would think I had used him ill in not taking his money. - Sir I am gratefully obliged to both you Lady Bunbry for condescending to think of my favourite. He returned to Lyme at midnight quite well. I [am] also greatly obliged for your kind present of the game.

Your most humble servant

Mary Anning

Lyme, December 26 1823

P.S. Sir since I wrote the above I have received an order from the Duke of Buckingham if not sold to send him the specimen on his account. I hope you will not think me impertinent in requesting an answer by return of post I had forgot the Ichthyosaurus it is about four feete long although Not equal to C[aptain] Warrings it is not a bad specimen. The price is five pounds.

Based on the letter, and other similar letters, the fossil was purchased by the Duke of Buckingham. The fossil was then given to the geologist William Buckland, who then let Conybeare formally describe it, essentially omitting the work put in by Anning. The specimen, which is the holotype specimen (i.e., the specimen that the name is based on) of Plesiosaurus dolichodeirus (Conybeare 1824), would eventually be purchased by the British Museum of Natural History (specimen BMNH 22656). Mary Anning's plesiosaur can now be seen at the Natural History Museum, London (new specimen ID: NHMUK PV OR 22656)

Mary Anning's plesiosaur specimen as displayed at the Natural History Museum, London. Image by Adam S. Smith and courtesy of Plesiosauria.com.

A little bit about plesiosaurs. Plesiosaurs were marine reptiles (note: NOT dinosaurs), that existed from the the Late Triassic (~203 million years ago) until the end Cretaceous extinction ~66 million years ago, the same one that wiped out the non-avian dinosaurs. The deposits that Mary discovered this specimen are known as the Blue Lias Formation, and are approximately 200 million years old (the unit spans the Late Triassic Rhaetian Age to the Early Jurassic Sinemurian Age). The rocks are interbedded limestones and shales that were deposited within the deeper offshore shelf waters. The lime mud is thought to have been deposited as a result of episodic storms. 

References

https://show.me.uk/collection/letter-from-mary-anning/

https://www.nhm.ac.uk/discover/mary-anning-unsung-hero.html

https://shop.minimuseum.com/blogs/articles/mary-anning

https://upload.wikimedia.org/wikipedia/commons/e/e2/Notice_of_the_Discovery_of_a_New_Fossil_Animal_Forming_a_Link_Between_the_Ichthyosaurus_and_Crocodile_Together_with_General_Remarks_on_the_Osteology_of_the_Ichthyosaurus.pdf

https://plesiosauria.com/directory/genera/plesiosaurus/

https://www.geolsoc.org.uk/the-library/online-exhibitions/mary-anning-and-the-geological-society/reconstruction-of-life/plesiosaurus-dolichodeirus/

https://webapps.bgs.ac.uk/lexicon/lexicon.cfm?pub=BLI

https://www.sciencedirect.com/science/article/abs/pii/S0031018208004197

https://www.sciencedirect.com/science/article/abs/pii/S0016787806800337

Conybeare, W.D., 1824. XXI.—On the Discovery of an almost perfect Skeleton of the Plesiosaurus. Transactions of the Geological Society of London, 1(2), pp.381-389.