A GRANITE BOULDER TAKES A RIDE IN UTE PASS

 By Steven Wade Veatch

With the suddenness of a rattlesnake’s strike, an enormous boulder of Pikes Peak Granite moved down one of the steep slopes of the lower part of Ute Pass, Colorado. As this rock—larger than a yellow school bus—traveled down the hill, it flattened the bushes growing in front of it, and left a trail of scraped ground behind it.

Figure 1. Gravity’s relentless force pulled this huge boulder
down the hill to its resting place near US Highway 24
between mile marker 295 and 296. This is a geohazard.
Photo © S. Veatch.

This giant rock, perched on a slope in Ute Pass along US Highway 24— between Manitou Springs and Green Mountain Falls—moved downslope from the pull of gravity in a type of erosion called mass wasting. When combined with the water of winter snow melt or rain that alters ground conditions, gravity can move rocks downhill—the steeper the slope, the faster the rocks and boulders move (McGeary, Brown, & Plummer, 1992).

During a recent summer, thunderstorms poured rain on the pass.  The slope where this boulder rested was saturated with water, making the ground a muddy, slippery mess. As the rain soaked into the soil, it filled pore spaces, which pushed apart individual grains in the soil—decreasing the resistance of the boulder to movement (Murck, Skinner, & Porter, 1997). Also, some of the grass was washed away by rivulets and rills running downslope, also adding to the conditions that mobilized the boulder.

One night when it was quiet, except for the rasp of a cricket and the passing of an occasional car on the highway, the force of gravity became greater than the resistance of the ground holding the immense boulder in place. Catching the sleeping birds in the pine trees off guard, the giant rock yielded to the endless pull of gravity and slid down the slope—a geological event that starts within the blink of an eye.

Figure 2. A once moving boulder left behind a trail and pushed up
loose gravel in front of it as it slid down the slope of Ute Pass.
Photo © S. Veatch.

This rapid movement of rocks is a geohazard that develops over time and locally impacts Ute Pass and Manitou Springs. Ute Pass and Manitou Springs are in the path of sliding and falling rocks. Work is ongoing to mitigate some of these hazards. Travelers going through Ute Pass not only have to watch other drivers, but must also look out for moving boulders.

References
McGeary, D., Brown, W. C., & Plummer, C. C. (1992). Physical Science: Earth Revealed. Dubuque: William C. Brown.

Murck, B. W., Skinner, B. J., & Porter, S. C. (1997). Dangerous Earth: An Introduction to Geologic Hazards. New York: John Wiley & Sons, Inc.

GARDEN OF THE GODS: A NATURAL LANDMARK

By Steven Wade Veatch

The tall spires and monoliths of the Garden of the Gods have been a landmark to countless travelers and explorers.  The story of these rocks starts long ago and spans many periods of geologic time. About 65 million years ago, forces in the Earth’s crust resulted in the uplift of buried Pikes Peak granite and the bending and warping of overlying sedimentary rocks to a near vertical position.  This uplift, called the Laramide Orogeny, formed a major fault, the Rampart Fault, that fractured rocks in the area and caused their movement along this and other faults.   

A view of the Garden of the Gods. Pikes Peak is in the background. 

South Gateway Rock (left) and North Gateway Rock (right) are 

eroded features of the Lyons Sandstone. A Ute encampment 

is seen at the base of North Gateway Rock. 

Antique postcard from the S.W. Veatch collection.

The Rampart Fault divides the Garden of the Gods Park. Rocks on the west side of the park are at an angle of 45 degrees or less. It is here that the rocks of the Fountain Formation, such as Balanced Rock, are on display. To the west were the Ancestral Rocky Mountains, formed 300 million years ago. Erosion washed down unsorted sand and pebbles of many sizes from the nearby Ancestral Rocky Mountains. By 250 million years ago these mountains were eroded away, leaving behind sediments piled up as gravels in layers that formed the Fountain Formation.  This rock unit, up to 4,500 feet thick, has a dark red color from the chemical alteration of iron minerals.  

Rocks of the Fountain Formation are on the west side
of the Garden of the Gods park. Balanced Rock is on
the left, Steamboat Rock is on the right. These landmark
conglomerate rocks reveal the interbedded nature of
the Fountain Formation.  Antique postcard from the
S.W. Veatch collection.

Rocks east of the Rampart fault have been tilted more than 90 degrees from their original, horizontal position, such as the North Gateway Rock, which is formed from ancient sand dunes when the area was much drier and windier 280 million years ago when all the continents were joined into one giant landmass known as Pangaea.  Today, geologists call this rock formation the Lyons Sandstone which is composed of uniform sized grains of sand. The Lyons Sandstone was deposited largely in a desert environment, and oxidation of iron to hematite caused the red color. 

Archaeologists tell us people have visited the Garden of the Gods for over 3,000 years.  Before the advent of settlers and their occupation, the plentiful game, wild plants, and nearby water, made the park a good camping site for the Ute people and other Indian tribes. 

Starting in the 1800s, explorers spread the word of the scenic wonders there. The 1850s and 1860s brought gold prospectors through the region and others who stayed and farmed and raised cattle in this area.  With the establishment of the railroad in the 1870s, tourists flocked to see the unusual sandstone formations. 

In 1879, General William Jackson Palmer, the founder of Colorado Springs, persuaded his friend, Charles Elliot Perkins, to buy land in Garden of the Gods.  Perkins paid $22.00 per acre for 480 acres that surrounded the Gateway Rocks.  Perkins, who lived in Iowa, was the president of the Chicago, Burlington and Quincy Railroad.  He never built on his land in Garden of the Gods and wanted his holdings to become a public park. Perkins died before this could be arranged.  In accordance with their father’s wishes, Perkins’ children offered the land to the City of Colorado Springs with the following restrictions: 1) the park will be free of charge to visitors; 2) the park will be known as Garden of the Gods; 3) no liquors could be made or sold in the park; and 4) no buildings could be built, other than those needed to maintain the park. 

Late in 1909, the Colorado Springs City Council accepted the land and conditions.  Today, Garden of the Gods Park, with over 1,360 acres, is a national landmark (designated in 1972 by the U.S. Department of the Interior) and a popular destination for tourists from all over the world. We all owe a debt to the Perkins family.

Fun with the Short Line’s Push Cars

By
Steven Wade Veatch and Peter Doolittle

The narrow-gauge Colorado Springs and Cripple Creek District Railroad, or Short Line, was built along what is now the Gold Camp Road. By 1901, the train ran all the way from Colorado Springs to Cripple Creek. This was the shortest route from the goldfields to Colorado Springs. Train cars, filled with gold ore, rumbled along the rails behind powerful steam locomotives to mills on the west side of Colorado Springs. The route also operated two daily passenger trains that provided service each way.

Figure 1 is an antique postcard that shows what is known as a "gravity car" that was popular with tourists, photographers, and other interested people from the Pikes Peak region who took a trip on these gravity cars that rolled down the grade at fast speeds from a point known as the “Summit” eastward to Colorado Springs.

Figure 1. This photo shows two tourists riding down a grade of the 

Colorado Springs and Cripple Creek Railroad on a gravity car. 

This photo is on a postcard.  From the S. W. Veatch collection.

These gravity cars could reach speeds of 40 MPH! What a thrill that must have been in these early days. This car appears to a lever operated handbrake. The location depicted in the postcard is Point Sublime on the Short Line. The lake in the distance is at the Broadmoor Casino, now the Broadmoor Hotel.

The white post in this picture is most likely a warning for a crew operating a flanger, or snow plow, that there is a bridge or tunnel ahead. There is probably some structure or obstruction out of view to the left in the postcard. Note the guard rails between the two outer rails going to the left. Those are usually present on a bridge or trestle, possibly a tunnel, to keep derailed equipment from falling off into the abyss or causing damage to the structure being protected. 

This so-called gravity car was known as a push or hand car and was used by section men or "gandy dancers" who were responsible for inspecting and maintaining a section of the railroad track. The gandy dancers used the push cars to get to and from the section they were working on that day. Push cars were a more primitive version of the pump handle handcar depicted in old movies. Someone, standing on the deck of these cars, would push them along on flat or level track by using a pole they pushed against the ground. In the case of mountain railroads, such as the Cripple Creek railroads, the push cars would be lashed onto the back of a train going upgrade and then allowed to coast down from the top of the pass or grade, carrying a gandy dancer along his section of track.

A Small White Dot

Steven Wade Veatch
Vishwam Sankaran

“There’s nothing new under the sun” goes a famous saying, and these words are very apt when trying to understand Earth’s climate trends. Thanks to numerous discoveries made about Earth’s ancient past, we now know that our climate has never been static. According to geological and paleontological records, climate change has affected the Earth throughout geologic time.

To understand climate change, researchers study past climates and events that affect climates such as volcanic activity, solar radiation, sunspot activity, astronomical changes, and other factors that influence climate. Once we understand the dominoes that have fallen during the past climate change events, we can understand and predict—to some degree—the kind of patterns that may follow current trends. To do this, scientists piece together clues from past climates provided by rock formations. Scientists likewise examine fossil records that yield climate signals from the past. These fossils range from prehistoric pollen to dinosaurs. Putting both geological and fossil records together reconstructs ancient climates and environments. More recent climate change is studied through climate records held in polar ice caps and ice sheets, ice cores, glaciers, isotopes of elements (like oxygen, carbon, and sulfur), soil sediments, and tree rings.

When we think of the term “ice age,” the picture that immediately comes to mind is early Neanderthals or Homo sapiens wrapped in animal fur, hiking endlessly through snow and ice-covered plains, striking fire, hunting mammoths, and surviving in nomadic camps. This image stems from the most recent ice age (Pleistocene Epoch), and evidence reveals more severe ice ages before the last one. Scientists know of at least five major glaciation events (see table 1). And it is speculated that some of the ice ages covered the whole Earth in snow and ice.

Table 1: Five Major Continental Glaciations. There have been five episodes of extensive continental glaciation through geologic time. The Cryogenian Glaciation lasted the longest, producing a “Snowball Earth” (Levin, 2013).
Glaciation	Time Period
Huronian Glaciation (Paleoproterozoic Era)	2.4-2.1 billion years ago
Cryogenian Glaciation (Neoproterozoic Era)	850-635 million years ago
Andean-Saharan Glaciation (Ordovician-Silurian Period)	460-430 million years ago
Karoo Glaciation (Carboniferous-Permian Period)	360-260 million years ago
Pleistocene Glaciation (Pleistocene Epoch)	2.6 million years ago to the present

Broadly speaking, a number of scientists believe Earth’s climate, throughout geologic time, can be characterized by three climate conditions. First, that of “Earth as a Greenhouse” when warm temperatures extend to the poles, eliminating the polar icecaps and all other ice sheets. The climate, in some parts of the planet, was like hell in a box. Secondly, that of “Earth as an Icehouse” which includes some permanent ice whose extent varies as glaciers periodically advance and retreat. And lastly, by what is termed as “Snowball Earth” where the planet’s entire surface is frozen up to hundreds of millions of years (Walker, 2003).

There is credible speculation that there is a fourth state: “Slush House Earth,” where there is an ice-free zone along the equator (Cowen, 2013). Today’s climate, marked by polar ice caps, is characterized by the second condition, an “Icehouse.” Since primordial times, it has been speculated that the Earth has been cycling between these phases.

The Earth froze completely in defiance to the warmth of the sun between 2.45 and 2.22 billion years ago (BYA), resulting in Earth’s first Ice Age, known as the Huronian Glaciation (named after Lake Huron in Ontario, Canada). This deep freeze may not have happened once, but perhaps several times, during the Huronian Glaciation (Levin, 2013).

The cause of this first Snowball Earth event is not known, however several theories have been proposed, including a decrease in solar output, the Earth passing through so-called space clouds, or an extreme cooling caused by a reduction in greenhouse gases ("Oceans of Ice: The Snowball Earth Theory of Global Glaciation," n.d.). Some scientists view a combination of these events could be a reason the Earth became frozen in ice. It seems likely that a sharp drop in carbon dioxide, a greenhouse gas, caused temperatures to plummet. An unimaginably thick, white ice sheet crept down from the poles. Snow, whipped by winds, danced on the crenelated surface of the ice while the bottom of the ice sheet plucked and ground the rock surface beneath as it crept forward.

During these frigid times sunlight, instead of warming the planet, bounced off the ever-spreading ice, in what scientists call the albedo effect, causing temperatures to fall—which created more ice—which bounced more sunlight back into the cold reaches of outer space (Melehzik, 2006). This process repeated in a positive feedback loop until the cooling became unstoppable: the ice marched on, temperatures plunged, and the blue planet became a small white dot—a snowball, surrounded by a riot of stars, orbiting the sun.

Of interest to scientists is that life came to a near biological standstill in the first Snowball Earth event, yet life survived this hyper-freeze phase. Even in an Earth almost entirely covered by ice, volcanoes punched through the ice by melting it. Against these odds and brutal mass extinctions, a handful of tiny organisms, living near volcanic vents on the sea floor, thrived. These organisms were anaerobic bacteria and called methanogens by scientists. The methanogens fed on mineral nutrients like sulfur, iron, and manganese from underwater volcanic vents and merrily expelled methane, a greenhouse gas. Oxygen was not present in the Earth’s atmosphere. The methanogens spread and continued to help gas-up an atmosphere that contained methane, nitrogen, and few other gasses in trace quantities. The microscopic methanogen’s methane trapped some of the sun’s energy and warmed the planet.

Following the Huronian Glaciation, the frozen planet thawed, marking one of the greatest periods of transition in our world’s history—The Great Oxygenation Event, one that would change forever the destiny of this planet we call home. Here is what happened.

Soon after Snowball Earth melted a new kind of bacteria evolved—cyanobacteria, the planet’s first photosynthesizing organisms that made oxygen (Canfield, 2016). There was a slow and episodic enrichment of gaseous oxygen in the atmosphere that continued over millions of years, possibly due to an exponential bloom of the cyanobacteria as mats that rolled and pitched with the waves of the sea.  Near the shore, cyanobacteria grew in layered structures known as stromatolites. Stromatolites were also present in some lakes and in any other shallow aquatic setting where the conditions were favorable.

FIGURE 1.  A photomicrograph of Cyanobacteria, Tolypothrix sp. Cyanobacteria produce oxygen as a by-product of photosynthesis, and it is thought this process converted Earth’s early, oxygen-poor, reducing atmosphere, into an oxidizing one, causing two major events: 1) the " Great Oxygenation Event” and 2) the so-called rusting of the Earth. Both events dramatically changed the nature of life forms on Earth and almost led to the extinction of anaerobic organisms. Image by Matthew Parker, used by permission under Community Commons Licence 3.0.

The rising oxygen levels brought the Great Oxygenation Event—a significant shift in the content of oxygen in the atmosphere (Crowell, 1999). As the cyanobacteria churned out more and more oxygen that bubbled through the water column, the methanogens almost went extinct—oxygen is toxic to them, those that survived lived in deep ocean water near hydrothermal vents and other places that protected them. In the meantime, due to the higher levels of oxygen resulting from photosynthesis, iron—previously dissolved in the oceans—could no longer stay in solution, leading to an intricate alchemy that brought the “Great Oxidation Event.”

This so-called “rusting” event formed rocks known as banded iron formations (BIFs). BIFs are white bands of chemically precipitated quartz, or chert, with alternating darker red bands of the iron oxide minerals hematite and magnetite. From this oxidation of iron and the formation of BIFs, we infer that oxygen began to appear in Earth’s atmosphere.

FIGURE 2. An exposure of banded iron formations (BIFs) at the Fortescue Falls, Dales Gorge, Karijini National Park, Western Australia. Cyanobacteria contributed oxygen to Earth’s atmosphere. This oxygen, combined with iron in the ocean’s water, caused chemical precipitation of iron oxides, and formed dark red bands that alternated with white bands of chert that produced the banded iron formations. Photo by Graeme Churchard, used by permission under Community Commons Licence 2.0.

Scientists continue to speculate on the source of the iron that was dissolved in the oceans prior to the Great Oxygenation Event. One source of the iron likely weathered from iron-bearing rocks on land masses. Another, much larger source of iron spewed out in dark clouds from more active submarine volcanoes and hydrothermal vents on the seafloor. 

The BIFs were deposited in a relatively brief geologic time between 2600 and 1800 million years ago, and occurred in great bodies that exceeded hundreds of meters in thickness and extended thousands of meters laterally (Macdougall, 2004). BIFs are an essential part of our modern industrial complex as they yield most of the rich iron ore mined today from the massive iron ore deposits of Minnesota, Michigan, Ukraine, Brazil, Labrador, and Australia (Levin, 2013).

Despite the frozen conditions of the first Snowball Earth, the period following it was an evolutionary triumph when oxygen became part of Earth’s atmosphere and early life flourished.  Oxygen formed the extensive iron ore deposits that are the foundation of modern society.  Although we are building a compendium of knowledge about past and present climate change, unanswered questions about Snowball Earth remain while certain aspects of climate change remain unknown. 

An army of scientists, with intellectual fire, continue their work in their search for answers. Even if we do not find some of these unknown factors affecting climate change, those factors will perhaps find us. 

References Cited

Canfield, D. (2016). Oxygen: A four billion year history. Princeton: Princeton                   Univ. Press.

Cowen, R. (2013). History of Life. Oxford: Wiley-Blackwell.

Crowell, J. C. (1999). Pre-Mesozoic Ice Ages: Their Bearing on Understanding the Climate System. Boulder: Geological Society of America.

Levin, R. (2013). The Earth Through Time. Hoboken: John Wiley and Sons.

Macdougal, D. (2004). Frozen Earth: The Once and Future Story of Ice Ages. Berkeley: University of California Press.

Melezhik, V. A. (2006). Multiple causes of Earth's earliest global glaciation. Terra Nova, 18(2), 130-137.

Oceans of Ice: The Snowball Earth Theory of Global Glaciation. (n.d.). Retrieved from http://dujs.dartmouth.edu/2010/05/oceans-of-ice-the-snowball-earth-theory-of-global-glaciation/

Walker, G. (2003). Snowball Earth: The Story of the Great Global Catastrophe that Spawned Life as We Know It. New York: Crown Publishers.