Monday: We will leave school and after dropping off the juniors and seniors and eating lunch, we will have a short class session and then head for the Mojave Desert.

On the way, we will stop at Boron to see the Borax open Pit Mine, and take a tour of the processing plant. You have already seen the video about how the Boron is mined, what mineral forms it comes in, and how it is processed and used.

The Kramer borate deposit is now the major source of most of the borate compounds produced in the U.S. as well as the world, although a Turkish mine is making headway in the industry.

The open pit mine should have no problem in continuing its mining well into the year 2000, due to the large amounts of deposits still existing in the southeast corner of the mine.

After our stop at the Borax mine, we will travel 30 miles west on highway 58 to Mojave, where we will make a restroom stop and fuel up. From there we travel north on highway 14 to Red Rock Canyon about 30 miles away. This will be our camping spot for the night. We will use what daylight we have left to set up camp, eat dinner and explore the local area. Tomorrow we will spend the morning at Red Rock Canyon.

Tuesday: After breakfast, we will take about two hours to visit Red Rock Canyon.

Red Rock Canyon is famous worldwide for its "old west" look. Many westerns have been filmed here over the years, including the TV series Bonanza. Yet, the geology of Red Rock Canyon is even more impressive; sedimentary layers give geologists a look into the past, and the desert climate creates some impressive "badland" type erosion. Badlands most commonly form in sedimentary deposits soft enough to erode easily, but coherent enough to stand in very steep faces. Desert thunderstorms let loose very large drops, effective in producing threads, rills and gully drainage patterns. This drainage system forms columns, spires, chutes, and alcoves; color variation of the local rock include white, cream, beige, brown, pink, red and green.

The main rock group in the park is the Ricardo formation, named after the only human settlement to remain for any length of time. Ricardo was either an innkeeper there, a small boy who tended stagecoach horses, or a member of the original family to settle there, the Hagars; no one knows for sure. The Ricardo formation can be broken into two sub-formations, the Cudahy and Dove Spring. Together, these two total about 7,000 feet in thickness. In Red Rock Canyon, only the Dove Spring formation is visible; the Cudahy formation is exposed in Last Chance Canyon farther east. How could sedimentary rock form to that thickness? The action of the Garlock and San Andreas faults caused warping in the region, causing a large basin to form called the El Paso. From about 19 million years ago to less than 7 million years ago, the basin has been filling with sediments. The basin sank slowly, and as it sank, deposition occurred to keep the relief fairly even.

From the south, Highway 14 makes a dramatic entrance into the park. At the south face of the El Paso Mountains, look for the El Paso fault (which is marked by the front of the mountain range).

From the parking area (stop #1), look north to see the first badland exposure. The Red Cliffs (named for their color) display accordion like drainage. Look closer to determine if the layers are horizontal or tilted.

Walking south across the parking area, look at the top of the bluffs. A thick and massive layer of tan to pink rock caps them. If you have time to inspect it closely, you will find it is composed of a fine matrix of consolidated volcanic ash (or tuff) which includes small angular fragments of a variety of rocks, mostly volcanic. This rock is called tuff breccia. It was deposited by a fast moving, hot ash flow, erupted from a nearby volcano 12 to 13 million years ago. That volcano was on the south side of the Garlock fault, which has since displaced the volcano many miles to the east (what type of fault would that be?). If you look down from the cliffs, you will see a small fault, inclined to the east, that displaces the contact between the tuff breccia and the underlying sedimentary beds by about 30 feet.

There are other geologically interesting formations within the park, again showing the badland topography and faulting.

We will leave Red Rock Canyon and head north towards Bishop. On the way we will stop at Coso Junction to eat lunch and view an impressive basalt flow. The basalt was cut by glacial Owen River. At the head of the flow is a dry waterfall and evidence of flowing water; the rocks have been worn smooth. You will notice that the basalt is full of holes, 1/4"-1/2" across. These were formed by bubbles of gas in the molten material at the time of flow. The last major discharge of the Owen River was during the last minor ice age, 10-15 thousand years ago. The silt laden water did a good job of eroding the basalt. Where do you think the source of this basalt was?

We travel further north, and just past the town of Olancha, Owens Lake comes into view. This once large lake is now mostly dry, except for exceptionally wet years. Since 1913, the flow of the Owen River that fed this lake has been diverted to the aqueduct, shrinking the lake to its present size. During the last ice age, the lake was 220 feet deep. Even before that, the lake suffered from a high rate of evaporation, causing the water to be saline. Salts of various sorts crystalize in lakes as these (similar to the lake that was responsible for the great salt deposits in Boron). Among the salts mined from this lake were Soda ash and Boron.

Looming large to the west is the Sierra Nevada range. We will study how this range came into being later.

We will be stopping at the north end of Owens Lake to view abandoned shoreline markings.

To the west the Alabama hills begin to rise (in front of the Sierras). These hills formed by way of a Normal fault. We will discuss this further at our next stop, which is a gravesite used to bury those killed by the 1872 earthquake, one of the largest earthquakes in historical times. This gravesite is located on an older scarp caused by the down-dropping of the Owens Valley in respect to the Sierras. In fact, the basement rock of Owens Valley is 6000 feet below sea level, but sediments from the Sierra Nevada and the White Mountains to the east have filled the basin to its current level.

The scarp from the 1872 earthquake can be seen 3/4 mile southwest of here. As we travel north, you will see many scarps to the west of the highway, evidence of the tectonic activity taking place here.

We will fuel up at Bishop, and continue on highway 395 as it heads west. In a few miles, we start our ascent towards Mammoth. This ascent is on what is called Sherwin Grade, and takes place on the upper surface of the Bishop tuff. Somewhere not too far to the north, about 700,000 years ago, volcanic vents repeatedly ejected clouds of hot glowing ash and rock particles that spread out over a great distance. These flows flowed by gravity, and they were kept mobile by gases being released from the hot volcanic fragments. When the material came to rest, it was still so hot that the material partly recrystallized and fused, creating a coherent rock called tuff.

When the eruptions ceased, it left a nearly level sheet of material averaging 500 feet in thickness. The sheet extends from Mono Lake south to Bishop, a distance of 50 miles. It has since been deformed by faulting and warping, and today it is being eroded so that only remnants are preserved. The grade follows the largest remnant remaining. The ascent we are taking was tilted by faulting.

As we drive, you can see what the Bishop tuff looks like by observing the road cuts as we drive. When fresh, this rock is mostly pink, but weathered exposures appear brown.

Also look toward the south into the canyons of the Sierras for signs of glaciation. Many of the canyons in this area were carved by glaciers, with large moraines deposited in or near the valley floor. Also look for fault scarps that offset the moraines themselves.

As we near the top of Sherwin grade, you will see a large lake to the north. This is Crowley Lake. It is an artificial lake that lies on the south edge of Long Valley (you’ll be hearing a lot about Long Valley during this trip). Our campground is on the northwest side of the lake. Dress warmly, it will get cold and it might be windy.

Wednesday: We will do some mapping and sketching of geological features. Our first stop will be Hot Creek, a place where hot springs have formed.

Hot Creek lies within a 10 by 20 mile caldera called Long Valley, a product of a massive volcanic eruption about 730,000 years ago. After the eruption, a lot of molten rock was left behind under the surface, and through weak spots in the lithosphere has leaked to the surface. These "leaks" are the cause of all the cinder cones, domes, craters and hot springs we will be seeing over the next few days. The hills around Hot Creek are domes caused by rising magma below the surface. Mammoth Mountain (to the west from here) was also built up by rising magma. The heat source of Hot Creek is from magma just a few miles below the earth’s surface.

The future of Long Valley and Mono Craters just to the north is uncertain. Geologists believe that this area is the next one to erupt (second only to Mt. St. Helens). Two important new studies by Dan Miller of the USGS and Kerry Sieh of Cal Tech have predicted increased volcanic activity in the area. Recent earthquake activity seems to backup the theory that magma is once again making its way to the surface. When this area does become active, it won’t be from a single crater. This area historically erupts from numerous vents stretching from Mono Lake southward to Crawley Lake. Residents of the area are naturally concerned, as this includes towns such as Mammoth Lakes and Lee Vining, not to mention a large public-use recreational area. Historically, this region erupts every few centuries, and since the first eruption took place 600 years ago, the region appears to be headed towards another active stage (Harris, 123).

From the parking lot, scan the horizon. To the east is the White Mountains (+14,000). Looking north, you can see the northern edge of the caldera marked by Glass Mountain. To the west is Mammoth Mountain, while to the south is Mt. Morrison (12,268 feet).

Hot Creek flows within a narrow gorge cut deeply into the relatively soft volcanic rock of the Long Valley Caldera. The rock cliffs are mostly rhyolite, but some have been altered by hot water and volcanic gases (mostly steam and carbon dioxide), along with some sulfur dioxide and hydrogen sulfide (that’s the gross smelling stuff). The sulfur oxide gases combine with the water to form sulfuric acid, which is highly corrosive to rocks, vegetation and geothermal pipes.

Many of the hot springs surround themselves with siliceous sinter, a rock made of a form of silica similar to opal, and travertine, a banded form of calcite. These solids form when the hot water cools and loses its gases, which causes the silica to precipitate. These minerals also deposit in pipes, which makes the use of geothermal energy difficult.

On your Hot Creek Map, you will be splitting up into groups and mapping the locations where a) there is current hot spring/fumarole activity and b) areas that have been active in the past. CAUTION: Do not climb over any fences. The areas near hot springs can be treacherous and can collapse under your weight. The water in the hot springs has been responsible for a few deaths over the years, all caused by carelessness.

There has been a number of attempts to use hot springs to produce electricity. Just north of Hot Creek is the Casa Diablo Hot Springs Power Plant. Early attempts at generating power failed for several reasons: the steam is highly corrosive to pipes, drilling caused geothermal activity to decrease, and the hot water that was brought up polluted the groundwater due to boron and arsenic. A new plant was dedicated in 1991, and uses a large building to condense the steam into water to comply with environmental standards. It produces 40 megawatts of electricity (enough for 10,000 homes).

Our next stop will be to Convict Lake. We will be observing glacier depositional features, and sketching the layers of rock that make up Mt. Morrison (if it is free of snow). The mountain is made of Ordovician and Silurian marine sediments. These sediments have been overturned so that the older Ordovician sediments lie on top of younger Silurian sediments.

All the way up the road leading to Convict Lake are moraines made up of till. We will hike the trail along the western edge of Convict Lake to see more effects of glaciation.

We will be traveling into town tonight for dinner, either at McDonald’s, Carl's Jr. or Shakey’s.

Thursday: This is an exploration day throughout the Mammoth lakes/Long Valley area. We will be traveling to Mono Lake and the Mono Craters, exploring volcanism and the rock types associated with this process (extrusive igneous). We will be mapping a number of craters and lava flows throughout the day, looking for a pattern in this geologically active area. Thursday: This is an exploration day throughout the Mammoth lakes/Long Valley area. We will be traveling to Mono Lake and the Mono Craters, exploring volcanism and the rock types associated with this process (extrusive igneous). We will be mapping a number of craters and lava flows throughout the day, looking for a pattern in this geologically active area. Thursday: This is an exploration day throughout the Mammoth lakes/Long Valley area. We will be traveling to Mono Lake and the Mono Craters, exploring volcanism and the rock types associated with this process (extrusive igneous). We will be mapping a number of craters and lava flows throughout the day, looking for a pattern in this geologically active area.

We will be taking a short loop around June Lake, and study glaciation patterns in the area.

Next we will visit the Mono Craters. Mono Craters is a collection of about 20 domes, extending in a gentle arc to the south where they run into the Long Valley caldera. They were formed during an active period of the caldera dating back to 12,000 years ago, although some have formed as recently as 1,800 years.

While on the south end of Mono lake, we will also take a short hike down to the tufa towers. They were formed at the openings of underwater springs by the precipitation of minerals, usually calcium carbonate, sometimes silica. They can only form underwater, which allow us to imagine a former level of the lake. We will be doing some field work here to attempt to determine the historic shoreline of this once great lake.

If time permits we may also visit Bodie, an old ghost town in the mountains north of Mono Lake. If we go to Bodie, you will see one of the best preserved ghost towns in California. The mines produced over $30 million of gold and silver ores between 1876-1890. The ore was found in veins caused by the upwelling of mineral rich water from deep within in the earth which solidified as quartz veins.

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