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Undergraduate Spring Break Field Trip 2014Western Texas and Southern New Mexico
Department of Geological Sciences, Brown University
davis mountains - big bend - guadalupe mountains - white sands
Itinerary
Part One: Davis MountainsDay 1: Friday, March 21
Early Morning: Fly Delta Air Lines flight 1263 from PVD to ATL (duration 2 hours 49 minutes)Morning: Fly Delta Air Lines flight 2136 from ATL to ELP (duration 3 hours 28 minutes)Midday: Claim checked baggage, obtain rental cars, and shop for food at WalmartAfternoon: Drive 3.5 hours to Davis Mountains State ParkEvening: Set up camp at Davis Mountains State Park and eat dinnerEvening: Attend the McDonald Observatory Star Party (2 hours)
The Star Party takes full advantage of the dark night skies of Western Texas. Constellations and celestial objects will be viewed through numerous telescopes at the observatory.
Day 2: Saturday, March 22
Morning: Hike the 2.4-mile Madera Canyon Trail (2 hours)The Nature Conservancy’s Davis Mountains Preserve hosts the 900 ft.-deep Madera Canyon. Springs and volcanic dikes are noteworthy features.
Morning: Attend the McDonald Observatory daytime tour This 2 hour 30 minute guided tour includes a 45-50 minute solar viewing and 90-100 minute tour of the facilities.
Afternoon: Drive 20 minutes to Fort Davis National Historic Site, have lunch, and exploreAfternoon: Visit the Chihuahuan Desert Nature Center
This nature center is located in the foothills of the Davis Mountains and has a desert botanical garden and short walking trails to explore.
Afternoon: Drive 2 hours 30 minutes to Big Bend National ParkWe will stop at the Fossil Bone Exhibit on the way into the park.
Evening: Arrive at Chisos Basin Campground and set up camp
Part Two: Big BendDay 3: Sunday, March 23
Morning: Hike 10.5-mile Emory Peak Trail (7 hours)This mountain trail goes past spectacular vistas and leads to the highest peak in the park. The last 25 feet requires a scramble up an exposed rock face.
Evening: Hike the 0.3-mile Window View Trail (5 minutes); enjoy sunset at 8:05pmThis easy stroll offers excellent views of the mountain peaks surrounding the Chisos Basin.
Day 4: Monday, March 24
Morning: Drive to the Ross Maxwell Scenic Drive (45 minutes)This scenic drive showcases some of the most historic and geologic features of Big Bend.
Morning: Hike the 3.8-mile Mule Ears Spring Trail (3 hours)This hike leads through the foothills of the Chisos Mountains, skirts Trap Mountain, and crosses several arroyos. An old rock corral is near an overgrown spring with shrubs, ferns, and cattails.
Midday: Drive to Tuff Canyon and hike through the gorgeAfternoon: Visit the Castolon Historic District Visitor Center
Castolon was established as a cavalry camp in the early Twentieth Century. Afternoon: Hike the Santa Elena Canyon Trail (1 hour)
The trail follows the Rio Grande upstream and then drops down to the canyon floor of this 1,500-foot vertical chasm. The right wall of the canyon is in Texas, while the left wall is in Mexico.
Afternoon: Hike the 0.5-mile Burro Mesa Trail (30 minutes)Evening: Make brief stops at the Sotol Vista Overlook and Blue Creek Ranch Overlook (time permitting)
The Sotol Vista offers views of the entire western side of Big Bend National Park, including Santa Elena Canyon. The Blue Creek Ranch Overlook provides views of the headquarters of the Homer Wilson Ranch, which used to be one of the largest in the region.
Day 5: Tuesday, March 25
Morning: Hike the 4.8-mile Lost Mine Trail (3.5 hours)This trail is a great way to witness the flora and fauna of the Chisos Mountains. The trail climbs steeply in and out of juniper, oak, and pine forest. The ridge offers superb views of Pine Canyon and the Sierra del Carmen in Mexico.
Afternoon: Drive 1 hour to the Terlingua ghost town; explore the ghost townThe ruins of the Chisos Mining Company are the backdrop of this unique stop.
Afternoon: Visit the Barton Warnock Environmental Education Center Self-guided tours go through the Interpretive Center and two-acre desert garden.
Afternoon: Drive 1 hour 15 minutes to the Grapevine Hills TrailAfternoon: Hike the 2.2-mile Grapevine Hills Trail (1 hour)
This trail leads hikers to a balanced rock formation. Evening: Drive back to camp
Day 6: Wednesday, March 26
Morning: Pack up camp and drive 2 hours to Big Bend Ranch State ParkMorning: Hike the 1.4-mile Closed Canyon Trail (1 hour) and 1-mile Hoodoos Trail (1 hour)
Closed Canyon is a narrow slot canyon. The Hoodoos Trail descends to the Rio Grande river.Afternoon: Drive 2 hours to Marfa, TX; shop for foodEvening: Drive 2 hours 15 minutes to Guadalupe Mountains National Park; set up camp at Pine Springs Campground
Part Three: Guadalupe MountainsDay 7: Thursday, March 27
Morning: Guided and self-guided tours of Carlsbad CavernsThe 2-hour Left Hand Tunnel tour begins at 9:00am and the 1.5-hour Kings Palace tour begins at 10:30am. Both cave groups will also take the Big Room self-guided tour.
Afternoon: Hike the 0.9-mile McKittrick Canyon Nature TrailTrailside exhibits describe common plants. This is also a great opportunity to learn about Permian Reef geology.
Afternoon: Hike the Permian Reef Geology Trail (3 hours)This is a trail for serious geology buffs. There are excellent views looking down into McKittrick Canyon from the top of Wilderness Ridge. The trail is 8.4 miles round-trip, but turn around after hiking 1 hour 30 minutes.
Evening: Hike the short Pinery Trail before dinnerThis short hike from the Pine Springs Visitor Center goes to the ruins of the old Pinery Station, once a favored stop on the original 2,800-mile Butterfield Overland Mail Route. Trailside exhibits describe Chihuahuan Desert vegetation.
Part Four: White SandsDay 8: Friday, March 28
Morning: Hike the 2.3-mile Smith Spring Trail at Frijole Ranch (1.5 hours)Enjoy the shady oasis of Smith Spring and the gurgling sounds of the tiny waterfall before continuing around to sunny Manzanita Spring.
Morning: Drive 2 hours 30 minutes to El PasoMidday: Take the Wyler Aerial Tramway and have lunch at the top
The tramway offers panoramic views of the Franklin Mountains. Afternoon: Drive 1 hour 45 minutes to White Sands National MonumentAfternoon: Explore White Sands
Potential activities include going on short hikes and sledding down the gypsum dunes. Hiking options include the Playa Trail, Dune Life Nature Trail, and the Interdune Boardwalk.
Evening: Drive 40 minutes to Oliver Lee Memorial State Park; set up camp
Return to Brown UniversityDay 9: Saturday, March 29
Morning: Eat a pancake breakfast; clean up the campsite and rental carsMorning: Drive 1 hour 30 minutes to El Paso International AirportAfternoon: Fly Delta Air Lines flight 2136 from ELP to ATL (duration 3 hours 12 minutes)Evening: Fly Delta Air Lines flight 772 from ATL to PVD (duration 2 hours 25 minutes)Night: Arrive at the Providence airport, claim checked baggage, and return to GeoChem
Undergraduate Students:Jeff BaumJonah BerkowitzRaquel BryantChris CarchediLena ChamplinCamera FordAdam GilbertAlan Gorchov NegronGreg Jordan-DetamoreLydia JoukowskyRachel KaplanAllison LawmanOliver McLellanJames NapoliNick O’MaraGene RobinsonBekah SteinMarina StevensonConor SullivanKlara Zimmerman
Graduate Students:Sam BovaTabb Prissel
Professor:Steve Parman
This book was designed by Greg Jordan-Detamore and organized by Greg Jordan-Detamore, Klara Zimmerman, and Allison Lawman.
This trip generously received funding from the Rhode Island Space Grant Consortium.
Itinerary iChihuahuan Desert 2Regional Deformation History 3Stratigraphy and Noteworthy Structural Features 4
Davis Mountains 7Friday, March 21 9Davis Mountains 10McDonald Observatory 12Dark Energy Experiment 13Saturday, March 22 14Davis Mountains Preserve 15Chihuahuan Desert Nature Center 16
Big Bend 17Big Bend National Park 21Geology of Big Bend 22Paleontology 24Dinosaurs and Pterosaurs 26History and Culture 28Sunday, March 23 29Wildlife of Big Bend 30Collared Peccary 32Monday, March 24 34Ross Maxwell Scenic Drive 35Igneous Geology 36Rio Grande River 38Tuesday, March 25 40Terlingua and Mining History 41Wednesday, March 26 42Big Bend Ranch State Park 43Native American History 44
Guadalupe Mountains 45Geology of Guadalupe Mountains 48Environment of Guadalupe Mountains 50Roadside Geology Guide 52Thursday, March 27 54Carlsbad Caverns 55Speleothems as Climate Proxies 57Cave Geology 58Bat Research 60McKittrick Canyon Geology 62Permian Reef Geology Trail 64
White Sands 67Friday, March 28 71Smith Spring Trail 72White Sands 74Common Native Plants 76Common Tracks and Scat 78History of Commercial Filming 80Recent Research 82Planetary Analog 84Sacramento Mountains 86
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Saturday, March 22Morning: Madera Canyon Trail (B)
The Madera Canyon Trail offers a glimpse into The Nature Conservancy’s Davis Mountains Preserve, a unique sky island with plants and animals found nowhere else in the world.
The trail offers a moderate hike. Most of the trail is on sloping terrain. After crossing the Madera Creek, the trail winds through pinyon-oak-juniper woodlands to a scenic view of 8,378 foot Mount Livermore. The cliff tops in front of you offer a beautiful overlook of Madera Canyon. — The Nature Conservancy
Midday: McDonald Observatory (C)The Visitors Center operates a set of specially filtered
telescopes equipped with HD video cameras that allow us to bring live, safe views of the Sun into our multimedia theater. Your knowledgeable guide will discuss some interesting highlights about the history of the Sun, its formation, and what we expect the Sun to do over its expected 5-6 billion year remaining “lifetime”. Assuming relatively clear skies, your guide will use the telescopes’ remote controls to steer around a live view of the Sun showing and discussing various surface features typically visible. On not so clear days, video and stills from clear days as well as from the web are used. This is typically a 45-50 minute program. ...
Your guide for the Solar Viewing is also your guide for the Tour immediately following the Solar program.
The Tour typically begins at the overlook to the south of the 107” dome. From there, peaks over 80 miles way can be seen. At this location, your guide will typically discuss some of the history of the Observatory and why this location was chosen for an astronomical research facility. After pointing out some of the peaks in the area, the tour typically then proceeds to the ground floor lobby of the 107” dome where some of the history of that telescope is discussed. After a climb up four flights of steps (an elevator is available for those who shouldn’t or can’t take the steps .. your guide with discuss access to the elevator) the tour continues with descriptions of the parts of the telescope seen at the 5th floor level, demonstrations of the telescope motions, etc.
After visiting the 107” telescope, your guide will provide instructions for continuing with the tour at the summit of Mt. Fowlkes and the Hobby-Eberly Telescope. At the HET, you’ll learn more about that telescope’s unique, low-cost (for a world class telescope, at least) design and about new cutting-edge research projects for which the HET is currently being re-engineered.
— McDonald Observatory
Midday: Fort Davis National Historic Site (D)A brief stop here will give us a chance to rest while taking in some of the local history.“Fort Davis is one of the best surviving examples of an Indian Wars’ frontier military post in the Southwest. From 1854 to
1891, Fort Davis was strategically located to protect emigrants, mail coaches, and freight wagons on the Trans-Pecos portion of the San Antonio-El Paso Road and on the Chihuahua Trail.” — National Park Service
Afternoon: Chihuahuan Desert Nature Center (E)In 1978, the board and supporters of the Chihuahuan Desert Research Institute purchased 507 acres of rolling grassland, oak-
studded hills, and shady canyon springs in the foothills of the Davis Mountains. Here, they established the Chihuahuan Desert Nature Center. For over three decades, visitors have explored this tranquil and visually stunning site, taking the opportunity to reconnect with nature and discover the desert.
Highlights of the Nature Center include a desert botanical garden, 1400 sq. ft. cactus and succulent greenhouse, over 3 miles of hiking trails, and interpretive exhibits. Both formal and informal education programs for children and adults are offered throughout the year. — Chihuahuan Desert Research Institute
Afternoon: Drive to Big BendOur drive to Big Bend National Park will take approximately 2.5 hours. On our way into the park, we will stop at the Fossil
Bone Exhibit.We will set up camp at Chisos Basin Campground in the center of the park.
Big Bend
Big Bend national Park is a chihuahuan Desert nature Preserve that will introduce us to Southwestern geology. We’ll explore volcanism, rock deformation, dinosaur fossils, and landscapes modified by the erosive power of the rio Grande river.
Sunday, March 23Monday, March 24Tuesday, March 25Wednesday, March 26
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national ParK Service
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The author Fredrick Gelbach describes these bor-derlands aptly when he calls them “a carpet of inter-acting plants and animals deftly woven on a geologic loom.” This statement conjures up images of looming mountains, stark desert landscapes, and a ribbon of water slicing through it all. And, indeed, this is what Big Bend and the surrounding area is—a diverse natu-ral area of river, desert, and mountains, and a land of extremes—hot and cold, wet and dry, high and low. To wander the shimmering desert flats, to ascend the rimrocks of the desert mountains, to float the canyons of the Rio Grande—to be “on the border”— is to ex-perience sights and sounds and solitude unmatched elsewhere.
In the heart of Big Bend National Park lie the Chi-sos Mountains, mountains born of fire during volcanic eruptions and intrusions 40 - 60 million years ago and exposed by the incessant forces of erosion. As you as-cend the slopes of the Chisos, the thorns of the desert give way to evergreens like pinyon pine and juniper, and oak trees appear. Some surprising species living at the very limit of their ranges can be found in the high-er, moister areas—bigtooth maple, quaking aspen, and Douglas fir. Although only 2% of the park is wood-land, this area draws people like a magnet—especially in the summer—as daytime temperatures are usually about 20 degrees cooler than by the river. Here, in this mountain island surrounded by a desert sea, one can find flora and fauna unique to the Chihuahuan desert and some unique to Big Bend.
Whether hiking to gain a glimpse of the colima warbler, a much sought after bird by birdwatchers which winters in Mexico but is only seen in Big Bend here in the U.S., or to get a coveted look at a mountain lion or black bear, or to see the towering displays of the century plants in bloom—whatever the reason, visitors to the Chisos are struck by the contrasts the mountains provide—prickly pear and pine tree side by side, snow-covered cactus, and a waterfall flowing through a fea-ture called the “Window” to the desert below.
It’s been said that if the Chisos Mountains are the heart of Big Bend, then the desert floor is its soul. Ninety-eight percent of the park is desert, and like the mountains, the desert is a land of contrasts—a place where you can touch 400 million year old rocks with one hand, and a day-old flower with the other, where extremes of temperatures of 50 degrees or more be-tween dawn and mid-day are not uncommon.
Big Bend’s desert landscape itself is a study in con-trasts—mesas, mountains, and dikes formed by vol-canic activity, limestone ridges and cliffs formed 100 - 200 million years ago when shallow seas covered the
area, and ever-changing arroyos, dry most of the year, but subject to violent flash flooding during summer rains. Water is truly the “architect” of the desert, as its presence or absence determines the way the desert looks, its plant and animal life, and the way humans have been able to use it through time. Lest you feel a pang of pity for the roadrunners, coyotes, or javelinas you may encounter living in this harsh land, don’t—the adaptations that allow these creatures to live here are no less than amazing, and, in fact, even allow them to thrive. Instead, think of the land not as burdened by its lack (or in some months, abundance) of water, but rather as blessed. It is this cycle of wet and dry, so unfamiliar to those from wetter climates, that allows us our spectacular display of bluebonnets, yucca blos-soms, and other spectacular wildflowers. Our water, although paltry to some, is enough—for a desert. Any more, and this place would be something very differ-ent.
The one location where you can count on seeing water in Big Bend is along the Rio Grande—an oasis that’s been called the “lifeblood” of Big Bend. To drift through the majestic canyons of the Rio Grande with your oars touching two countries at the same time is to span time and space. Although the river, as the bound-ary between the United States and Mexico, looks like a solid line on the maps of the area, it is always chang-ing, always going somewhere, and it takes us along on its current opening our eyes to a panorama of tower-ing cliffs, brilliant bird life, and grassy vegas or beach-es. As you drift with the current, you may see both the expected and the unexpected—the black phoebe flit-ting to and fro, a turtle - a Big Bend slider, perhaps—perched on a rock slipping with a quiet “plop” into the water, swallows darting into their mud-nest “apart-ments”, or a peregrine falcon stooping to its prey. And then, at night, the display of stars, connecting you to other parts of the world as well as to other worlds.
A visit to Big Bend provides opportunities for us to escape to isolation seldom found in daily life—a chance to experience unfamiliar creatures and plants, an endless expanse of stark desert and mountain scen-ery, and the vast space, heat, and silence that is the es-sence of the desert. Big Bend has been described as harsh, isolated, lonely, parched, and desolate, but for some people, in all of these adjectives—in the remote-ness and isolation—lies the fascination of the Chihua-huan desert. From the earliest days of human occupa-tion, people have recognized the value of this rugged land that the Spanish called “El Despoblado,” and as a result, the people and the land have had a long part-nership here.
Big Bend National ParkBy National Park Service
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The state of Texas has three major Mesozoic fos-sil locations. The oldest remains, from the late Triassic 200 million years ago, are found in the Texas Panhan-dle, while the state’s center contains rocks dating to the Middle Cretaceous, 100 million years ago. However, the most extensive and spectacular Texan Mesozoic fossil deposits come from Big Bend National Park, from Cretaceous formations in that span a time pe-riod of 35 million years.
Big Bend’s Mesozoic fossils come from three rock formations. The oldest of these, the Boquillas Forma-tion, is a shallow marine limestone approximately 100-95 million years old that formed when Big Bend was flooded by the Western Interior Seaway. One of the many fossils it has yielded is a 30 foot long sea-dwell-ing reptile called Mosasaurus, closely related to mod-ern day varanid lizards such as the Komodo Dragon.
As the Western Interior Seaway retreated, the en-vironment at Big Bend changed drastically. A warm and shallow marine environment gave way to humid coastal forests and swamps. This change is reflected in the region’s stratigraphy - the Boquillas limestone transitions upward to the mudstones and sandstones of the Agujas Formation, which was deposited 80-75 million years ago. A relatively thin layer of marine shale, the Pen Formation, separates the two. Over 70 species have been discovered so far in this formation, including dinosaur remains. The most common Aguja dinosaur is the horned dinosaur Chasmosaurus mar-iscalensis, which was recovered in a bone bed of 10-15 individuals. Other dinosaur genera known from the Agujas Formation include Saurornitholestes and
Richardoestesia (maniraptoran dinosaurs similar to Velociraptor), Stegoceras (a dome-headed dinosaur), Edmontonia (an armored dinosaur), and Agujacera-tops (another horned dinosaur).
One of the most significant of the Agujas genera is not a dinosaur, but a giant crocodile known as Deinosu-chus riograndensis. Known mainly from two-meter long skulls, it is estimated to have reached an adult size near-ing 50 feet long and 5.5 metric tonnes in weight. Scars on Aguja dinosaur bones indicate that Deinosuchus preyed on them, likely using ambush tactics in a manner similar to Nile crocodiles hunting zebras and wildebeest.
Big Bend continued to dry in the Late Cretaceous. By 75-60 million years ago, the Western Interior Sea was completely gone from North America, and a semiarid floodplain environment had replaced the forests and swamps that had occupied Big Bend. This environment is preserved in the mudstones of the Ja-velina Formation. While its fossil yield does not match that of the Aguja Formation, the Javelina Formation has afforded over 20 species of dinosaur that lived in the time directly preceding the catastrophic im-pact that caused their extinction. Many of the species found in this formation, such as two species of horned dinosaur Torosaurus (T. latus and T. utahensis) and the famous Tyrannosaurus rex, represent the largest mem-bers of their clade to ever evolve.
Alamosaurus sanjuanensis, a long-necked sauro-pod dinosaur, is of particular significance to Big Bend and the Javelina Formation. While the first remains of the species were unearthed in New Mexico, they be-longed to an individual of relatively small size for a sauropod - approximately 15 meters long. In 1999, a graduate student at the University of Texas at Dallas stumbled across some protruding bones while explor-ing Big Bend. Excavation revealed a partial pelvis and ten articulated neck vertebrae, which were so massive that they had to be airlifted from the dig site by heli-copter. The Big Bend Alamosaurus has been estimated at 30 meters long, twice the size of the original New Mexico specimen.
Not all of the giant fossils from the Javelina
PaleontologyBy James Napoli
WiKiMeDia coMMonS
Skull of Deinosuchus riograndensis, as exhibited at the American Museum of Natural History for 50 years. In life, the animal was 45 feet long and weighed approximately 4 metric tonnes.
Skeletal diagram of Tyrannosaurus rex. The famous theropod is known from many fossil sites throughout North America, including Big Bend.
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Formation belong to dinosaurs, however. In 1971, a graduate student and his professor from the University of Texas at Austin discovered long, hollow arm bones exposed in a dry creek bed. After examining them, they concluded that they were the wings of an enormous fly-ing pterosaur (a group of archosaurs closely related to - but distinct from - dinosaurs). They named it Quetzal-coatlus nothropi, after the Aztec snake god Quetzalcoatl. Although no body was found, later searches found a series of complete, though much smaller, members of the same species. The initial arm bones belong to an in-dividual estimated to have a nearly 40 foot wingspan, making the Big Bend pterosaur the largest flying animal known in the fossil record.
Big Bend National Park has yielded an exception-al quantity and variety of fossil Mesozoic vertebrates, from marine reptiles to birdlike dinosaurs to immense soaring pterosaurs. The Aguja and Javelina Formations in particular have proved extremely valuable, giving an important insight into the composition of late Creta-ceous terrestrial ecosystems, and both have been stud-ied extensively. Few other locations have the ability to offer such a complete snapshot of life in the Mesozoic world.
References:“Dinosaurs, Pterosaurs, and Crocodiles.” National
Park Service. http://www.nps.gov/bibe/parknews/up-load/Dinosaur_SB.pdf
“A Paleontological Paradise.” National Park Service. http://www.nps.gov/bibe/naturescience/dino.htm
“What do fossils tell us about the history of Big Bend National Park?” University of Texas at Dallas. https://www.utdallas.edu/scimathed/resources/torch/bb00_geo-bd.htm
Sankey, Julia T. “Late Campanian Souther Di-nosaurs, Aguja Formation, Big Bend, Texas” Jour-nal of Paleontology. http://www.bioone.org/doi/abs/10.1666/0022-3360%282001%29075%3C0208%3ALCSDAF%3E2.0.CO%3B2
“Texas Cretaceous Dinosaurs: Big Bend Country Area.” Texas-Geology.com. http://www.texas-geol-ogy.com/Texas%20Cretaceous%20Dinosaurs%20Big%20Bend%20Country%20Area.html
Skeletal diagram of titanosaur sauropod Alamosaurus sanjuanensis. An individual, discovered in Big Bend in 1999, measured 100 feet long and weighed nearly 50 tonnes.
Ut DallaS
Stratigraphic column of Big Bend, showing extensive unconformity from the Paleozoic to the Lower Cretaceous.
hoPKinS MeDicine
Quetzalcoatlus nothropi, the Big Bend pterosaur, with a giraffe and a human for scale. Quetzalcoatlus is the largest known flying organism in the history of the Earth.
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Sunday, March 23
Morning: Emory Peak TrailThis mountain trail goes past spectacular vistas and leads
to the highest peak in the park. The last 25 feet requires a scramble up an exposed rock face.
“A hike to the summit carries you through layers of Cretaceous formations embedded with an assortment of snail, clam, and oyster shell fossils; higher up only lava and extrusive rocks appear. Once upon the summit proper, you are standing on a cap of lava that cooled so quickly it appears glassy. Here, jointing occurred, breaking the rock into large vertical blocks. Once of these is the informally named ‘water tower,’ a remnant of rock that remained after erosion weathered the adjacent rock away.” — E. Dan Klepper (“100 Classic Hikes in Texas”)
Evening: Window View TrailAfter eating dinner, we will head to the 0.3-mile Window
View Trail, which offers great views of The Window.Sunset is at 8:05pm.
Rio Grande Village 1850ft 564m
Area Phone Numbers
Chisos Basin 5401ft 1646m
16 The Big Bend Paisano
national ParK Service
After hiking the Pinnacles Trail for 3.5 miles, the Emory Peak Trail proper splits off as a 1-mile spur.
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Wild and Scen
ic River
Rio
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ild a
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ceni
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M A D E R A S
D E L C A R M E N
P R O T E C T E D A R E A
S A N T A E L E N A C A N Y O N P R O T E C T E D A R E A
UN
ITED STATES
MEXICO
UNITED STATES
MEXICO
MEX
ICO
UN
ITED
STA
TES
Mule EarsSpring
GrapevineSpring
Creek
Wash
Javelina
Creek
Blue
Rough Run
Ala
mo
Terl
ing
ua
Tornillo Creek
Rio
Gra
nde
Rio
Grande
Tight Squeeze
RockSlide
23mi37km
5mi8km3mi
5km
26mi42km
3mi5km
6mi10km
Road to the Basin not recommendedfor trailers longer than 20 feet andRVs over 24 feet because of sharp
curves and steep grades.
10mi16km
22mi35km
8mi13km
13mi20km17mi
27km
18mi29km
20mi32km
4mi6km
0.5mi0.8km
Panther Junction
Castolon/Santa Elena
Junction
MaverickJunction
Chisos MountainsBasin Junction
Entrance
Entrance
Ross
Max
wel
l Sc
enic
Dri
ve
(Store open all year)
(Store open all year)
Do not use this map for backcountryhiking or trip planning. For safe travelget detailed maps at visitor centers.
B I G B E N D N AT I O N A L PA R K
Gle
nn
Sp
rin
g R
oad
Old M
averic
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ad
Grapevin
e H
ills
Roa
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Black Gap
Roa
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Old O
re Road
Old O
re Ro
ad
(not main
tain
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County Road
Dagger Flat Auto Trai
l
To Alpine58mi 94km
To Marathon39mi 63km
To Presidio50mi 80km
B L A C K G A P
W I L D L I F E M A N A G E M E N T A R E A
R O S I L L O S
R A N C H(private land)
N O RT H
R O S I L L O S(Harte Ranch)
CH I SOS
MO U N TA I N S
CE
RR
O D
EL V
EIN
TE
SI E
RR
A D
E SA
N V
ICE
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S I ERRA DEL CARMEN
S IER
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DEL C
AR
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MARISCAL
CA
NY
ON
SAN TA ELENA CAN Y O N
MESA DE ANGUILA
BLACK MESA SIER
RA
DE
L CA
BA
LL
O M
UE
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T O R N I L LO F LAT
DOG CANYON
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T BA
S IN
TELEPHONE CA N YON
DAGGER
FLAT
MA
RISC
AL M
OU
NTA
IN
S IER
RA
LAR
GA
ROSILLOS MOUNTAINS
SANT IAGO MO
UNTA INS
GRA
PEVINE HILLS
BURRO MESAJUNIPER CAN
YON
PINE CANYON
GREEN
GU
LCH
CHRISTMAS MOUNTAINS
BOQUILLAS CANYO
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SOUTH RIM
T U F FC A N Y O N
CHIH
UAHU
A CO
AHUI
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Hen Egg Mountain4963ft1513m
PacksaddleMountain
Aqua Fria Mountain
Camels Hump
Graytop5502ft1677m
5319ft1621m
CORAZONES PEAKS
Rosillos Peak5373ft1638m
Dagger Mountain
Stairway Mountain
Slickrock MountainCroton Peak
Dogie Mountain
The Window4600ft1500m
Emory Peak7825ft2384m
Mule Ears Peaks3881ft 1193m
GoatMountain
Maverick Mountain
Tule Mountain
Peña Mountain
Cerro Castellan 3293ft1004m
Triangulation Station Mountain3143ft953m
Elephant Tusk5249ft1600m
Roys Peak3945ft1202m
Dominguez Mountain5156ft1572m Talley Mountain
3765ft1148m
Chilicotal Mountain4108ft1252m
3932ft1199m
Casa Grande7325ft2233m
TollMtn
Lost Mine Peak7550ft2301m
Panther Peak
Pummel Peak6620ft2018m
NugentMountain
2169ft661m
1850ft564m
5401ft1646m
3750ft1143m
PAINT GAPHILLS
Chimneys WestLuna's Jacal
Terlingua Abajo
Ocotillo Grove
BuenosAires
Black Dike
GaugingStation
JohnsonRanch
LoopCamp
JewelsCamp
Woodsons
DominguezTrailhead
Talley
Solis
Fresno
ElephantTusk
La Clocha
Gravel Pit
Candelilla
La NoriaErnstTinaja
CampdeLeon
Ernst Basin
Willow Tank
TelephoneCanyon
McKinney Spring
Roys PeakVista
Hannold Draw
K-Bar
GovernmentSpring
Paint Gap
Croton Spring
PineCanyon
Rice Tank
RobbersRoost
TwistedShoe
Nine Point Draw
Fossil BoneExhibit
GlennSpring
Sam NailRanch
Dugout Wells
HotSprings
Santa Elena Canyon Overlook
Santa Elena CanyonRiver Access
(raft/canoe take-out)
Burro MesaPouroff
HomerWilsonRanch
Sotol VistaOverlook
Mule Ears Viewpoint
Heath Canyon
AdamsRanch
Stillwell Store and RV Park
Barton WarnockEnvironmental Education Center(Big Bend Ranch State Park)
Terlingua Ranch
DanielsRanch
Chisos Basin
Chisos Mountains Lodge
Park Headquarters
Cottonwood
Rio GrandeVillage
Rio GrandeOverlook
Boquillas CanyonOverlook
MariscalMine
STUDY BUTTE/TERLINGUA
TERLINGUA GHOST TOWN(Historic District)
LAJITAS
SANTAELENA
LA LINDA
BOQUILLAS DEL CARMEN
SAN VICENTE
0.5mi0.8km
Distance indicator(other roads)
Distance indicator(main roads)
Primitive road(four-wheel drive,high-clearancevehicles only)Trail
Unpaved road
Please observe land owner’srights.
Private land withinpark boundary
Rapids
Ruins
Picnic area
Gas station
Campground
Primitive campsite
Lodging and food
Restaurant
Store
Self-guiding trail
Ranger station
18mi29km
23mi37km
1.9mi3.1km
5.1mi8.2km
26mi43km
1.9mi3.1km
2.3mi3.7km
9mi14km
4.1mi6.6km
4.5mi7.2km
5.3mi8.5km
4.5mi7.2km
1.4mi2.3km
6.8mi10.9km
8.5mi13.7km
6.0mi9.7km
9.6mi15.5km
1.5mi2.4km
6.8mi10.9km
2.2mi3.5km
27.5mi44.3km
7.7mi12.4km
12.8mi20.6km
2.5mi4.0km
Tunnel
S IERRA DEL C
AB
ALLO
MU
ER
TO
THE
SOLITARIO
River Road W
est
Rive
r R
oad East
Chimneys
Trail Mountain Loop)
(Outer Dodson
Pine Canyon Trail
Telephone Cany
on
Trai
l
Do
min
gu
ez Spring
Trail
Boqu i l l a sCanyonTra i l
Santa ElenaCanyon Trail
Lost MineTrail
Trail
Strawhouse Trail Juniper Canyon Trail
Visitor Center
Visitor Center(closed in summer)
Castolon Visitor Center(closed in summer)
Persimmon Gap Visitor Center
Visitor Center
Big BendNational Park
T E X A S
0 5
0 5 10 Miles
10 KilometersNorth
30
Big
Ben
d
Wildlife of Big BendBy Jonah Berkowitz
There are 4 chief communities of vegetation (bi-omes) in Big Bend:
1. Chihuahuan Desert scrub: Occupies the largest proportion of the park, and is characterized by creo-sotebush as well as yucca, agave, and candelilla (used for wax production in the early 1900s). The desert bursts into spectacular bloom twice a year, with the
annual monsoon season in late summer and again dur-ing the spring after minimal winter precipitation. The spring will feature the cactus, yucca, and ocotillo blooms. Cactuses represent an espe-cially good adaptation to the desert’s harsh living condi-tions, growing with no leaves and sharp protective spines. Big Bend hosts the greatest diversity of cactuses of any National Park; look for ev-erything from pricklypear to pineapple and strawberry cacti. Despite their extreme-ly spiny bases, agaves are not cactuses because they have leaves. Some agaves are known as century plants be-cause it takes them 100 years to reach maturity and flower. When agaves reach maturity, they die and the next gen-eration sprouts from around the dead one, so look out for agaves in circular groups! The lechuguilla agave is unique to the Chihuahuan Desert, and was heavily used by Native Americans, espe-cially for making soap.
2. Desert Grassland: Oc-cupies mid-level elevations (3000ft-5000ft); low areas of the high mountains or the high areas of low mountains Chinograss and stotol are the
2 dominant species, although overgrazing has heavily altered grass diversity; invasive species like Bermuda are now common. Chinograss used to cover the hills of Big Bend country but became the primary food source for settlers, tradesmen and their livestock. It is
still common, but not in its previous grandeur.3. Pinyon-juniper-oak woodland: Occupies most
of the Chizos mountain slopes, interspersing with grasslands at around 3500 ft. and becoming denser at greater heights.
4. Ponderosa pine-Douglas fir-Arizona cypress forest: Occupies the upper reaches of the Chizos mountains. This biome is not particularly common in Big Bend and is only found near peaks where ideal soil content and moisture exist. It is greatly endan-gered by current global warming and drought. Pon-derosas have a wonderful vanilla, cinnamon smell so you’ll know if they are nearby.
AnimalsBecause of its various biomes, Big Bend is host
to a fantastic diversity of animal life. For example, at least 450 bird species inhabit—or migrate through—the park, more than in any other National Park. Black and turkey vultures are common, often mistaken for golden eagles and several other large hawks which are also present. Peregrine falcons thrive in the high cliffs of the Chisos Mountains and Rio Grande. Rep-tiles are common in Big Bend, and include 31 snake species and 22 lizard species. Rattlesnakes, bull-snakes and patchnose snakes are common. Lizards play an important role in keeping insect populations under control, while they themselves are an impor-tant food source for birds. The greater roadrunner, a type of cuckoo that feeds on lizards, can often be seen racing down roads in front of cars before jump-ing off into the brush. Collard and leopard lizards
Sotol resembles the agaves but has flattened, barbed leaves at its base.
The ocotillo in bloom.
A stand of giant dagger yuccas, unique to the Big Bend area; they can reach a height of 25 feet. Yuccas are closely related to lilies and are ubiquitous in the southwest. Native Americans utilized the entire plant, from the roots to the fruit, for everything from basket making fibers to tequila production.
31
Big
Bend
can measure over a foot in length, and are known to feed on small snakes! The yucca night lizard inhabits dead, moist yucca plants for shelter.
Mammal species found in Big Bend include 20 species of bats, including the Mexican Long-nosed Bat, an endangered species key to cactus pollination. This species is only present in the United States at Big Bend, where there is a colony in the Chisos Moun-tains. Black bears, mountain lions, javelinas, and coy-otes are also present. Black bears became extinct in the park but returned in the 1980s and exist in small numbers in the Chisos. Javelinas are found through-out South and Central America, but are common in Big Bend country. They resemble wild pigs but are actually very different, possessing 3 toes instead of 4, a short tail, and a complex stomach system. They are herbivores, relying on pricklypear pads during the dry seasons, and herds of 10-20 are often seen around campsites in Big Bend. They are known to be quite adept at intruding campers’ food supplies. In the early 1900s, their hides were shipped to New
England and Europe for gloves and hairbrushes. Mountain lion sightings are rare at Big Bend, and 90% occur along park roads. Animals such as prong-horn, prairie dogs, wild turkey, Mexican gray wolf, and bighorn sheep were more common before the ranching and settlement in the Big Bend country.
References:Evans, Douglas B. Cactuses of Big Bend Nation-
al Park. Austin, TX: University of Texas, 1998. Print. McDougall, W. B., and Omer Edison. Sperry.
Plants of Big Bend National Park: With Illustrations and Keys for Identification. Washington: U.S. Dept. of the Interior, National Park Service, 1951. Print.
Sutton, Ann, Myron Sutton, and Ansel Adams. The American West; a Natural History. New York: Random House, 1969. Print.
United States. National Park Service. “Big Bend National Park (U.S. National Park Service).” National Parks Service. U.S. Department of the Interior, n.d. Web. Mar. 2014
Creosote bush. This shrub is characteristic to the desert floor; it grows very slowly, and can take a decade to reach a height of a couple feet. In addition, its circle of roots excretes a substance that is poisonous to other plants, so that it can protect all the available water for itself.
Greater Earless Lizard. Males are generally larger with more vivid colorations.
The non-poisonous Red Racer is the most commonly seen snake in Big Bend. You might see it stretched across an entire road lane.
40
Big
Ben
d
Tuesday, March 25
2627
170
118
385
118
Rio
Gra
nde
Wild and Scen
ic River
Rio
Gra
nd
e W
ild a
nd S
ceni
c R
iver
M A D E R A S
D E L C A R M E N
P R O T E C T E D A R E A
S A N T A E L E N A C A N Y O N P R O T E C T E D A R E A
UN
ITED STATES
MEXICO
UNITED STATES
MEXICO
MEX
ICO
UN
ITED
STA
TES
Mule EarsSpring
GrapevineSpring
Creek
Wash
Javelina
Creek
Blue
Rough Run
Ala
mo
Terl
ing
ua
Tornillo Creek
Rio
Gra
nde
Rio
Grande
Tight Squeeze
RockSlide
23mi37km
5mi8km3mi
5km
26mi42km
3mi5km
6mi10km
Road to the Basin not recommendedfor trailers longer than 20 feet andRVs over 24 feet because of sharp
curves and steep grades.
10mi16km
22mi35km
8mi13km
13mi20km17mi
27km
18mi29km
20mi32km
4mi6km
0.5mi0.8km
Panther Junction
Castolon/Santa Elena
Junction
MaverickJunction
Chisos MountainsBasin Junction
Entrance
Entrance
Ross
Max
wel
l Sc
enic
Dri
ve
(Store open all year)
(Store open all year)
Do not use this map for backcountryhiking or trip planning. For safe travelget detailed maps at visitor centers.
B I G B E N D N AT I O N A L PA R K
Gle
nn
Sp
rin
g R
oad
Old M
averic
k Ro
ad
Grapevin
e H
ills
Roa
d
Black Gap
Roa
d
Old O
re Road
Old O
re Ro
ad
(not main
tain
ed)
County Road
Dagger Flat Auto Trai
l
To Alpine58mi 94km
To Marathon39mi 63km
To Presidio50mi 80km
B L A C K G A P
W I L D L I F E M A N A G E M E N T A R E A
R O S I L L O S
R A N C H(private land)
N O RT H
R O S I L L O S(Harte Ranch)
CH I SOS
MO U N TA I N S
CE
RR
O D
EL V
EIN
TE
SI E
RR
A D
E SA
N V
ICE
NT
E
S I ERRA DEL CARMEN
S IER
RA
DEL C
AR
MEN
MARISCAL
CA
NY
ON
SAN TA ELENA CAN Y O N
MESA DE ANGUILA
BLACK MESA SIER
RA
DE
L CA
BA
LL
O M
UE
RT
O
T O R N I L LO F LAT
DOG CANYON E
RN
ST B
AS IN
TELEPHONE CA N YON
DAGGER
FLAT
MA
RISC
AL M
OU
NTA
IN
S IER
RA
LAR
GA
ROSILLOS MOUNTAINS
SANT IAGO MO
UNTA INS
GRA
PEVINE HILLS
BURRO MESAJUNIPER CAN
YON
PINE CANYON
GREEN
GU
LCH
CHRISTMAS MOUNTAINS
BOQUILLAS CANYO
N
SOUTH RIM
T U F FC A N Y O N
CHIH
UAHU
A CO
AHUI
LA
Hen Egg Mountain4963ft1513m
PacksaddleMountain
Aqua Fria Mountain
Camels Hump
Graytop5502ft1677m
5319ft1621m
CORAZONES PEAKS
Rosillos Peak5373ft1638m
Dagger Mountain
Stairway Mountain
Slickrock MountainCroton Peak
Dogie Mountain
The Window4600ft1500m
Emory Peak7825ft2384m
Mule Ears Peaks3881ft 1193m
GoatMountain
Maverick Mountain
Tule Mountain
Peña Mountain
Cerro Castellan 3293ft1004m
Triangulation Station Mountain3143ft953m
Elephant Tusk5249ft1600m
Roys Peak3945ft1202m
Dominguez Mountain5156ft1572m Talley Mountain
3765ft1148m
Chilicotal Mountain4108ft1252m
3932ft1199m
Casa Grande7325ft2233m
TollMtn
Lost Mine Peak7550ft2301m
Panther Peak
Pummel Peak6620ft2018m
NugentMountain
2169ft661m
1850ft564m
5401ft1646m
3750ft1143m
PAINT GAPHILLS
Chimneys WestLuna's Jacal
Terlingua Abajo
Ocotillo Grove
BuenosAires
Black Dike
GaugingStation
JohnsonRanch
LoopCamp
JewelsCamp
Woodsons
DominguezTrailhead
Talley
Solis
Fresno
ElephantTusk
La Clocha
Gravel Pit
Candelilla
La NoriaErnstTinaja
CampdeLeon
Ernst Basin
Willow Tank
TelephoneCanyon
McKinney Spring
Roys PeakVista
Hannold Draw
K-Bar
GovernmentSpring
Paint Gap
Croton Spring
PineCanyon
Rice Tank
RobbersRoost
TwistedShoe
Nine Point Draw
Fossil BoneExhibit
GlennSpring
Sam NailRanch
Dugout Wells
HotSprings
Santa Elena Canyon Overlook
Santa Elena CanyonRiver Access
(raft/canoe take-out)
Burro MesaPouroff
HomerWilsonRanch
Sotol VistaOverlook
Mule Ears Viewpoint
Heath Canyon
AdamsRanch
Stillwell Store and RV Park
Barton WarnockEnvironmental Education Center(Big Bend Ranch State Park)
Terlingua Ranch
DanielsRanch
Chisos Basin
Chisos Mountains Lodge
Park Headquarters
Cottonwood
Rio GrandeVillage
Rio GrandeOverlook
Boquillas CanyonOverlook
MariscalMine
STUDY BUTTE/TERLINGUA
TERLINGUA GHOST TOWN(Historic District)
LAJITAS
SANTAELENA
LA LINDA
BOQUILLAS DEL CARMEN
SAN VICENTE
0.5mi0.8km
Distance indicator(other roads)
Distance indicator(main roads)
Primitive road(four-wheel drive,high-clearancevehicles only)Trail
Unpaved road
Please observe land owner’srights.
Private land withinpark boundary
Rapids
Ruins
Picnic area
Gas station
Campground
Primitive campsite
Lodging and food
Restaurant
Store
Self-guiding trail
Ranger station
18mi29km
23mi37km
1.9mi3.1km
5.1mi8.2km
26mi43km
1.9mi3.1km
2.3mi3.7km
9mi14km
4.1mi6.6km
4.5mi7.2km
5.3mi8.5km
4.5mi7.2km
1.4mi2.3km
6.8mi10.9km
8.5mi13.7km
6.0mi9.7km
9.6mi15.5km
1.5mi2.4km
6.8mi10.9km
2.2mi3.5km
27.5mi44.3km
7.7mi12.4km
12.8mi20.6km
2.5mi4.0km
Tunnel
S IERRA DEL C
AB
ALLO
MU
ER
TO
THE
SOLITARIO
River Road W
est
Rive
r R
oad East
Chimneys
Trail Mountain Loop)
(Outer Dodson
Pine Canyon Trail
Telephone Cany
on
Trai
l
Do
min
gu
ez Spring
Trail
Boqu i l l a sCany onTra i l
Santa ElenaCanyon Trail
Lost MineTrail
Trail
Strawhouse Trail Juniper Canyon Trail
Visitor Center
Visitor Center(closed in summer)
Castolon Visitor Center(closed in summer)
Persimmon Gap Visitor Center
Visitor Center
Big BendNational Park
T E X A S
0 5
0 5 10 Miles
10 KilometersNorth
Morning: Lost Mine TrailEarly Spanish explorers of the Southwest discovered and developed many mines. That
we know of, no mine exists here today, but legend tells of a rich mineral deposit, kept so secret that those who worked the mines were prisoners, blindfolded on their way in and out each day. The trail is moderately strenuous and has beautiful views.
Afternoon: Terlingua Ghost Town and Barton Warnock Environmental Education Center
At Terlingua, we will walk around and explore the old ghost town. The Environmental Education Center has self-guided tours and a two-acre desert garden.
Afternoon: Grapevine Hills Trail
This trail leads to a group of balanced rocks in the heart of the Grapevine Hills. Initially, the trail follows a gravel wash, then climbs steeply for the last quarter mile into the boulders. Grapevine Hills is an exposed laccolith, with many giant, rounded boulders that are tempting to climb, but watch for snakes.
42
Big
Ben
d
Wednesday, March 26
Morning: Travel to Big Bend Ranch State Park
After packing up camp we will drive 2 hours to Big Bend Ranch State Park.
Morning: Closed Canyon Trail and Hoodoos Trail (B, C)
The 0.7 mile (one-way) Closed Canyon trail leads to a narrow and deep slot canyon that cuts through the Colorado Mesa and the Rio Grande River. The canyon has been carved through welded tuff, a volcanic eruption of ash, liquid and gas. A small arroyo leads directly into the canyon. The Hoodoos Trail is an easy one mile loop that will take approximately one hour to complete. “Hoodoos” is defined as a uniquely shaped rock that has been formed over time by weathering.
Afternoon: Travel to Marfa, TX (D)We will drive 2 hours to Marfa and do our second round
of grocery shopping.
Afternoon: Travel to Guadalupe Mountains National Park (E)
We will leave Texas and drive 2 hours 15 minutes to Guadalupe Mountains National Park. We will set up camp at Pine Springs Campground.
Guadalupe Mountains
the Guadalupe Mountains are the exposed remains of an ancient barrier reef that lined the perimeter of the Permian basin in modern-day eastern new Mexico and western texas. here we will hike the Permian reef Geology trail and check out carlsbad caverns, a limestone cave network with some of the largest and deepest caves in the world.
Thursday, March 27
46
Gua
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upe
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ins
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Gua
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Thursday, March 27
14371576
62180
62180
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285
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NEW MEXICOTEXAS
LINCOLN
NATIONAL
FOREST
GUADALUPEMOUNTAINS
NATIONAL PARK
CARLSBADCAVERNSNATIONAL
PARK
HeadquartersVisitor Center
Dog Canyon McKittrick Canyon
14mi23km
16mi26km
20mi32km
23mi37km
12mi19km
9mi14km
11mi18km
16mi26km
19mi31km
9mi14km
7mi11km
14mi23km
21mi34km
13mi21km
White’s City
Queen
Pine Springs
VisitorCenter
DellCity
Carlsbad
Malaga
Pine Springs to El Paso110mi (177km)
Pine Springs to Van Horn65mi105km
Carlsbad to Artesia36mi
58km
Malaga to Pecos69mi
111km
ToOrla and Pecos
0 20 Kilometers10
20 Miles100
national ParK Service
We will begin by driving from Pine Springs Campground to Carlsbad Caverns. After cave tours and lunch, we will head to McKittrick Canyon for two hikes, followed by a return to camp.
Morning: Carlsbad CavernsWe will go on both self-guided and ranger-led tours
of the caves at Carlsbad Caverns National Park.“The basic tour through Carlsbad Cavern is the Big
Room route, a one-mile, self-guided underground walk around the perimeter of the largest room in the cave, the Big Room. An audio guide notably enhances the tour. Taking approximately 1½ hours, this circular route passes many large and famous features including Bottomless Pit, Giant Dome, Rock of Ages, and Painted Grotto. Highly decorated and immense, the Big Room should be seen by all park visitors.” — National Park Service
There are two ranger-led tours available: Kings Palace and Left Hand Tunnel. The Kings Palace tour is a 1.5-hour tour that goes to the deepest part of the cave accessible to the public; it is the most popular tour at Carlsbad Caverns. For the more adventerous, the moderately strenuous Left Hand Tunnel tour lasts 2 hours and “is a historic candle-lit lantern tour through an undeveloped section of the cave on unpaved trails.”
Following the self-guided and ranger-led tours, we will eat lunch.
Afternoon: McKittrick Canyon Nature Trail“An intermittent seep lies hidden within junipers, shrubs, and grasses that cling to this tiny ecosystem. Trailside exhibits
describe common plants, reference wildland fire, and explain Permian Reef geology. The trail is 0.9 miles round trip, is rated moderate, but takes less than one hour to complete.” — National Park Service
Afternoon: Permian Reef Geology Trail“For serious geology buffs, this trail has stop markers that can be used with a comprehensive geology guide, available at the
park’s Headquarters Visitor Center. There are excellent views into McKittrick Canyon from the top of Wilderness Ridge.”— National Park Service
Evening: The Pinery Trail“Travel the short 0.75 mile path to the ruins of the old Pinery Station, once a favored stop on the original 2,800 mile Butterfield
Overland Mail Route. Trailside exhibits describe Chihuahuan desert vegetation.” — National Park Service
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The limestone bedrock of the Guadalupe Moun-tains in southeastern New Mexico hosts Carlsbad Caverns, a series of 118 caves which are 317 m deep and have a total length of over 48 km. The Caverns are among the largest and deepest in the world, and have resulted from millions of years of chemical weathering. Unlike the simple dissolution by acidic water that forms most caves, the process that formed Carlsbad Caverns is unique.
The vast Carlsbad Caverns cave network is situated within the 250 million year old Permian Capitan limestone. During this time, the Delaware Basin (which includes modern southeastern New Mexico) was closer to the equator and covered by a large and deep (549 m, 1800 ft.) inland sea. Over millions of years the accumulation and compaction of now extinct calcareous sponges, algae, bryozo-ans, and other marine microorganisms eventually became the thick (229 m, 750 ft) Capitan limestone.
Once the inland sea dried up at the end of the Permian period, the reef was buried under oth-er sediment layers until it was uplifted 20 million years ago when the Guadalupe Mountains started forming. The abundant oil fields below the Capitan limestone further indicate that the Delaware Basin was once a shallow marine environment.
Most caves form when rainwater and carbon dioxide from the atmosphere and soil combine to create carbonic acid. As acidic water moves down through soluble bedrock such as limestone, it en-larges fractures and faults and develops under-ground channels and cavities. However, geologic evidence indicates that Carlsbad Caverns formed in a different manner from the ‘bottom up.’
Radioactive dating reveals that Carlsbad Cav-erns was one of the last caves to be dissolved in the Guadalupe Mountains. The last major uplift associated with the formation of the Guadalupe
Carlsbad CavernsBy Allison Lawman
Peter JoneS / national ParK Service
Speleothems are cave formations that form when surface water flows through cracks in limestone bedrock, drips into a cave opening and eventually evaporates, leaving a small calcite deposit behind.
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Mountains occurred during the late Tertiary period 4-6 million years ago. During this period, sulfuric acid production occurred when hydrogen sulfide (H2S) rich water migrated upward from the under-lying oil-bearing strata and mixed with the oxygen in groundwater according to the following reac-tion:
H2S + 2O2 → H2SO4 → H+ + HSO4-
Very large chambers developed in the Capitan limestone as sulfuric acid dissolved the carbonate along fractures and faults. Gypsum (CaSO4•2H2O) is a byproduct of the sulfuric acid and calcium car-bonate reaction, and thus the extensive deposits of this mineral in Carlsbad Caverns provide strong evidence of this unique cave formation process. Typical caves formed by carbonic acid dissolution are often characterized by the presence of lakes, wa-terfalls, and streams within their interior. However, the lack of flowing streams through Carlsbad Cav-erns further indicates that the sulfuric acid disso-lution was not connected to surface processes. In fact, Carlsbad Caverns remained isolated from the surface until approximately one million years ago when the top of the cave collapsed and created the natural entrance.
In addition to the immense size of the chambers,
the elaborate speleothems (cave decorations) are some of the most impressive features of Carlsbad Caverns. Air and water containing carbonic acid could readily circulate through the chambers fol-lowing the formation of the natural entrance. When this acidic water reaches an open void in the cave it forms a drop and releases its carbon dioxide. The water becomes saturated with dissolved carbonate, so further evaporation causes a tiny amount of cal-cium carbonate to re-precipitate. Over time stalac-tites and stalagmites form on the cave ceiling and floor, and columns develop when these features meet. Other cave decorations include thin soda straws, sheet-like draperies, curved helectites, and bulbous protrusions called popcorn.
Guided and self-guided tours allow visitors to experience the ornate beauty of Carlsbad Caverns. Occupying 8.2 acres, the Big Room is the largest cave chamber in North America. The King’s Pal-ace and the Left Hand Tunnel tours further allow people to witness the elaborate speleothems and gypsum deposits. King’s Palace goes through four highly decorated chambers and down 253 meters (830 ft) into the deepest portion of the cave acces-sible to the public.
References:Burges, Paul. “Carlsbad Caverns National
Park.” The National Park Service, U.S. Department of the Interior. http://permanent.access.gpo.gov/gpo308/CaveICSPostersmall.pdf.
“Carlsbad Caverns National Park.” National Geographic. http://travel.nationalgeographic.com/travel/national-parks/carlsbad-caverns-national-park/.
“Cave Geology: Dissolution and Decoration.” The National Park Service, U.S. Department of the Interior. http://www.nps.gov/cave/planyourvisit/upload/cave_geology.pdf.
“Geologic Formations.” The National Park Ser-vice, U.S. Department of the Interior. http://www.nps.gov/cave/naturescience/geologicformations.htm.
“Kings Palace Tour.” The National Park Service, U.S. Department of the Interior. http://www.nps.gov/cave/planyourvisit/kings_palace.htm.
“Surface Geology: From Living Reef to Desert Mountains.” The National Park Service, U.S. De-partment of the Interior. http://www.nps.gov/cave/planyourvisit/upload/surface_geology.pdf.
Peter JoneS / national ParK Service
Sulfuric acid dissolution formed the elaborate 48 km cave network of Carlsbad Caverns. The large chambers remained isolated from surface processes until approximately 1 million years ago when the natural entrance (above) formed.
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Speleothems as Climate ProxiesBy Klara Zimmerman
Speleothems are cave deposits that form when groundwater drips into underground caverns and precipitates small amounts of calcite, which can even-tually grow into large stalactite or stalagmite depos-its. The drip formations that we will see on our trip to Carlsbad Caverns are not only beautiful, but also geologically interesting. The geochemical signatures, trace elements, and fluid inclusions in calcite cave for-mations can hold clues to past climates.
In order to understand the usefulness of speleo-thems, it is necessary to have a basic understanding of how stable isotope analysis of oxygen is used in pa-leoclimate reconstructions. Ocean water molecules that contain 18O, a heavier isotope of oxygen, tend to stay in the ocean whereas 16O, the lighter and more prevalent isotope, evaporates more readily. Some 18O containing water does evaporate, but once in the at-mosphere, it condenses and precipitates more read-ily than the lighter 16O. Therefore, on its route from evaporation at the ocean near the equators toward the poles, atmospheric water vapor becomes relatively enriched in 16O. Ambient temperature of an envi-ronment can be deciphered from the relative 18O/16O concentration in precipitation because water that condenses at colder temperatures will be relatively depleted of 18O.
Although the 18O/16O relationship, commonly calculated as δ18O, is well-known in ice core paleo-climatology, it has more recently been applied to spe-leothems. There are many advantages of speleothem climate reconstructions compared to other climate proxies. First of all, they have the potential to provide long duration records because stalagmite deposits can date from thousands to millions of years ago. In addi-tion, some speleothems can be accurately dated down to the calendar year or even the month using Urani-um-Thorium decay. In some cases, speleothem lam-ina can even be counted like tree rings. Speleothems preserve relatively pure calcium carbonate (usually as calcite) precipitated from meteoric water and there-fore are representative of surface environments. Fi-nally, the caverns where speleothems are found have been protected from erosion and other potential causes of degradation for long periods of time.
However, like all climate proxies, speleothem sta-ble isotope geochemistry has its weaknesses. Speleo-them growth rates are not constant over the long term; they can vary considerably by season and can stop altogether when conditions are dry. Furthermore, variations in δ18O values may be influenced by factors other than temperature including volume of rainfall, surface evaporation, and kinetic fractionation due to
secondary evaporation in caves. Ideally, if uncertain-ties can be minimized, speleothems could serve as pa-leo-temperature proxies for long time period recon-structions. Due to the ambiguities mentioned, recent speleothem climate research has focused on mini-mizing uncertainty by measuring fluid inclusions that enable confirmation that the calcite was deposited in equilibrium with the source drip water.
New Mexico is one hotspot for speleothem cli-mate research due to the prevalence of caves. Carls-bad Caverns, in particular, were the subject of a 2006 study, which took a core of a giant calcite column that contained a 164,000 year climate record. One advan-tage of Carlsbad Caverns as a study site is that the only water entering the caves percolates directly from the surface to groundwater to the cave, and moves a rela-tively short distance before it precipitates, minimiz-ing errors associated with surface evaporation. Using the core, Brook et al (2006) were able to correlate the inferred temperature record with other Southwestern speleothem records and even far away ice cores that documented climate variations through several glob-al glaciations. They found that global warm intervals were generally drier times for New Mexico, whereas wetter times were associated with global cooling. In sum, cave formations can link local climate to global climate events like glacial-interglacial cycles, and al-though many uncertainties still exist, efforts are be-ing made to both increase precision of data collection and continually monitor present-day cave precipita-tion with local climate conditions to better under-stand the past.
References:Brook, George A., Brooks B. Ellwood, L. Bruce
Railsback, and James B. Cowart. “A 164 Ka Record of Environmental Change in the American Southwest from a Carlsbad Cavern Speleothem.” Palaeogeog-raphy, Palaeoclimatology, Palaeoecology237.2-4 (2006): 483-507.
“Climate Change | Oxygen Isotope Analysis.” Web. 23 Feb. 2014. <http://www.global-climate-change.org.uk/3-3-2-1.php>.
Feng, Weimin, et al (2014). “Oxygen Isotope Varia-tions in Rainfall, Drip-water and Speleothem Calcite from a Well-ventilated Cave in Texas, USA: Assess-ing a New Speleothem Temperature Proxy.” Geochi-mica Et Cosmochimica Acta 127: 233-50.
McDermott, Frank (2004). “Palaeo-climate Re-construction from Stable Isotope Variations in Spe-leothems: A Review.” Quaternary Science Reviews 23.7-8: 901-18.
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Friday, March 28
Morning: Smith Spring Trail (B)Begin this hike at the trailhead sign. Look for birds, mule deer, and elk as you walk this loop trail to the shady oasis of Smith
Spring. Take a break here and enjoy the gurgling sounds of the tiny waterfall before continuing around to sunny Manzanita Spring. Scars from wildland fires of 1990 and 1993 are evident along the trail. The trail is rated moderate, with a round-trip distance of 2.3 miles. Allow one to two hours.
— National Park Service
Midday: Wyler Aerial Tramway (C)The Wyler Aerial Tramway at Franklin Mountains State Park features an aerial cable car situated on 195.742 acres of rugged
mountain and rock formations on the east side of the Franklin Mountains.Driving the paved road that snakes up the east side of the Franklin Mountains from the intersection of McKinley and Alabama
streets is half the fun. The visitor arrives at a parking area that sits at an elevation of 4,692 feet. The view of El Paso, to the east, is magnificent. Here visitors can admire the beauty of cacti gardens or watch the tramway gondolas take off.
Visitors can purchase tickets at the tramway station to ride a gondola that will transport them to the top of Ranger Peak. The Swiss made gondolas travel on a 2,600 feet long, 1 3/8 inch diameter steel cable. While waiting to depart, the visitor can view part of the machinery and mechanism of the system through a window located on the south side of the base station. On the smooth ride to the top, the cabin attendant will describe the different cacti and rock formations along the way. Abundant wildlife, including reptiles, birds and insects, offer exciting viewing opportunities. The 4 minute ride soars above a vast canyon that is 240 feet deep in some places.
From Ranger Peak, 5,632 feet above sea level, the visitor can enjoy the view of 7,000 square miles encompassing three states and two nations. The tramway ride is a memorable experience offering a vista of the vastness and stark beauty of the southwest.
— Texas Parks and Wildlife
Afternoon: White Sands National Monument (D/E)Potential activities include going on short hikes and sledding down the gypsum dunes. Hiking options include the Playa Trail,
Dune Life Nature Trail, the Interdune Boardwalk, and the Backcountry Camping Trail.— National Park Service
Evening: Oliver Lee Memorial State Park (F)Located on the western edge of the Sacramento Mountains, this state park is where we will camp for our last night. There are showers!
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The Sacramento Mountains are located in south-ern New Mexico, directly east of Almogordo in Otero County. The range trends 85 miles north-south. The range forms part of the eastern border of the Tularosa Basin, which in turn is part of the Rio Grande rift valley. The mountains form a large cuesta. The western escarpment has a total relief of more than a mile and irregular topography typical of the Basin and Range Province. The shallow, 1-2 degree dipping eastern slope extends 80 miles from the crest to the Pecos River; this broad expansive terrain resembles the structures typically found in the Great Plains Province.
Stratigraphic history
The strata of the Sacramento Mountains have a composite thickness of 8,000 feet and range from Precambrian metamorphic rock to Cretaceous limestone. The exposed section consists entirely of Paleozoic rocks and has an average thickness of 5,000 feet. The Precambrian strata are slightly meta-morphosed shales, siltstones, and quartzites that are
intruded by igneous sills. These strata only outcrop towards the southern end of the range. An angular disconformity of approximately 10 degrees sepa-rates these strata from the thick, overlying Paleozo-ic sediments. These sediments are primarily marine carbonates deposited while the Permian sea cov-ered the area. However, the Permian sea retreated and advanced periodically, leading to depositions of gypsum, shale and sandstone layers as well.
Formation of the mountains
Towards the end of the late Cretaceous, the Sacramento Mountains region was part of a large anticline composed of Paleozoic sediments. This anticline stretched across today’s Tularosa Basin and San Andres Mountains. The Rio Grande Rift Zone led to the collapse of the anticline. The Tu-larosa block dropped over 5000 feet and the San Andreas and Sacramento Mountains were uplifted along normal fault zones. The Tularosa Basin has no drainage outlet; all of the sediment eroded from the Sacramento and San Andres Mountains is deposited
Sacramento MountainsBy Jeff Baum
WiKiMeDia coMMonS
The steeper, West escarpment of the Sacramento Mountains, dipping towards the Tularosa Basin. We will have a similar view when we stay at Oliver Lee Memorial State Park
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in the basin. During the Pleistocene Ice Age, the re-gion was significantly cooler and wetter; the basin was covered by Lake Otero. The water that drained from the San Andreas and Sacramento Mountains was rich in gypsum and other salts, so gypsum ac-cumulated in the basin. The lake eventually dried up, leaving behind the massive gypsum deposits known as the White Sands National Monument.
Hydrology
The Sacramento Mountains receives most of the precipitation in Southern New Mexico. This precip-itation seeps through fracture networks into shal-low carbonate aquifers that supply water to several indigenous highlands communities as well as much of the industrial agriculture in the region.
However, there has been a marked decrease in groundwater levels and spring discharges over the past few decades attributed to both a change in cli-mate and land use. Most of the groundwater in the Tularosa Basin originates as high-altitude snow-melt, but summer precipitation can contribute sig-nificantly to groundwater levels. Climate projec-tions project both less future snowfall and more intense summer rainstorms. Thus, summer storms will become a progressively more important source of groundwater in the region.
As natural recharge rates continue to drop, arti-ficial recharge techniques may be required for hu-man withdrawal in the future. One technique be-ing discussed in New Mexico is tree thinning. Tree thinning reduces the local canopy cover, increasing the amount of water that reaches the surface. Fur-thermore, the removal of some vegetation prevents excess water loss due to evapotranspiration. An on-going study is analyzing whether tree thinning will
actually increase groundwater levels in the Sacra-mento Mountains region.
References:Newton, Tallon. New Mexico Bureau of Geology
and Mineral Resources. “The Sacramento Moun-tains Hydrogeology Study: How Geology and Cli-mate Affect our Water Resources” http://geoinfo.nmt.edu/publications/periodicals/earthmatters/11/emv11n1.pdf
Bowsher, Arthur L. Some Effects of Precam-brian Basement on the Development of the Sacra-mento Mountains. New Mexico Geological Society. https://nmgs.nmt.edu/publications/guidebooks/downloads/42/42_p0081_p0089.pdf
Otte Jr., Carel. Late Pennsylvanian and Early Permian Stratigraphy of the Northern Sacramen-to Mountains, Otero County, New Mexico. State Bureau of Mines and Mineral Resources. https://nmgs.nmt.edu/publications/guidebooks/down-loads/42/42_p0081_p0089.pdf
Pray, Lloyd C. Outline of the Stratigraphy and Structure of the Sacramento Mountain Escarpment. Division of Geological Science, California Institute of Technology. http://nmgs.nmt.edu/publications/guidebooks/downloads/5/5_p0092_p0107.pdf
Pray, Llloyd C. Geology of the Sacramento Mountains Escarpment, Otero County, New Mex-ico. 1961. State Bureau of Mines and Mineral Resources. New Mexico Institute of Mining and Technology. http://geoinfo.nmt.edu/publications/monographs/bulletins/downloads/35/Bulletin35.pdf
Roadside Geology of New Mexico, Halka Chron-ic, Roadside Geology Series. Mountain Press Pub-lishing Company. Missoula 1987.
new mexico earth matters 3 winter 2011
this water is removed from the system by evaporation in mountain streams and by vegetation that extracts water from the shallow perched aquifers. Ground water in the high mountains is also stored in soils, alluvium, fractures, and pores that are not directly connected to these regional fracture systems. These different areas where water is stored have a direct effect on where vegetation can extract water, and therefore on how tree thinning and other land management practices might affect the local hydrology. For instance, trees growing above a shallow perched aquifer may derive their water directly from that aquifer, whereas trees growing above a deep aquifer derive their moisture primar-ily from unsaturated soils and fractured bedrock.
In areas to the south and east, where the Yeso Formation is not exposed at the surface, most ground water comes from the aquifer system in the high mountains, and very little surface recharge occurs. Estimates are that as much as 22 percent of high-altitude precipitation goes to recharge adjacent regional aquifers to the east and south, the directions of regional dip. Age-dating data indicate that it may take as long as 1,300 years for ground water to flow from Mayhill to the eastern portion of the Pecos Slope, toward Hope, Artesia, and Roswell. Ground water flow-ing to the east ultimately makes its way to the ground water system in the Roswell Artesian Basin. Less is known about the
pack, which is predicted by climate models, will reduce the amount of ground water that is recharged by snowmelt. Large sum-mer storm events associated with the North American monsoon and remnant hurricane disturbances may become a more impor-tant source of ground water recharge. But this in turn means that these aquifers may rely on such climatic events to maintain or increase their long-term productivity. Clearly, we need a better understanding of how ongoing climate change will ultimately affect regional weather patterns like our summer monsoons.
Artificial recharge techniques, where surface water runoff in the mountains is injected and stored in the aquifer system, may become necessary to sustain down-gradient ground water resources. Knowledge gained from this regional-scale hydrogeology study can be very useful in identifying areas that would be sufficient for storing this water in the subsurface.
The Sacramento Mountains Watershed Study: Can We Increase Our Water Supply by Thinning Forests?Thinning trees is a forest restoration technique that is being used to improve wildlife habitat and reduce fire danger in the Sacramento Mountains. This restora-tion technique is also being studied to determine its potential for increasing the ground water and surface water supply.
contribution of ground water recharge from high-altitude precipitation to regional aquifers to the west. However, ephemeral mountain streams on the western slopes of the Sacramento Mountains certainly provide some recharge to regional aquifers in the Tularosa Basin. The New Mexico Bureau of Geology is currently conducting a similar hydrogeology study in this area.
When and Under What Conditions Does Ground Water Recharge Occur? Results from this regional study clearly indicate that most ground water originates as high-altitude snowmelt. However, under certain conditions, summer precipitation can contribute significantly to the regional ground water systems. Above-average rainfall in the summers of 2006 and 2008 significantly increased water levels in most wells being monitored in the study area. August 2006 and July 2008 were the wettest months recorded in Cloudcroft in the last 100 years. In 2006 the unusually wet monsoon season was characterized by frequent thunderstorms. In 2008 nearly half of the 13 inches of rain that fell in Cloudcroft in July fell within two days as a remnant disturbance of Hurricane Dolly passed over the area.
This observation has important implica-tions on how this hydrologic system may respond to climate change in the near future. A decrease in snowfall and snow-
Cross section of the Sacramento Mountains from west to east, showing the steep west-facing slope and the broader, more shallow east-facing slope. Much of the ground water moves eastward toward the Pecos River and the Roswell Artesian Basin.
neW Mexico BUreaU of GeoloGy anD Mineral reSoUrceS