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Crystal Geyser

Crystal Geyser is a cold-water, -driven located on the east bank of the in , approximately 10 miles south of the town of . This partially human-made feature, one of the few cold-water in the world, erupts under high pressure from dissolved gas, producing fountains of water without geothermal heat. The originated in 1936 during oil exploration when a well known as Ruby No. 1, drilled in 1935, inadvertently penetrated a pressurized containing from ancient geological formations. The , sourced from Jurassic-age and Entrada sandstones trapped by the Little Grand Wash fault in the Paradox Basin—a region with over 250 million years of sedimentary history—mixes with to create the explosive eruptions. Historically, eruptions reached heights of up to 200 feet, but as of 2025, they typically reach 2 to 10 feet high, occurring irregularly every 8 to 27 hours (often about twice daily) and lasting from minutes to over 2 hours. In 2023, after years without significant activity, eruptions resumed due to increased pressure from wet weather, though obstructions such as rocks thrown into the vent by visitors continue to limit heights and predictability. Notable for its "soda pop" like fizzing explosions and vibrant terraces formed by deposits from the mineral-rich water, Crystal Geyser has been a regional since its and draws hikers and geologists to its remote desert setting. The site is accessible via a short, unpaved road from , offering views of the surrounding [San Rafael Swell](/page/San Rafael_Swell) landscape, though visitors are advised to respect the fragile formations to preserve its natural dynamics.

Location and Description

Geographical Position

Crystal Geyser is located on the east bank of the in , , at precise coordinates of 38°56′18″N 110°08′08″W. This positions it approximately 10 miles (16 km) south of the town of , accessible via a dirt road off Interstate 70. The site sits at an elevation of 4,062 feet (1,238 m) above , within a semi-arid environment typical of the region. The occupies a dynamic setting where the flows through layered sedimentary rocks, influencing local erosion patterns and sediment deposition. It lies within the , characterized by vast tablelands and canyons formed over millions of years. Nearby rock formations include Jurassic-age and Entrada Sandstones, which contribute to the area's striking red and white cliffs visible along the riverbanks. To the west, Crystal Geyser is in close proximity to the , an expansive anticlinal structure that defines much of the surrounding topography with its rugged reefs and slot canyons. This location highlights the interplay between fluvial dynamics of the and the broader tectonic features of east-central .

Physical Features

Crystal Geyser is a driven by (CO₂) pressure rather than geothermal heat, classifying it as a non-thermal feature with effluent water maintaining an average temperature of 18.0°C (64.4°F). The sits atop a gently sloping, conical that spans approximately 85 m (279 ft) across at its base and reaches a thickness of a few meters, formed through ongoing from erupted waters. At the 's summit lies the central vent, consisting of an exposed iron protruding about 0.6 m (2 ft) high and surrounded by vibrant encrustations, including iron oxide-rich laminae in shades of orange and red, alongside low-Mg and deposits that decrease in abundance away from the vent. The geyser's water originates from a CO₂-saturated aquifer within the Jurassic Navajo and Entrada Sandstones, where dissolved minerals such as calcium and iron are mobilized and subsequently deposited as travertine during surface exposure.

History

Early Exploration

The first recorded human encounter with the site of Crystal Geyser took place on July 13, 1869, during the Powell Geographic Expedition led by John Wesley Powell, a pioneering explorer and geologist tasked with mapping the uncharted canyons of the Green and Colorado Rivers in the American West. As the expedition navigated downstream along the Green River in present-day eastern Utah, members observed evidence of ancient mineral springs manifesting as tufa deposits and curious rock formations along the riverbank. Powell described stopping after a rapid to examine these features, noting "some curious rocks, deposited by mineral springs that at one time must have existed here, but are no longer flowing," indicating the springs had ceased activity by that time. This observation was documented in Powell's official report, Report on the Exploration of the Colorado River of the West and Its Tributaries (1875), which detailed the expedition's findings on the region's and to inform potential and resource development. The site appeared as a natural seep or inactive , with no eruptive behavior noted, aligning with the expedition's broader focus on identifying water sources amid the arid landscape. Powell's work contributed to early understandings of the area's karst-like features, though the specific location was not named "Crystal Geyser" at the time. The Crystal Geyser site lay within territories explored through various 19th-century U.S. government surveys of , including the Powell Survey (1869–1879), which systematically assessed geography, geology, and natural resources across and surrounding states. These efforts revealed scattered reports of carbonate-rich springs and minor oil seeps in the vicinity, but the remote location along the saw no significant settlement or exploitation during this period. Human activity remained minimal until early 20th-century oil prospecting interests drew attention to the region, prompted by those earlier seep observations.

Drilling and Artificial Origin

In 1935, an oil exploration well known as Ruby No. 1 (or Glen Ruby #1-X) was drilled at the site of Crystal Geyser in , as part of efforts to locate resources in the Paradox Basin region. The drilling targeted potential reservoirs but instead intersected a pressurized system. The well was advanced to a total depth of approximately 2,627 feet (800 meters), penetrating formations including the Entrada Sandstone. Upon completion in early 1936, the well was abandoned without adequate sealing, which allowed from overlying units to migrate downward and interact with (CO₂) gas escaping from deeper reservoirs in the Entrada Sandstone. This improper abandonment created a pathway for CO₂ accumulation, pressurizing the system and transforming the site into an artificial . The first eruptions occurred shortly after abandonment in , marking the onset of the geyser's activity. Initial activity featured two distinct cycles: shorter eruptions reaching up to 82 feet (25 meters) every 15 minutes, and longer cycles with jets up to 148 feet (45 meters) occurring approximately every 9 hours. These powerful displays were driven by the buildup of CO₂-saturated water, which generated sufficient pressure for periodic ejections, quickly drawing regional attention to the newly formed feature.

Geology

Regional Geological Context

Crystal Geyser is situated within the , a tectonically stable region characterized by broad uplifts and minimal deformation since the Mesozoic era. The broader area lies at the northern margin of the Paradox Basin, an intracratonic basin formed during the Pennsylvanian Period due to the ancestral orogeny associated with the Uncompahgre uplift. Subsequent modifications occurred during the in the to early (approximately 70–40 million years ago), which imposed regional compression, faulting, and uplift across the , including the development of monoclines and reverse faults that influenced basin architecture and fluid migration pathways. This tectonic framework created structural traps and permeability contrasts essential for hydrocarbon and gas accumulations in the region. At the site of Crystal Geyser, the Little Grand Wash fault plays a crucial role in trapping CO₂ in the sandstones and providing conduits for upward migration. Key stratigraphic units in the vicinity include the Entrada , a porous eolian and marginal marine deposit that serves as a primary for dissolved CO₂ due to its high permeability and connectivity via faults. Overlying it is the Summerville Formation, composed of red siltstones and mudstones that exhibit evidence of dissolution linked to acidic CO₂-rich fluids percolating through the section. The nearby , also , consists of fluvial and lacustrine sediments including sandstones and shales, contributing to the regional system and occasionally hosting evaporitic influences from deeper strata. These formations overlie older units, including the Pennsylvanian Paradox Formation, which includes organic-rich shales that generate CO₂ through maturation, as well as evaporites acting as seals. The of the Paradox Basin features interconnected porous aquifers within , such as the Entrada, that facilitate and gas migration over large distances. Natural CO₂ seeps are prevalent throughout the basin, resulting from CO₂ migrating from deeper sources in the Paradox Formation, such as organic-rich shales, into overlying aquifers via fault conduits and stratigraphic leaks. This results in carbonated springs and seeps common across the , with typically saline in evaporite-influenced zones but fresher in higher sandstone aquifers. These formations date to the Period, approximately 150 million years ago, during a time of widespread shallow and terrestrial deposition across the Western Interior of . The Entrada Sandstone spans the Middle to (Callovian to Oxfordian stages, ~168–160 Ma), while the Summerville and Morrison Formations are firmly (Oxfordian to Tithonian, ~160–145 Ma).

Local Formation Processes

The at Crystal Geyser is primarily composed of low-magnesium , with dominating near the vent and transitioning to magnesium-poor outward from the central area. The distinctive coloration of the deposit results from precipitates, which form alternating laminae with micritic layers in the primary fabric. deposition occurs as dissolves (CaCO₃) from the overlying Summerville Formation, a unit rich in carbonates, before the waters rise to the surface. Upon ascent, of dissolved CO₂ causes and rapid precipitation of as the pH increases and decreases. Dissolved CO₂, sourced from deep aquifers within the regional aquifer at depths of approximately 215 m, plays a central role in both mineralization and the potential for eruptions by building subsurface pressure through gas accumulation. The mound has grown through ongoing accumulation since the geyser's activation in the mid-20th century, spanning over 80 years, and now forms a gently sloping structure approximately 85 m across and a few meters thick.

Eruptions and Hydrology

Eruption Mechanics

Crystal Geyser's eruptions are driven by the accumulation of (CO₂) gas in a subsurface , where pressure builds until it surpasses the resistance of the overlying cap rock or well , leading to a sudden release. This process is facilitated by the geyser's origin as an abandoned oil exploration well drilled beginning in to a depth of 2,627 feet (800 meters), which activated in 1936 upon penetrating a fault zone connecting to natural CO₂ reservoirs. The eruption sequence begins with the gradual filling of the surface with several hours prior, accompanied by minor bubbling events that increase in intensity over intervals of about 20 minutes. As CO₂ exsolution occurs due to reduction, gas expansion propels the water—typically at around 17°C—upward in a vigorous jet, transitioning from initial bubbling to high-velocity jetting that can reach heights of up to 15 meters. The eruption concludes abruptly with the drainage of the back into the conduit, marking the end of the active phase. Eruptions exhibit a bimodal duration pattern, with short events lasting 7–32 minutes and longer ones extending 98–137 minutes, reflecting variations in gas volume and pressure buildup. Unlike thermal geysers such as , which rely on steam formation from exceeding 100°C, Crystal Geyser operates through non-thermal gas expansion, resulting in consistently cold-water discharges without .

Patterns and Variability

Crystal Geyser's eruption patterns have evolved significantly since its artificial activation in , initially featuring frequent short bursts and periodic major events. Early observations reported minor eruptions reaching 80 feet (24 m) at intervals of approximately 15 minutes, interspersed with taller columns up to 150 feet (46 m) occurring every . These patterns reflected a relatively regular cycle driven by the buildup of carbon dioxide-charged water in the , with the geyser's activity peaking in and 1940s before gradually diminishing. By the mid-2000s, monitoring revealed a distinct in eruption cycles, with approximately 66% of events following short intervals of about 7.6 hours and 33% occurring after longer intervals of around 22.2 hours. This was documented during a 76-day observation period in 2005, which recorded 140 eruptions and highlighted the absence of intermediate cycle lengths. Eruption durations also showed bimodality, with short events lasting 7–32 minutes (average 19 minutes) and long events extending 98–137 minutes (average 114 minutes), contributing to a cumulative daily eruption time of about 101 minutes. Variability in intervals has ranged from 8 to 27 hours, influenced by factors such as obstructions from , including added rocks, and potential but unconfirmed effects from regional seismic activity. Durations for major eruptions typically span 3–49 minutes, though overall frequency and predictability have decreased over time. Observations after 2005, including as of 2023, indicate increasingly sporadic behavior, with intervals sometimes exceeding 24 hours. In 2023, following a wet winter, the experienced a temporary increase in eruption frequency, though heights remained low at 2–10 feet (0.6–3 meters); major eruptions have been rare since. As of 2023, most eruptions reach heights of 2 to 10 feet (0.6 to 3 meters), primarily as minor events that are often unpredictable and occur at irregular times, such as overnight. This shift underscores ongoing changes in the geyser's , potentially linked to variations in CO₂ accumulation, though detailed remain tied to broader hydrological processes.

Scientific and Cultural Significance

Research and Studies

Early scientific investigations of the Crystal Geyser site began with Powell's documentation of the regional during his 1869 expedition through the region, as detailed in his 1895 publication Canyons of the Colorado, which described the faulted Entrada Sandstone and formations in the area. Following the geyser's accidental creation in 1936 during oil exploration drilling that intersected a pressurized CO₂-saturated , initial post-drilling observations focused on the artificial eruptions, with local newspaper reports noting blowouts reaching up to 45 meters in height every nine hours shortly after abandonment of the Ruby 1-X well. Key publications have advanced understanding of the geyser's dynamics. Gouveia and Friedmann's 2006 study analyzed 145 eruptions over 76 days in 2005, revealing a bimodal periodicity with short eruptions averaging 19 minutes (63% of events) followed by intervals of about 7.6 hours, and long eruptions averaging 114 minutes (37% of events) followed by 22.2-hour intervals, enabling predictive models based on eruption duration. Barth and Chafetz's 2015 research on the surrounding mound, approximately 85 meters across and a few meters thick, employed petrographic thin-section analysis, diffraction on 88 samples, and scanning electron to identify low-Mg as the dominant mineral, with prevalent near the vent due to rapid CO₂ degassing, and microbial influences like Leptothrix bacteria contributing to iron oxide-rich laminae in depositional couplets. Research methodologies have included seismic monitoring to image subsurface fault properties and CO₂ outgassing signatures along the Little Grand Wash Fault, as in active-source seismic profiling studies that correlate eruption cycles with fault permeability. chemistry analyses have tracked periodic variations in effluent composition, such as and concentrations tied to CO₂ during eruptions, revealing similarities to natural analog leakage processes in CO₂ storage sites. Time-lapse observations, using thermistors, sensors, and loggers, have documented cycle variability, including bimodal patterns and atmospheric influences on interval timing over multi-year periods. Despite these advances, significant gaps persist, particularly regarding long-term to assess variability driven by environmental changes. Eruption activity reactivated in 2023 following a multi-year quiescence, attributed to elevated levels from a wet winter, with ongoing eruptions reported through 2025.

Tourism and Conservation

Crystal Geyser serves as a popular roadside attraction in eastern , accessible via a well-maintained dirt road off at exit 164 near . From the town of , the drive takes approximately 20-30 minutes south along the Green River shoreline, with free public access on federal land requiring no permits or fees. The site is reachable by standard vehicles, though visitors are advised to check road conditions after rain due to occasional mud. Visitors are drawn to the site primarily for observing the 's cold-water eruptions, which create a spectacle of colorful deposits in shades of orange, red, and white surrounding the vent. The experience often involves waiting 17 to 27 hours between major events, during which time people , hike nearby trails, or launch rafts for outings from the adjacent boat ramp. is available at dispersed sites along the riverbank, enhancing its appeal for multi-day adventures in the region. The attracts thousands of annually, including international visitors, particularly during periods of heightened activity following wet winters. As a designated GeoSight managed by the Geological Survey, Crystal Geyser benefits from oversight to preserve its unique features, though it faces threats from human activity. , such as visitors throwing rocks into the , has partially plugged the vent, reducing eruption heights from historical maxima of up to 200 feet to current levels of 40-80 feet and altering frequency patterns. from foot traffic and vehicle proximity also poses risks to the fragile mounds and surrounding riparian habitat. Recent conservation initiatives include ongoing monitoring by the Utah Geological Survey, which has deployed sensors over the past two decades to track eruption dynamics and site stability. Following increased activity in due to elevated levels from a wet winter, there have been calls for enhanced assessments of long-term stability and potential climate influences on the CO2-driven system, with activity continuing as of 2025. Proposed interventions, such as clearing obstructions from the vent or installing a protective cap, remain under consideration to mitigate further degradation while maintaining public access.

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