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Tuya

A tuya is a type of flat-topped, steep-sided formed by subglacial eruptions, where ascends through and interacts with a thick or , initially producing hyaloclastic deposits that build a until the edifice emerges above the ice, at which point lava flows cap the summit plateau. These landforms are characterized by a lower of fragmental volcanic , a central flat summit of horizontally bedded lavas, and steep ice-contact slopes at the base. The term "tuya" originates from Tuya Lake in northern , , where such features were first described in 1947 by geologist William H. Mathews. Tuyas are rare globally and serve as key indicators of past glacial conditions, recording ice thicknesses through their morphology and the transition from subglacial to volcanism. They typically form in regions with glaciations, such as , the in the western United States, and the in northwestern . Notable examples include the Tuya Volcanic Field in , which encompasses over 20 tuyas and related subglacial landforms near Tuya Lake, and the tuya in 's Ódáðahraun desert, a prominent 1,682-meter-high feature formed during the last . While most tuyas are basaltic, rhyolitic variants occur, as seen in the Kerlingarfjöll central in , where explosive eruptions produced distinctive pyroclastic-dominated structures. These provide valuable insights into glaciovolcanic processes, paleoclimate reconstruction, and the interactions between and in formerly glaciated terrains.

Definition and Characteristics

Definition

A tuya is a flat-topped, steep-sided formed by the eruption of beneath a thick or , producing a distinctive isolated mound or hill with a table-like summit. The term "tuya" was coined in 1947 by geologist William H. Mathews to describe such landforms observed in northern , , derived from a local name for certain hills in the region. These volcanoes are distinguished by their subglacial origin, which confines eruptive products within the , leading to characteristic isolated, steep-sided structures that emerge as the ice retreats. Tuyas are rare worldwide, occurring only in regions that experienced contemporaneous glaciation and , such as parts of , , , and beneath ice sheets. Tuyas typically rise 100–500 meters above their base, with basal diameters ranging from 1 to 3 kilometers, though dimensions can vary based on ice thickness and eruption volume.

Morphological Features

Tuyas are characterized by their distinctive flat-topped, steep-sided morphology, often resembling table mountains or mushrooms, with a roughly circular to elliptical outline in plan view. These edifices typically rise from several hundred meters to over 400 meters above their base, featuring a level that contrasts sharply with the surrounding terrain. The sides of tuyas exhibit steep slopes, commonly ranging from 15° to 34° or more, resulting in near-vertical to moderately inclined walls that give the structure its pronounced vertical relief. These slopes are particularly evident in the lower portions of the edifice, where the transition from the base to the is abrupt, often without significant talus accumulation due to the resistant nature of the materials. The flat top of a tuya forms a subhorizontal plateau, typically capped by thick layers of lava flows, which can reach thicknesses of 90 to 120 meters. This summit plateau is a defining feature, often spanning several kilometers in diameter and providing a , expansive surface that highlights the edifice's subglacial origins in a confined environment. Morphological variations among tuyas include conical forms lacking a pronounced flat top, linear ridges with elongated profiles (length-to-width ratios greater than 2:1), and complex edifices combining multiple shapes from prolonged eruptive activity. Some tuyas display eroded edges or nested structures indicative of multiple eruption phases, altering the classic table-like profile while retaining core elements of steep flanks and a cap.

Formation and Geology

Subglacial Eruption Process

The subglacial eruption process that forms a tuya commences with the initial phase, in which ascends through a from a source beneath a ice sheet. This ascent liberates that melts the adjacent ice, excavating a subglacial and generating an englacial lake of within the confined space. The process demands substantial ice thickness to maintain confinement, typically at least 500–1000 meters, ensuring the cavity remains sealed against external pressure and prevents premature drainage. During the ensuing quench phase, the erupts into the water-saturated , where it undergoes rapid cooling upon contact with the . This interaction causes the erupting material to fragment and accumulate at the , building the foundational edifice through successive pulses of and under high hydrostatic pressure. The phase persists as long as the ice roof holds, with the potentially enlarging laterally and upward due to ongoing thermal erosion. In the breaching phase, continued edifice growth and volatile exsolution increase internal pressure within the cavity, eventually fracturing the overlying ice roof. This structural failure transitions the eruption to conditions, permitting unconfined lava flows to spread across the breached surface and cap the structure. The resulting flat-topped morphology arises from this shift, as the lava effuses horizontally before solidifying. The eruption concludes in the termination phase when the magma supply diminishes or is depleted, halting activity and isolating the emergent edifice. As the regional recedes over time—due to climatic warming or other factors—the tuya remains as a steep-sided, flat-topped protruding above the surrounding .

Associated Rock Types and Structures

Tuyas exhibit a characteristic vertical zonation in their , reflecting the transition from subglacial to eruptive conditions. The lower sections are predominantly composed of , consisting of glassy fragments formed by the rapid of in contact with water, along with pillow basalts and volcanic breccias. Pillow basalts in these basal units form lobate structures due to underwater , often interbedded with breccias derived from fragmented volcanic material. These rock types can reach thicknesses of up to 280 meters in examples. The upper cap of a tuya consists of subaerial basalt flows that form the flat plateau, typically exhibiting columnar jointing from cooling contraction. These flows, ranging from tens to hundreds of meters thick, overlie the fragmental lower units and represent the final phase when the edifice emerges above the ice surface. Internally, tuyas display a zoned structure from base to summit, beginning with possible sedimentary infill of ice-melt derived materials such as glacial debris or till at the foundation, transitioning upward through hyaloclastite and pillow-dominated units to the overlying lava flows. Intrusions such as dikes, which may show pillow-like structures on their margins, and sills can occur within the volcanic pile, facilitating magma ascent. The mineralogy of tuyas is primarily , with compositions ranging from to , dominated by , , and in the volcanic rocks, while the basal sediments incorporate ice-melt derived clasts of or volcanic fragments. in these edifices often contains basaltic glass, which alters to upon .

History and Etymology

Discovery and Naming

The term "tuya" was coined by Canadian geologist William H. Mathews in his 1947 paper, which described flat-topped volcanic features in northern British Columbia. Mathews introduced the term while analyzing Tuya Butte, the first such structure he systematically examined, highlighting its distinctive morphology formed through subglacial eruptions. The name derives directly from Tuya Butte, a prominent landform in the Tuya River area of , which itself may originate from the Tahltan language, an Athabaskan tongue spoken by in the region. Although the precise meaning in Tahltan remains unconfirmed in geological literature, the term's adoption reflects local nomenclature for the landscape. Following Mathews' publication in the American Journal of Science, "tuya" rapidly gained acceptance as the standard geological term for analogous flat-topped volcanoes worldwide, supplanting earlier descriptive phrases like "flat-topped mountains." This formalization stemmed from the paper's detailed stratigraphic and morphological analysis of Tuya Butte and nearby features, establishing a for identifying subglacial volcanic edifices.

Historical Context

Tuyas, distinctive flat-topped volcanoes, primarily formed during the Pleistocene epoch, spanning approximately 2.6 million to 11,700 years ago, when volcanic eruptions occurred beneath extensive ice sheets such as the Cordilleran and Laurentide in . These subglacial eruptions interacted with thick glacial ice, producing characteristic steep-sided, flat-capped landforms capped by subaerial lava flows after breaching the ice surface. The prevalence of tuyas in regions like northern underscores their association with Pleistocene glaciovolcanic activity under ice thicknesses estimated at several thousand feet. Flat-topped mountains in the region were noted during late 19th- and early 20th-century geological surveys of . However, the subglacial origin of these structures was not hypothesized until the mid-20th century, as geologists began linking their morphology to interactions with glacial ice rather than purely processes. This interpretation gained traction through field observations in remote northern , where the landforms' pillow lavas and bases suggested confinement by ice during eruption. In 1976, geologist S.S. Holland refined understandings of tuya formation in his comprehensive physiographic study of , emphasizing their development under thick Pleistocene ice sheets that constrained initial eruptions to subglacial lakes before allowing subaerial capping. Initial explorations focused on isolated Canadian sites like the Kawdy Plateau, but post- research expanded internationally, with detailed studies of analogous table mountains in confirming subglacial processes through fieldwork in the 1950s. Further investigations in the early identified potential subglacial tuyas beneath ice sheets, broadening global recognition of these features as indicators of past ice volumes.

Distribution and Examples

Global Distribution

Tuyas, flat-topped volcanic edifices formed by subglacial eruptions, are predominantly found in regions of the that experienced extensive glaciation during the Pleistocene epoch, particularly where volcanic activity coincided with ice cover. The primary concentrations occur in glaciated areas of , , within the , which hosts multiple such structures near Tuya Lake. Similarly, features numerous tuyas due to its history of subglacial volcanism under ice caps like . In the , the Azas Plateau in the Tuva Republic contains at least six prominent tuyas, formed during glaciations. Beyond these core Northern Hemisphere sites, tuyas appear in other glaciated volcanic provinces, including in the United States, where examples like Hayrick Butte and Hogg Rock rise in the . In the , the hosts tuyas such as on the Tabarin Peninsula, a structure that emerged from subglacial activity within the last million years. Subglacial tuyas have also been identified beneath the , indicating widespread glaciovolcanic activity under continental ice. Globally, tuyas are relatively rare and are primarily clustered in several major volcanic fields associated with hotspots or zones that were overridden by past ice sheets during glacial maxima. These distributions reflect the necessity of synchronous active and substantial thickness—typically exceeding 500 meters—to confine eruptions and produce the characteristic steep sides and flat summits. Modern analogs persist in Iceland's subglacial environments, where ongoing eruptions under ice caps demonstrate the processes that formed ancient tuyas elsewhere.

Notable Examples

Tuya Butte, located in northern , , is the type locality for the landform, first analyzed by geologist William H. Mathews in 1947, who coined the term "tuya" based on its distinctive morphology. The edifice rises approximately 390 meters above its base, forming a roughly oval structure measuring 4 by 2.5 kilometers, with horizontal flows capping a sequence of deposits indicative of subglacial eruption. places its formation at around 1.1 million years ago, during the Pleistocene epoch. Herðubreið, an iconic in northeastern near the volcanic system, exemplifies a complex tuya with a peak elevation of 1,682 meters. It erupted during the approximately 20,000 to 12,000 years ago, when ice thicknesses exceeded 2 kilometers, producing a flat-topped edifice of ridges overlain by lava flows and a post-glacial cone. The structure's steep, palagonitized slopes and symmetrical form make it a prominent , often called the "Queen of Icelandic Mountains." The , situated in the of southern , , stands about 300 meters high and represents a lava-dominated tuya variant. Its base features a thick sequence of formed through interactions with glacial , transitioning upward to subaerial cap lavas that preserve the flat . This edifice highlights variations in glaciovolcanic construction where effusive activity predominates over explosive phases. On the Azas Plateau in the , , Sorug-Chushku-Uzu forms a large tuya complex approximately 10 kilometers in , with multiple vents contributing to its elongated, flat-topped profile rising to 2,525 meters elevation. The structure includes nested ridges and subglacial pillow lavas, reflecting prolonged eruption under thick ice sheets during Pleistocene glaciations, and is one of the most extensive examples in the East Tuva . Additional notable examples in the Tuya Volcanic Field include Caribou Tuya in northern , dated to about 1.2 million years old, which exhibits classic flat-topped morphology with a prominence of around 300 meters. West Vent, another component of the field, is a small shield-like tuya with a broad, low-relief summit formed by late-stage effusive activity emerging through glacial ice.

Scientific Significance

Glacial Reconstruction

Tuyas serve as key proxies for inferring past thicknesses because the formation of their flat, lava caps requires the volcanic edifice to penetrate through the overlying , with the cap's above the basal contact providing a direct measure of the minimum ice depth at the time of breaching. Passage zones—transitional boundaries between subglacial and deposits—further refine these estimates by recording paleo-englacial lake levels and . For example, at Kima’Kho tuya in northern , a passage zone at approximately 1,850 m above indicates an englacial lake depth of about 380 m, constraining the minimum thickness to over 425 m during the eruption. Radiometric dating of tuya lavas using methods such as ⁴⁰Ar/³⁹Ar and establishes the timing of eruptions, enabling correlations with glacial maxima and paleoclimatic phases. These techniques analyze the decay of isotopes in volcanic rocks to yield precise ages, linking subglacial to specific intervals of advance. In northern British Columbia's Tuya-Kawdy region, such of over 30 Pleistocene tuyas has produced a 3-million-year volcanic record that intersects with multiple glaciations, offering temporal anchors for fluctuations. The spatial distribution of tuyas maps former ice sheet extents by identifying sites of subglacial eruptive activity, particularly in regions like the of where volcanic fields align with reconstructed ice limits. Tuya fields in , such as those on the Tuya-Kawdy Plateau, delineate the margins and internal dynamics of the during the . These features reveal patterns of the Fraser Glaciation—the final major phase of Cordilleran advance from approximately 30,000 to 10,000 years ago—by showing eruption loci beneath ice thicknesses exceeding 400 m, which constrained ice flow directions and local topographic influences on glacial erosion.

Volcanological Research

Volcanological research on tuyas has advanced through precise geochronological techniques to determine eruption timelines, revealing that many such edifices formed between 0.01 and 2 million years ago. The 40Ar/39Ar method, a variant of potassium-argon dating, has been widely applied to basaltic and rhyolitic samples from tuya caps and underlying pillow lavas, providing high-resolution ages for subglacial eruptions in regions like northern and . For younger tuyas, cosmogenic nuclide dating, particularly using 3He exposure ages on surfaces analogous to tuya tops, complements radiometric approaches by quantifying post-eruptive exposure durations and glacial interactions in . Geophysical surveys, including seismic profiling and (GPR), map subsurface structures such as feeder dikes and cavity roofs, with GPR proving effective for imaging near-surface explosive deposits in monogenetic tuyas. Post-2000 studies have focused on tuyas to develop models of subglacial , integrating radio-echo sounding, , and magnetic data to inventory over 138 subglacial edifices in , many manifesting as emergent tuyas. , such as Landsat mosaics, facilitates remote identification of tuya-like landforms in inaccessible regions, aiding preliminary mapping before targeted fieldwork. Despite these advances, significant gaps persist in quantifying eruption volumes, with estimates for individual tuyas ranging from 0.1 to 10 km³ but lacking precision due to erosion and ice cover. Models of magma-ice remain approximate, often assuming efficient convective exchange but underestimating conductive losses and ice deformation effects. Furthermore, the potential for subglacial eruptions to drive climate-volcano feedbacks through gas emissions and pulses is underexplored, as historical impacts on are poorly constrained.