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Mima mounds

Mima mounds are low, dome-shaped hills, typically up to 2 meters high and 12 meters in diameter, composed of sandy loam overlying coarse-bedded gravels, that occur in dense clusters on proglacial terraces in the Puget Lowland of western Washington state.^[1] These elliptical to circular features, elongated parallel to slopes, are best known in prairie landscapes south of Olympia but similar mound complexes—often termed Mima-like or desert mounds—appear globally in regions including the American Midwest, California, South Africa, and Australia.^[1] First documented scientifically in the early 20th century, the mounds have puzzled researchers due to their uniform spacing and abrupt boundaries with surrounding flat terrain, prompting over a century of investigation into their formation.^[1] The prevailing explanation for their origin is the fossorial rodent hypothesis, which posits that pocket gophers (Thomomys mazama) build the mounds through intensive burrowing in response to seasonally waterlogged soils, creating refuges that promote vegetation and concentrate further activity.^[2] This biotic process, first proposed in 1942 based on field observations of gopher behavior and mound stratigraphy, involves rodents excavating shallow pits in underlying gravel, mixing finer sediments into raised lenses, and exposing larger stones on surfaces over extended periods.^[2] Numerical modeling studies have since validated this theory, demonstrating that gopher burrowing can generate self-organized mound patterns and vernal pools in 500–700 years, matching observed field distributions without invoking abiotic forces alone.^[3] Alternative hypotheses have included glacial "sun cup" melting from retreating ice sheets, wind-driven aeolian deposition anchored by vegetation, and seismic liquefaction of sediments during earthquakes, though these lack the empirical support and predictive power of the gopher model.^[1] Mima mounds play key ecological roles today, supporting unique prairie habitats for endemic plants and insects amid ongoing threats from urbanization and invasive species in the Pacific Northwest.^[1]

Description and Characteristics

Physical Structure

Mima mounds are low, flattened, circular to oval, dome-like natural hills formed by the accumulation of soil and sediment. They typically measure 2.5 to 21 meters in diameter and rise 0.5 to 2 meters in height, though some reach up to 2.4 meters at sites like Mima Prairie in Washington.^[4] Their overall morphology often resembles a biconvex lens, with occasional elliptical shapes aligned parallel to drainage patterns on slopes.^[4] Mound volumes reach up to approximately 38 cubic meters.^[4] The mounds consist primarily of loose, unstratified, gravelly sandy loam derived from glacial till or outwash deposits, such as the Vashon outwash in the Pacific Northwest.^[4] Internally, they exhibit distinct soil horizons: a dark, organic-rich A horizon (often black, 10 YR 2/1, up to 76 cm thick) overlying a coarser C horizon, with the A horizon comprising approximately 56% gravel, 23% sand, 16% silt, and 5% clay, while the C horizon has higher gravel content at 74%.^[4] This layering shows an angular unconformity with underlying bedded outwash, and mounds may include rounded pebbles, cobbles up to 9 cm, and occasional boulders up to 35 cm in diameter concentrated toward the crests.^[4] In some regions, such as Manastash Ridge, the soil is a homogeneous silt loam with low clay (5-10%) over basalt bedrock, featuring a mollic epipedon 18-31.5 cm thick.^[5] Surfaces of Mima mounds are typically covered by a dense turf of grasses, mosses, and lichens, which provides protection against erosion and maintains a treeless appearance in pristine areas, though shrubs and trees may encroach in disturbed sites.^[4] Erosion patterns are minimal due to this vegetative cover, but low mounds under 30 cm may represent remnants of larger forms.^[4] Mounds occur in extensive fields with regular, over-dispersed spacing of 10 to 30 meters between centers, often forming hexagonal or curvilinear patterns that reflect underlying topography, at densities of 20 to 25 mounds per hectare.^[4]^[6] Intermound areas frequently contain vernal pools or shallow depressions.^[4]

Associated Ecological Features

Mima mounds support the formation of vernal pools in the shallow depressions between mounds, creating seasonal wetlands that fill with rainwater during the wet season and dry out in summer. These ephemeral pools are integral to the local hydrology, as the mound topography promotes water retention in low-lying areas, fostering unique microhabitats that differ from the surrounding uplands.^[4]^[7] The biodiversity of these ecosystems is notable, with vernal pools harboring specialized flora and fauna adapted to the wet-dry cycles. Rare prairie species such as Lupinus polyphyllus (bigleaf lupine) thrive in the mound-interspersed grasslands, contributing to the floral diversity alongside grasses like Festuca idahoensis and forbs. Fauna includes amphibians dependent on pool cycles for breeding, such as the northwestern salamander (Ambystoma gracile), which utilizes the temporary wetlands, as well as endemic crustaceans and insects unique to these habitats—over 100 plant and animal species in California vernal pool landscapes alone exhibit high endemism, with approximately 50% of regional crustacean species restricted to them.^[8]^[4]^[9] Underlying the mounds and pools are impermeable clay layers or hardpans that create perched water tables, preventing deep drainage and sustaining the ephemeral nature of the wetlands even on otherwise permeable soils. This hydrological regime results in distinct soil profiles, with higher organic matter accumulation in mound tops (up to 24% in A horizons) compared to intermound areas, supporting varied microbial activity.^[7]^[4]^[9] The mound topography influences interactions with surrounding prairie grasslands by altering drainage patterns and facilitating nutrient cycling; bioturbation from burrowing animals like pocket gophers mixes soils, concentrating nutrients on mounds and enhancing overall ecosystem productivity in the grasslands. This dynamic supports a mosaic of habitats where mounds act as nutrient hotspots amid the broader prairie matrix.^[9]^[7]^[4]

Geographic Distribution

Pacific Northwest and Adjacent Regions

Mima mounds are primarily concentrated in the southern Puget Lowland of Washington state, particularly within Thurston County, where they characterize several prairie remnants such as Mima Prairie, Rocky Prairie, and areas within Capitol State Forest near Capitol Peak.^[4] These landforms occur on the outwash deposits from the Vashon Stade of the Fraser Glaciation, which reached its maximum extent approximately 14,000 years ago and left behind gravelly sandy loam soils that form the substrate for the mounds.^[4] The mounds in these sites typically exhibit densities of 20 to 25 per hectare, contributing to a distinctive undulating topography across the landscape.^[6] Historically, Mima mounds covered an estimated 30,000 acres (about 12,140 hectares) in the southern Puget Lowland, encompassing roughly 900,000 individual mounds before significant portions were altered by agriculture, development, and forest regrowth.^[10] Today, these prairies represent fragmented remnants influenced by post-glacial drainage patterns, where impeded water flow on the outwash plains has preserved open grasslands amid encroaching coniferous forests.^[4] The environmental context features a maritime climate with cool, dry summers and mild, wet winters, which supports unique prairie ecosystems on these geologically distinct surfaces. Beyond Washington, similar mound features extend into southern Cascadia, notably in the prairies of south-central Oregon, where they share comparable soil and topographic characteristics with their northern counterparts. Reports also indicate Mima-like mounds in adjacent regions, including the Fraser Valley of British Columbia, aligning with the broader distribution of such microrelief across post-glacial landscapes in the Pacific Northwest.^[1]

Broader North American Occurrences

Mima-like mounds occur in the southwestern United States, including California prairies such as those in San Diego County and the Carrizo Plain National Monument in San Luis Obispo County, where they form smaller, less dense clusters integrated into grassland ecosystems.^[11] In Texas, these features are known as pimple mounds, particularly in the coastal prairies and Gulf Coast regions, exhibiting similar low-relief, circular to oval shapes but often associated with relict dune formations from late Holocene droughts.^[12] Extending into northwestern Mexico, analogous mounds appear in Baja California, especially in vernal pool landscapes near the fringes of the Sonoran Desert, where they support interstitial wetlands and exhibit subdued topography compared to northern examples.^[13] In the central and eastern United States, Mima-type mounds are documented in Missouri's Diamond Grove Prairie Natural Area, where they rise to an average height of 45 cm and span about 14 m in diameter, with densities of roughly 7.6 per hectare on gravelly, residual soils derived from cherty limestone bedrock.^[14] Similar formations, often termed prairie or pimple mounds, dot landscapes in Oklahoma's eastern counties like Haskell and Le Flore, as well as throughout Arkansas, typically on loess, alluvial, or karst-influenced substrates that promote localized soil thickening through bioturbation and erosion.^[15]^[16] These eastern and central variants generally feature smaller dimensions, ranging from 5 to 20 m in diameter, contrasting with the larger, more organized arrays in the Pacific Northwest while sharing core structural similarities such as gravelly, bioturbated profiles.^[14] Further broadening their North American scope, Mima-like mounds appear in the channeled Scablands of eastern Washington and northern Oregon, where they cluster on windblown silt (loess) and alluvial deposits amid the region's basaltic terrain.^[4] A 2025 LiDAR analysis by Eastern Washington University researchers quantified mound distributions in areas like the Rock Creek Recreation Area near Sprague, Washington, revealing extensive clustering patterns and supporting ongoing investigations into their geomorphic evolution on these substrates.^[17]

Formation Theories

Biological Mechanisms

The primary biological mechanism proposed for the formation of Mima mounds involves the burrowing activity of pocket gophers, particularly Thomomys mazama, which preferentially excavate and deposit soil in loamy, well-drained substrates over extended periods.^[2] According to this hypothesis, first detailed by Dalquest and Scheffer in 1942, gophers construct tunnels in response to seasonally saturated soils, pushing excavated material uphill and toward mound centers due to behavioral preferences for drier, elevated areas, resulting in gradual mound accumulation through repeated deposition spanning millennia.^[2] Field observations by Dalquest and Scheffer showed that gopher burrowing patterns closely mimic the spatial arrangement and soil profiles observed in Mima mounds, with active colonies producing similar small-scale heaps that coalesce over time.^[2] Supporting evidence includes subfossil beetle remains from rodent burrows in mound sediments, indicating historical occupancy by fossorial rodents such as Thomomys mazama, as well as modern observations of gopher colonies concentrated along mound edges where they continue to maintain and modify structures by translocating soil inward.^[18] Numerical simulations further corroborate the theory, showing that realistic gopher behaviors—such as uphill soil pushing and territorial burrowing—can generate mound-like features approximately 2 meters high within 500 to 700 years under prehistoric population conditions, involving successive generations of hundreds of individuals per site.^[3] Alternative biological explanations, such as mound construction by ants or termites, have been suggested for similar "pimple mounds" in regions like Texas, where insect colonies excavate and heap soil in arid environments, but these mechanisms lack substantial evidence for classical Mima mounds in the Pacific Northwest, where gopher activity aligns more closely with observed sediment characteristics.^[7] Critiques of the pocket gopher hypothesis often highlight a perceived mismatch in scale, noting that modern gopher mounds are typically small (under 0.5 meters) compared to Mima mounds reaching 2 meters, raising questions about feasibility with current population densities.^[19] However, computational models addressing prehistoric higher densities and long-term cumulative effects demonstrate that such discrepancies are resolvable, with gophers capable of transforming landscapes over thousands of years through persistent bioturbation.

Geological and Climatic Processes

One prominent abiotic explanation for the formation of Mima mounds involves aeolian processes, where post-glacial winds transported and sorted sand and gravel over uneven terrain, leading to dune-like accumulations that were later stabilized by vegetation.^[20] This hypothesis posits that vegetation patches acted as anchors, trapping wind-blown sediments to create mound structures, with evidence drawn from particle size gradients showing finer materials on mound tops and coarser ones in surrounding areas.^[6] Proposed in early 20th-century studies and refined in later analyses, the aeolian model remains viable for explaining mound distribution in wind-exposed prairies, though it struggles to account for the regular spacing observed in many sites.^[20] Seismic activity represents another key geological process invoked for mound genesis, particularly through soil liquefaction during earthquakes, where saturated, unconsolidated sediments are shaken into dome-shaped heaps. Andrew Berg's 1990 seismic hypothesis suggests that vibrational shock waves from earthquakes, propagating through loose fine-grained soils overlying a rigid substratum, concentrate material into mounds 2.5 to 15 meters in diameter and up to 3 meters high, as demonstrated by laboratory simulations producing nearly identical forms.^[21] This mechanism has been proposed especially for sites in California near active faults, such as those in North San Diego County, where liquefaction features and sand-rich dome structures align with paleoseismic evidence from Holocene earthquakes.^[22] However, the hypothesis faces challenges in explaining mounds in seismically stable regions or on non-liquefiable substrates.^[20] Early glacial theories, including subglacial pressure, ice-rafted debris, and differential melting of ice lenses, were among the first proposed for Mima mound origins but have largely been discredited due to the absence of correlative glacial till or erratic deposits in mound substrates. For instance, J Harlen Bretz's 1913 idea of sediment accumulation in snow or ice pits (suncups) and R.C. Newcomb's 1940 frost polygon model—where melting ice in frozen cracks left soil gaps—failed to match field sedimentology and have been rejected by modern geologists.^[20] A related 19th-century hypothesis linked mounds to catastrophic glacial outburst floods, such as a proposed event 17,000 years ago from Mount Rainier, but sediment analyses show mismatches with expected flood deposits.^[23] A 2024 review notes over 30 distinct theories for Mima mound formation, encompassing these and other abiotic processes, yet none has achieved universal acceptance due to site-specific variations and conflicting evidence.^[20]

Research and Investigations

Historical Studies

The Mima mounds were first documented by European explorers and settlers in western Washington during the 1840s, with early accounts appearing in journals from expeditions traversing the Puget Lowland prairies. In April 1840, Sir James Douglas of the Hudson's Bay Company noted the distinctive rounded hillocks during travels near the Nisqually River, describing them as unusual features amid the grassland landscape.^[24] Initial interpretations by these settlers attributed the mounds to human activity, specifically Native American construction, such as burial sites or defensive earthworks, though this view was later disproven through geological examinations revealing natural sedimentary patterns inconsistent with anthropogenic origins.^[20] By the late 19th century, preliminary geological surveys in the region, including those by U.S. Geological Survey personnel like Bailey Willis during his mapping of glacial deposits around Mima Prairie, began shifting focus toward natural processes, though definitive explanations remained elusive.^[25] Early 20th-century investigations laid foundational observations, including distribution surveys in the 1930s that mapped mound fields across Washington prairies such as those near Olympia and Tenino. These efforts, conducted by local naturalists and geologists, estimated over 100,000 individual mounds in pre-settlement prairie ecosystems, highlighting their dense clustering—typically 10 to 30 per acre—and association with glacial outwash soils.^[4] A pivotal advancement came in 1942 with the publication by Walter W. Dalquest and Victor B. Scheffer in The Journal of Geology, which proposed a biological origin through pocket gopher (Thomomys spp.) burrowing. Their seminal study involved excavation experiments on active mound sites, burrow mapping to trace sediment displacement patterns, and analysis of internal mound sediments showing layered gopher tunnels filled with prairie soil, suggesting gradual mound buildup over centuries as gophers sought elevated, well-drained positions above seasonal water tables. Mid-20th-century debates intensified through U.S. Geological Survey reports from the 1950s and 1960s, which rigorously tested competing geological mechanisms against the emerging biological hypothesis. R. C. Newcomb's 1952 analysis in The Journal of Geology, based on USGS fieldwork in Thurston County, critiqued the gopher hypothesis for internal inconsistencies and advocated for a geological origin involving differential erosion of glacial sediments, with trench digs revealing patterns more consistent with undisturbed glacial deposits than bioturbation. These investigations, including soil coring and topographic surveys, highlighted field evidence supporting geological processes over biological ones at the time.^[26] By the 1960s, such studies had established a timeline of mound development tied to post-glacial prairie stabilization, influencing later extensions into ecological modeling.^[27]

Modern Analyses and Debates

In the 1980s and 1990s, soil studies on Mima mounds emphasized grain-size distribution and organic matter content, revealing patterns consistent with post-glacial soil development, while radiocarbon dating of mound organics yielded ages up to approximately 4,180 years BP at depth, though the features themselves correlate with deglaciation around 13,000–14,000 years BP following the retreat of the Vashon glacier.^[4] These analyses, including work by Cox and Gakahu (1984) on soil volume displacement in analogous mound systems, supported bioturbation as a key process but highlighted the need for further chronological refinement due to organic mixing in the profiles.^[28] Studies of pocket gopher populations (Thomomys spp.) in mound fields during the 2000s and 2010s examined burrowing behaviors and indicated stable densities that could sustain long-term soil turnover without overexploitation of resources, bolstering the biotic model through numerical simulations.^[29] A 2024 synthesis in National Geographic underscored the persistence of over 30 theories for mound formation, noting that the pocket gopher model has gained significant traction through computational simulations demonstrating mound development over centuries, yet seismic hypotheses remain viable particularly for arid-region analogs where biological agents are scarce.^[20] This review highlighted the polygenetic nature of mounds, integrating evidence from multiple disciplines without resolving the debate. In 2025, a LiDAR survey by Eastern Washington University mapped over 5,000 mound-like features across the Channeled Scablands, employing digital elevation models to analyze sorting patterns in sediment distribution and elevation variability.^[17] Preliminary findings from this geospatial analysis, including a May 2025 comparative study of eastern and western Washington mounds, suggest a hybrid bio-geological formation process, where biological activity amplifies initial geological sorting from post-glacial floods. As of October 2025, syntheses in media outlets continued to emphasize the gopher hypothesis while noting unresolved aspects of mound evolution.^[30]^[31] Current debates center on integrating climate change effects, such as increased erosion from altered precipitation patterns, into mound evolution models, with researchers advocating for interdisciplinary approaches that combine GIS mapping, ecological monitoring, and predictive simulations to assess long-term stability.^[27] These discussions emphasize the urgency of such models amid observed vegetation shifts and soil degradation in prairie remnants.

Conservation and Ecological Significance

Protected Sites and Management

The Mima Mounds Natural Area Preserve in Thurston County, Washington, established in 1976, spans 756 acres (306 hectares) and serves as a primary protected site for these landforms, encompassing grassland-covered mounds, oak woodlands, and forests. Managed by the Washington Department of Natural Resources (WA DNR), the preserve focuses on prairie restoration through habitat enhancement and native species propagation to counteract historical losses. Similar protections exist in the Channeled Scablands region of eastern Washington, where Mima-like mounds occur on public lands. Mima-like mounds also appear in the Snake River Plain in Idaho, administered by the U.S. Bureau of Land Management (BLM), emphasizing preservation of arid grassland ecosystems.^[32]^[33] Management strategies at these sites address key threats including invasive species encroachment and habitat degradation from succession. Efforts include targeted removal of invasives such as Scotch broom (Cytisus scoparius) and non-native grasses, which outcompete native prairie flora. Prescribed burns, conducted periodically by WA DNR, mimic historical fire regimes to maintain open grasslands and reduce woody overgrowth, typically lasting 30 minutes to minimize impact. Trail systems, featuring a 0.5-mile paved ADA-accessible loop and additional gravel paths, direct visitor traffic to prevent soil compaction and erosion on the fragile mounds.^[34]^[35] Mima mounds are recognized as globally rare landforms, with associated prairie ecosystems ranked as critically imperiled (S1) in Washington under NatureServe assessments due to extensive historical conversion and ongoing fragmentation. In Washington, these grasslands hold state ranks of S1 (critically imperiled), reflecting fewer than six viable occurrences and over 90% habitat loss. Federal involvement through the BLM supports management of mound sites in the southwestern U.S., including monitoring and restoration on public lands to protect against development and grazing pressures.^[36]^[33] The preserve reopened to the public on October 6, 2025, following maintenance, with interpretive signage highlighting the mounds' geological fragility and susceptibility to disturbance to enhance visitor education. Broader climate monitoring programs by WA DNR track changes from rising temperatures and altered precipitation patterns, informing general adaptive management strategies.^[32]^[37]

Biodiversity and Environmental Role

Mima mounds provide critical habitat for a diverse array of prairie species, supporting over 160 native vascular plants documented across South Puget Sound prairies, including those on mound landscapes. This topographic heterogeneity fosters varied microclimates, enabling distinct vegetation patterns such as denser grass cover on mound tops and wetter conditions in intervening swales, which enhance overall biodiversity.^[38] Endangered insects, notably the Taylor's checkerspot butterfly (Euphydryas editha taylori), rely on these habitats for larval host plants like harsh paintbrush (Castilleja hispida) and meadow checkermallow (Sidalcea campestris), with mound prairies serving as key refugia amid habitat fragmentation. In 2025, recovery efforts included the release of over 1,200 post-diapause larvae into South Puget Sound prairie sites to bolster populations.^[39]^[40] The vernal pools embedded within Mima mound complexes play a vital hydrological role in prairie ecosystems, capturing seasonal rainfall to facilitate groundwater recharge through slow infiltration into underlying glacial outwash soils.^[41] These pools also contribute to flood mitigation by temporarily storing excess water from winter storms, reducing downstream runoff and erosion in the flat, low-permeability landscapes of the Puget Lowlands.^[42] Mound soils accumulate and store significant organic carbon, including remnants from post-glacial deposits dating back over 14,000 years, with bulk soil organic matter reaching approximately 20% in some profiles.^[6] This carbon sequestration, estimated at 50–100 tons per hectare in comparable prairie soils, bolsters ecosystem resilience against drought by maintaining soil structure and moisture retention.^[43] These ecological functions face severe threats from historical and ongoing environmental changes. Agricultural conversion has led to approximately 90% loss of native South Puget Sound prairies since the mid-19th century, exacerbating soil erosion on exposed mounds and degrading habitat connectivity.^[44] Additionally, projected sea-level rise of 0.6 meters by 2100 in the Puget Sound region endangers low-elevation mound sites through increased salinity intrusion and inundation, potentially altering vernal pool hydrology and species composition.^[45]

References

[1]
How Researchers' Backgrounds Have Shaped the Mima Mound ...
Berg (1990) proposed that earthquakes mobilized loose sediment into concentrated heaps, forming mounds. Though the hypothesis has not been further developed in ...
[2]
The Origin of the Mima Mounds of Western Washington
The Mima mounds are formed by pocket gophers (Thomomys talpoides) over long periods of time. Gopher activity in any particular place destined to become a mound ...Missing: explanation | Show results with:explanation
[3]
https://doi.org/10.1016/j.geomorph.2013.09.018
[4]
[PDF] MIMA MOUNDS - WA DNR
It has weak granular or blocky structure and is medium acid or strongly acid. The Bw horizon has value of 4 or 5 dry and 3 or 4 moist. It is very gravelly sandy ...
[5]
[PDF] The Age and Origin of Soil Mounds on Manastash Ridge in Kittitas ...
Soil mounds located on Manastash Ridge, in Kittitas County, share similar shapes and compositions to those found elsewhere on the Columbia Plateau (Kaatz, ...
[6]
[PDF] Are mima-like mounds the consequence of long-term stability of ...
The origins of large (N5 m diameter, N1 m height) and regularly spaced (i.e. over-dispersed) non-anthropogenic earth mounds (e.g. mima mounds, heuweltjies, ...
[7]
[PDF] Overview of concepts, definitions, and principles of soil mound studies
Most vernal pools in Pacific Coast states occur where slopes are low and drainage restricted, often by the presence of Mima- type mounds. Larger vernal ponds ...
[8]
[PDF] Community Planning and Economic Development - Amazon S3
Lupinus polyphyllus large-leaf lupine. Mid-May to mid-Jul June - September ... Mima mounds present? Yes or No. Surveyor(s):. Oaks (Quercus garryana ) ...
[9]
[PDF] A Model for the Origin and Persistence of Mima Mound—Vernal ...
Vernal pools are seasonal wetlands that harbor rare and endemic plants and animals. In. California, vernal pools are often associated with Mima mounds, roughly ...
[10]
Mima Mounds Illustrations - University of Washington
Their density ranges from 17-30 per acre, for a what was once a total of perhaps 900,000 mounds. They are round or elliptical in plan, with a profile of a ...Missing: square | Show results with:square
[11]
The Distribution and Origin of Mima Mound Grasslands in San ... - jstor
The distribution of mound fields in San Diego County corresponds closely to the distribution of original valley grassland inferred for a 10-yr fire cycle. It is ...
[12]
Relict nebkhas (pimple mounds) record prolonged late Holocene ...
These mounds have been variously referred to in the literature as pimple mounds, prairie mounds, and Mima mounds (in reference to superficially similar mounds ...
[13]
[PDF] Vernal Pool Landscapes of Baja California, México - Chico State
Sensitive plant species associated with Baja California vernal pools. ... Based on the presence of mima mounds adjacent to the houses on two sides, we ...
[14]
Mima-type mounds in southwest Missouri: Expressions of point ...
Mima-type mounds, formed in gravelly soils of the Diamond Grove Prairie Natural Area near Joplin, Missouri, are the focus of this study.
[15]
'Mima mounds' mystery in eastern part of state - The Oklahoman
Aug 19, 2002 · "Mima mounds" are located only in a couple of eastern Oklahoma counties (Haskell and LeFlore) and nowhere else in the state.
[16]
Prairie Mounds? - Arkansas Archeological Survey
Prairie mounds and human-made mounds vary in their internal composition. People constructed mounds by bringing individual baskets full of soil and dumping ...Missing: dimensions | Show results with:dimensions
[17]
An Examination of Washington's Mima Mounds Through LiDAR ...
A study of Mima Mounds and Mima-like mounds which are common to the Scabland areas of Washington and Northern Oregon.
[18]
Implications of Subfossil Coleoptera for the Evolution of the Mima ...
These results suggest the past presence of fossorial rodents (probably pocket gophers,Thomomys mazama) in the mounds, although none live there at present.Missing: fossil | Show results with:fossil
[19]
Mima Mound Mystery Solved | Science | AAAS
Dec 20, 2013 · It turns out that pocket gophers tend to push their burrow tailings uphill rather than downhill despite the extra effort required. So Gabet and ...
[20]
Will we ever solve the mystery of the Mima mounds?
Apr 9, 2024 · R. C. Newcomb of the U.S. Geological Survey hypothesized in 1940 that the mounds were caused by frost polygons—a phenomenon where ice fills ...
[21]
Formation of Mima mounds: A seismic hypothesis - GeoScienceWorld
Jun 2, 2017 · Most Mima mounds formed as the result of seismic activity in conjunction with unconsolidated fine sediments on a relatively rigid planar substratum.
[22]
[PDF] Earthquake-Induced Liquefaction - Features in the Coastal Setting of ...
Mima Mounds ....................................................... 34. Load ... B, View showing detailed layering in sill. C, Very close view showing ...
[23]
[PDF] How much surface water can gilgai microtopography capture?
Apr 1, 2014 · Height difference within a gilgai is 10–50 cm generally but can range vertically from a few cm to 3 m (Miller and Bragg, 2007; Kovda et al., ...Missing: rise | Show results with:rise
[24]
https://dnr.wa.gov/publications/amp_mima_mounds_mistery.pdf
[25]
[PDF] Mima Mounds: The Mysterious Work of Nature - WA DNR
The gophers began to dig nest chambers, but encountered the dense layer of glacial debris beneath the soil. They moved soil and pebbles upward, forming a mound.
[26]
[PDF] Glaciation of the Puo~et ound - WA DNR
An Area of Typical Mounds on Mima Prairie.... . .... . . . . 96. IX. Fig ... • Bailey Willis, Bul. Geo!. Soc. Am., Vol. 9, 1897. Page 217. 19. Bulletin No ...
[27]
Origin of the Mima Mounds, Thurston County region, Washington
The gopher theory, as it has been applied to the Mima mounds, contains internal disharmonies and ignores significant field evidence supporting the earlier idea.Missing: Bretz Schmitt 1942
[28]
[PDF] How Researchers' Backgrounds Have Shaped the Mima Mound ...
Found in the Puget Lowland of Washington State, USA, Mima mounds have baffled geologic thought for over a century (Fig. 1).
[29]
Using LIDAR to model Mima mound evolution and regional energy ...
Oct 1, 2012 · Our results indicate that gophers have ample energy to build typical Mima mounds in as little as 100 years, thus strongly supporting a biotic ...
[30]
Biotic origin for Mima mounds supported by numerical modeling
Aug 6, 2025 · A similar process ('cannibalization') has been reported for pocket gopher mounds (Gabet et al., 2014) . Three to ten entrance holes are ...
[31]
Mima Mounds Natural Area Preserve - WA DNR
The NAP currently comprises 756 acres of grassland covered mima mounds, forest and oak woodland. In 1966, the National Park Service designated Mima Mounds ...Missing: total | Show results with:total
[32]
[PDF] survey of pygmy rabbit distribution - Bureau of Land Management
Very recognizable sagebrush-covered Mima mounds are dotted in a regular pattern over large portions of the study area (Figure 2). Local BLM personnel and ...<|control11|><|separator|>
[33]
Mima Mounds — Washington Trails Association
Rating 2.9 (15) These mysterious mounds inspire imagination and speculation among visitors. With a half-mile ADA accessible path and another two miles of more rugged wandering.Missing: Peak | Show results with:Peak
[34]
Mima Mounds Natural Area Preserve Trail - BaldHiker
Prescribed burns generally last about 30 minutes and are used to eliminate invasive species of plants like Scotch broom. Additionally, native Prairie oak trees ...
[35]
Sporobolus silveanus - Carex meadii Grassland
Mima mounds are small circular hills which are often more than 1 m in height ... Conservation Status. Global Status: G1. Global Status Last Reviewed: 12 ...
[36]
[PDF] Conservation Status Ranks of Washington's Ecological Systems
Conservation status ranks indicate the rarity and risk of elimination of ecosystems, helping to prioritize conservation actions.
[37]
NHP Climate Change | Department of Natural Resources - WA DNR
Assessing the Climate Change Vulnerability of Washington's Wetlands. Washington Natural Heritage Program Report Number: 2025-03. Prepared for U.S. Environmental ...Nhp Climate Change · Assessing Species... · Assessing Natural Areas...Missing: visitor | Show results with:visitor
[38]
Forest Resilience Division | Department of Natural Resources
The Climate Resilience Plan highlights actions DNR can take in response to projections that suggest Washington will experience increased temperatures and ...Growing Healthy Forests In... · Assistance And Information · Forest Health And Resilience...
[39]
Vegetation of the Mima Mounds, Washington State - jstor
Mounds alter drainage and insolation to create moisture gradients to which all species respond. The largest scale involves the shift of species distributions ...<|control11|><|separator|>
[40]
Listing Taylor's Checkerspot Butterfly and Streaked Horned Lark and ...
Oct 11, 2012 · We, the U.S. Fish and Wildlife Service, propose to list the Taylor's checkerspot butterfly as an endangered species, and to list the streaked ...
[41]
[PDF] Hydrology of Vernal Pools at Three Sites, Southern Sacramento Valley
Apr 22, 2005 · Many claims have been made for the utility of vernal pools in water quality improvement and ground water recharge. Understanding the hydrology ...Missing: benefits | Show results with:benefits
[42]
[PDF] Report of Science Advisors - San Francisco Estuary Institute
state, result in “mima mounds” and vernal pools. ... Decreases in infiltration affect ground water recharge with subsequent effects on base ... ecological benefits ...
[43]
[PDF] INFLUENCES ON SOIL ORGANIC CARBON IN SOUTHWEST ...
Jun 9, 2023 · This study found that soil organic carbon levels were highest in Puget Lowlands Prairie soils, surprisingly, rather than forest soil types.
[44]
Conservation of Prairies in Western Washington
Prairies are one of the rarest ecosystems in Washington. Less than ten percent of historic prairie in the South Sound region remains today.
[45]
Coastal Resilience in Puget Sound - The Nature Conservancy
In western Washington, we've been seeing bigger floods and storms in the last couple of decades. By 2100, sea level will rise 24 inches in Puget Sound. Big ...