Your search keyword '"jemez mountains"' showing total 16 results

1. Predicting species-level vegetation cover using large satellite imagery data sets

Author

Scharf, Henry, Schierbaum, Jonathan, Matsumoto, Hana, and Assal, Tim

Published

2024

2. ENERGY-DISPERSIVE X-RAY FLOURESCENCE (EDXRF) ANALYSIS OF MAJOR, MINOR AND TRACE ELEMENTS FOR VOLCANIC ROCKS FROM THE JEMEZ MOUNTAINS, NORTHERN NEW MEXICO

Author

Shackley, M. Steven

Subjects

composition of volcanic rocks, Jemez Mountains, New Mexico

Abstract

The analysis here of 22 volcanic rock samples indicates a diverse set of volcanic rock types (Table 1, Figures 1 through 2).  The obsidian nodules collected from Turkey Ridge rhyolite on the NW side of Cerro Rubio are most definitely derived from the Cerro Toledo Rhyolite (CTR) event based on comparison with a large body of CTR source standards from Rabbit Mountain and the ash flow tuff to the south including "Obsidian Ridge" (see Shackley 2005; Table 2 and 3 and Figure 2 herein).  Using XRF the composition is well within those standards (see Table 2 and Figures 2 and 3).

Published

2020

3. The source provenance of an obsidian Eden point from Sierra County, New Mexico

Author

Shackley, M. [Geoarchaeological XRF Lab., Albuquerque, NM (United States)]

Published

2016

4. Predicting wildfire impacts on the prehistoric archaeological record of the Jemez Mountains, New Mexico, USA.

Author

Friggens, Megan M., Loehman, Rachel A., Constan, Connie I., and Kneifel, Rebekah R.

Subjects

FIRE management, WILDFIRE prevention, FOREST fires, RANDOM forest algorithms, WILDFIRES, ARCHAEOLOGICAL excavations, CLIMATE change, CULTURAL property

Abstract

Copyright of Fire Ecology is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

5. ARCYRIA VERSICOLOR OF WESTERN MOUNTAINS, U.S.A. (MYXOMYCETES: TRICHIALES: TRICHIACEAE): A MORPHOLOGICAL AND TAXONOMIC STUDY WITH OBSERVATIONS OF NIVICOLOUS SPECIES.

Author

Keller, Harold W., Stone, Billy G., Price, Relf L., and Forrester, Edward D.

Subjects

*MYXOMYCETES, *SPECIES, *SCANNING electron microscopy, *MICROSCOPY, *MOUNTAINS

Abstract

Arcyria versicolor (Trichiales: Trichiaceae) is a distinct myxomycete species described by William Phillips in 1877. The genus Arcyria dates back to Linnaeus in 1753 through the species A. denudata. Arcyria sporangia are brightly colored red, yellow, grey or white, mostly stalked, often in large groups easily seen with the naked eye. Approximately 54 species are known, many are common, and distributed worldwide. Collectors often encounter these colorful species on decaying logs as clusters of many sporangia often covering extensive areas. Arcyria versicolor, collected in the Valles Caldera National Preserve located in the Jemez Mountains of north central New Mexico, is a new record for the state. The nomenclatural history of this species is reviewed and the justification for selection of the species name versicolor is discussed. Arcyria versicolor is accepted as the valid species name and A. vitellina a synonym after examination of type specimens. Environmental parameters for coloration are discussed in general for fruiting bodies of Arcyria and more specifically for nivicolous snowbank species. Transitional stages of plasmodial color to mature fruiting body formation are described for Arcyria versicolor. More than 140 specimens of Arcyria versicolor fruiting bodies were examined with light microscopy and in part illustrated with multifocal computer stacked imaging. Higher magnifications were highlighted using scanning electron microscopy. A more complete and accurate species description is provided for Arcyria versicolor. Differences of fruiting body morphology including habit, color, dehiscence, peridial inner and outer surface features, capillitial ornamentation and size, spore color, size, and ornamentation, and stalk spore-like bodies are described and illustrated. Observation of type specimens from the type locality is illustrated, discussed, and nomenclatural evaluation given for the name selected. Mountain myxomycetes are reviewed based on the observations of T.H. Macbride and his early 1914 paper published in Mycologia. Collection data is presented that compares the dark-spored and light spored nivicolous myxomycetes in the French Alps. The history of renown collectors of nivicolous myxomycetes in western mountains of U.S.A. documents the discovery and study of this special ecological group of myxomycetes. This current paper is the first in a series from an ongoing research project entitled Myxomycetes of New Mexico. [ABSTRACT FROM AUTHOR]

Published

2020

6. NITROGEN CAN LIMIT OVERSTORY TREE GROWTH FOLLOWING EXTREME STAND DENSITY INCREASE IN A PONDEROSA PINE FOREST.

Author

MARSHALL, L.A., FALK, DONALD A., and MCDOWELL, NATE G.

Subjects

TREE growth, NITROGEN, PONDEROSA pine, TREE-rings, CARBON isotopes, FOREST ecology

Abstract

Extreme stand density increases have occurred in ponderosa pine forests throughout the western U.S. since the early 20th Century, with adverse implications for growth, physiological functioning, and mortality risk. Identifying primary stressors on large, old overstory trees in dense forests can informmanagement decisions to promote resilience and survival.We tested the impact of stand density increase on overstory tree-ring growth, and the relative influence of water and nitrogen, in an old-growth ponderosa pine forest in northern New Mexico subject to variable density increase. We measured annual tree-ring growth and carbon discrimination in trees before stand density increased, in a climatically-similar period post-density increase, and in recent transition to drought. We expected density-driven water stress to drive reduced tree-ring growth in overstory trees in dense stands.We found reduced growth and higher mortality in dense stands, but nitrogen rather than water constrained growth, as determined by carbon isotope discrimination in tree rings, leaf nitrogen concentration, and soil nitrogen supply. In dense stands, less available nitrogen limited photosynthetic rate, leading to reduced assimilation of intracellular 13C and higher discrimination with low tree-ring growth and a reduced relationship with climate. This unexpected result illustrates that a variety of limiting factors can influence forest dynamics, as density-driven nitrogen limitation interacts with water stress to influence tree growth and physiological functioning. [ABSTRACT FROM AUTHOR]

Published

2019

7. Mapping Tree Density in Forests of the Southwestern USA Using Landsat 8 Data.

Author

Humagain, Kamal, Portillo-Quintero, Carlos, Cox, Robert D., and Cain III, James W.

Subjects

FOREST density, FOREST mapping, LANDSAT satellites, FOREST ecology, FOREST restoration, FOREST fires

Abstract

The increase of tree density in forests of the American Southwest promotes extreme fire events, understory biodiversity losses, and degraded habitat conditions for many wildlife species. To ameliorate these changes, managers and scientists have begun planning treatments aimed at reducing fuels and increasing understory biodiversity. However, spatial variability in tree density across the landscape is not well-characterized, and if better known, could greatly influence planning efforts. We used reflectance values from individual Landsat 8 bands (bands 2, 3, 4, 5, 6, and 7) and calculated vegetation indices (difference vegetation index, simple ratios, and normalized vegetation indices) to estimate tree density in an area planned for treatment in the Jemez Mountains, New Mexico, characterized by multiple vegetation types and a complex topography. Because different vegetation types have different spectral signatures, we derived models with multiple predictor variables for each vegetation type, rather than using a single model for the entire project area, and compared the model-derived values to values collected from on-the-ground transects. Among conifer-dominated areas (73% of the project area), the best models (as determined by corrected Akaike Information Criteria (AICc)) included Landsat bands 2, 3, 4, and 7 along with simple ratios, normalized vegetation indices, and the difference vegetation index (R2 values for ponderosa: 0.47, piñon-juniper: 0.52, and spruce-fir: 0.66). On the other hand, in aspen-dominated areas (9% of the project area), the best model included individual bands 4 and 2, simple ratio, and normalized vegetation index (R2 value: 0.97). Most areas dominated by ponderosa, pinyon-juniper, or spruce-fir had more than 100 trees per hectare. About 54% of the study area has medium to high density of trees (100-1000 trees/hectare), and a small fraction (4.5%) of the area has very high density (>1000 trees/hectare). Our results provide a better understanding of tree density for identifying areas in need of treatment and planning for more effective treatment. Our analysis also provides an integrated method of estimating tree density across complex landscapes that could be useful for further restoration planning. [ABSTRACT FROM AUTHOR]

Published

2017

8. Overstory Tree Mortality in Ponderosa Pine and Spruce-Fir Ecosystems Following a Drought in Northern New Mexico.

Author

Oswald, Brian P., Dugan, Sean C., Balice, Randy G., and Unger, Daniel R.

Subjects

PONDEROSA pine, DROUGHTS, SPRUCE, CLIMATE change, ECOSYSTEMS

Abstract

Drought-caused tree dieback is an issue around the world as climates change and many areas become dryer and hotter. A drought from 1998-2004 resulted in a significant tree dieback event in many of the wooded areas in portions of the Jemez Mountains and the adjacent Pajarito Plateau in northern New Mexico. The objectives of this study were to evaluate and quantify the differences in tree mortality before and after a recent drought in ponderosa pine and spruce-fir ecosystems, and to assess the effect of mechanical thinning on ponderosa pine mortality. Significant increases in mortality were observed in the unthinned ponderosa pine ecosystem. Mortality varied significantly between species and within size classes. Mechanical thinning of ponderosa pines reduced overstory mortality to non-significant levels. A lack of rainfall, snowfall, and increases in daily minimum temperature contributed most to the mortality. Adaptive management, including the use of thinning activities, appear to moderate the impact of climate change on ponderosa pine forests in this region, increasing the long-term health of the ecosystem. The impact of climate change on the spruce-fir ecosystems may accelerate successional changes. [ABSTRACT FROM AUTHOR]

Published

2016

9. EVALUATING THE EFFECTS OF CATASTROPHIC WILDFIRE ON WATER QUALITY, WHOLE-STREAM METABOLISM AND FISH COMMUNITIES

Author

Clifford Dahm, David Van Horn, Thomas Turner, Ricardo González-Pinźon, Reale, Justin K, Clifford Dahm, David Van Horn, Thomas Turner, Ricardo González-Pinźon, and Reale, Justin K

Subjects

Rio Grande

Abstract

This dissertation investigated the initial and multi-year effects of a catastrophic wildfire (Las Conchas fire in 2011) on adjacent and downstream aquatic ecosystems in comparison to pre-fire conditions. Specifically, the research looked at 1) multi-year water quality responses along the river continuum using data collected before, immediately after and for multiple years post-fire, 2) differential water quality and whole-stream metabolism responses of paired headwater catchments over multiple years after disturbance, and 3) fish communities at two sites on a larger river downstream of the extensive region impacted by the catastrophic wildfire.Overall, the research in this dissertation highlights the importance of long-term ecological data collection using advanced instrumentation that can be used to evaluate the effects of a changing climate and climate-mediated disturbances on water resources. Secondly, these studies emphasize the need to collect water quality and biological data at temporal and spatial scales that more effectively capture the hydrology and water quality dynamics of landscape-scale disturbances that are becoming more common and more destructive with climate change and growing human impingement on forested lands. Thirdly, this research highlights the importance of evaluating streamflow pathways, geomorphology, physiochemical properties with biogeochemical processes, and watershed-specific hydrologic connections within their landscapes prior to and following landscape-scale disturbance.

Published

2018

10. Mapping Tree Density in Forests of the Southwestern USA Using Landsat 8 Data

Author

Robert D. Cox, Carlos Portillo-Quintero, James W. Cain, and Kamal Humagain

Subjects

0106 biological sciences, Landsat 8, restoration, 010504 meteorology & atmospheric sciences, Biodiversity, fire suppression, tree density, wildfire, Jemez mountains, 010603 evolutionary biology, 01 natural sciences, Vegetation type, Transect, Hectare, 0105 earth and related environmental sciences, Ecology, Forestry, Enhanced vegetation index, Understory, Vegetation, lcsh:QK900-989, lcsh:Plant ecology, Environmental science, Spatial variability, Physical geography

Abstract

The increase of tree density in forests of the American Southwest promotes extreme fire events, understory biodiversity losses, and degraded habitat conditions for many wildlife species. To ameliorate these changes, managers and scientists have begun planning treatments aimed at reducing fuels and increasing understory biodiversity. However, spatial variability in tree density across the landscape is not well-characterized, and if better known, could greatly influence planning efforts. We used reflectance values from individual Landsat 8 bands (bands 2, 3, 4, 5, 6, and 7) and calculated vegetation indices (difference vegetation index, simple ratios, and normalized vegetation indices) to estimate tree density in an area planned for treatment in the Jemez Mountains, New Mexico, characterized by multiple vegetation types and a complex topography. Because different vegetation types have different spectral signatures, we derived models with multiple predictor variables for each vegetation type, rather than using a single model for the entire project area, and compared the model-derived values to values collected from on-the-ground transects. Among conifer-dominated areas (73% of the project area), the best models (as determined by corrected Akaike Information Criteria (AICc)) included Landsat bands 2, 3, 4, and 7 along with simple ratios, normalized vegetation indices, and the difference vegetation index (R2 values for ponderosa: 0.47, piñon-juniper: 0.52, and spruce-fir: 0.66). On the other hand, in aspen-dominated areas (9% of the project area), the best model included individual bands 4 and 2, simple ratio, and normalized vegetation index (R2 value: 0.97). Most areas dominated by ponderosa, pinyon-juniper, or spruce-fir had more than 100 trees per hectare. About 54% of the study area has medium to high density of trees (100–1000 trees/hectare), and a small fraction (4.5%) of the area has very high density (>1000 trees/hectare). Our results provide a better understanding of tree density for identifying areas in need of treatment and planning for more effective treatment. Our analysis also provides an integrated method of estimating tree density across complex landscapes that could be useful for further restoration planning.

Published

2017

11. Ground-Dwelling Arthropod Community Responses to Recent and Repeated Wildfires in Conifer Forests of Northern New Mexico, USA

Author

Scott Ferrenberg, Philipp Wickey, and Jonathan D. Coop

Subjects

0106 biological sciences, Metacommunity, 010504 meteorology & atmospheric sciences, ground-dwelling community, Biodiversity, arthropods, 010603 evolutionary biology, 01 natural sciences, Basal area, litter, reburn, duff, jemez mountains, 0105 earth and related environmental sciences, Ecology, las conchas fire, Community structure, Forestry, lcsh:QK900-989, Understory, cerro grande fire, understory vegetation, Geography, bandelier national monument, Disturbance (ecology), lcsh:Plant ecology, Biological dispersal, Coarse woody debris

Abstract

The increasing frequency and severity of wildfires in semi-arid conifer forests as a result of global change pressures has raised concern over potential impacts on biodiversity. Ground-dwelling arthropod communities represent a substantial portion of diversity in conifer forests, and could be particularly impacted by wildfires. In addition to direct mortality, wildfires can affect ground-dwelling arthropods by altering understory characteristics and associated deterministic community assembly processes (e.g., environmental sorting). Alternatively, disturbances have been reported to increase the importance of stochastic community assembly processes (e.g., probabilistic dispersal and colonization rates). Utilizing pitfall traps to capture ground-dwelling arthropods within forest stands that were burned by one or two wildfires since 1996 in the Jemez Mountains of northern New Mexico, United States (USA), we examined the potential influences of deterministic versus stochastic processes on the assembly of these diverse understory communities. Based on family-level and genera-level arthropod identifications, we found that the multivariate community structures differed among the four fire groups surveyed, and were significantly influenced by the quantities of duff, litter, and coarse woody debris, in addition to tree basal area and graminoid cover. Taxon diversity was positively related to duff quantities, while taxon turnover was positively linked to exposed-rock cover and the number of logs on the ground. Despite the significant effects of these understory properties on the arthropod community structure, a combination of null modeling and metacommunity analysis revealed that both deterministic and stochastic processes shape the ground-dwelling arthropod communities in this system. However, the relative influence of these processes as a function of time since the wildfires or the number of recent wildfires was not generalizable across the fire groups. Given that different assembly processes shaped arthropod communities among locations that had experienced similar disturbances over time, increased efforts to understand the processes governing arthropod community assembly following disturbance is required in this wildfire-prone landscape.

Published

2019

12. Overstory Tree Mortality in Ponderosa Pine and Spruce-Fir Ecosystems Following a Drought in Northern New Mexico

Author

Brian P. Oswald, Daniel Unger, Sean C. Dugan, and Randy G. Balice

Subjects

0106 biological sciences, aspen, Climate change, Ecological succession, 010603 evolutionary biology, 01 natural sciences, white fir, Ecosystem, Douglas-fir, succession, Jemez Mountains, Douglas fir, geography, Plateau, geography.geographical_feature_category, Thinning, Ecology, fungi, food and beverages, Forestry, lcsh:QK900-989, Snow, lcsh:Plant ecology, Environmental science, sense organs, 010606 plant biology & botany

Abstract

Drought-caused tree dieback is an issue around the world as climates change and many areas become dryer and hotter. A drought from 1998–2004 resulted in a significant tree dieback event in many of the wooded areas in portions of the Jemez Mountains and the adjacent Pajarito Plateau in northern New Mexico. The objectives of this study were to evaluate and quantify the differences in tree mortality before and after a recent drought in ponderosa pine and spruce-fir ecosystems, and to assess the effect of mechanical thinning on ponderosa pine mortality. Significant increases in mortality were observed in the unthinned ponderosa pine ecosystem. Mortality varied significantly between species and within size classes. Mechanical thinning of ponderosa pines reduced overstory mortality to non-significant levels. A lack of rainfall, snowfall, and increases in daily minimum temperature contributed most to the mortality. Adaptive management, including the use of thinning activities, appear to moderate the impact of climate change on ponderosa pine forests in this region, increasing the long-term health of the ecosystem. The impact of climate change on the spruce-fir ecosystems may accelerate successional changes.

Published

2016

13. Ground-Dwelling Arthropod Community Responses to Recent and Repeated Wildfires in Conifer Forests of Northern New Mexico, USA.

Author

Ferrenberg, Scott, Wickey, Philipp, and Coop, Jonathan D.

Subjects

WILDFIRE prevention, WILDFIRES, CONIFEROUS forests, COARSE woody debris, PITFALL traps, COMMUNITY organization, FOREST fire ecology, STOCHASTIC processes

Abstract

The increasing frequency and severity of wildfires in semi-arid conifer forests as a result of global change pressures has raised concern over potential impacts on biodiversity. Ground-dwelling arthropod communities represent a substantial portion of diversity in conifer forests, and could be particularly impacted by wildfires. In addition to direct mortality, wildfires can affect ground-dwelling arthropods by altering understory characteristics and associated deterministic community assembly processes (e.g., environmental sorting). Alternatively, disturbances have been reported to increase the importance of stochastic community assembly processes (e.g., probabilistic dispersal and colonization rates). Utilizing pitfall traps to capture ground-dwelling arthropods within forest stands that were burned by one or two wildfires since 1996 in the Jemez Mountains of northern New Mexico, United States (USA), we examined the potential influences of deterministic versus stochastic processes on the assembly of these diverse understory communities. Based on family-level and genera-level arthropod identifications, we found that the multivariate community structures differed among the four fire groups surveyed, and were significantly influenced by the quantities of duff, litter, and coarse woody debris, in addition to tree basal area and graminoid cover. Taxon diversity was positively related to duff quantities, while taxon turnover was positively linked to exposed-rock cover and the number of logs on the ground. Despite the significant effects of these understory properties on the arthropod community structure, a combination of null modeling and metacommunity analysis revealed that both deterministic and stochastic processes shape the ground-dwelling arthropod communities in this system. However, the relative influence of these processes as a function of time since the wildfires or the number of recent wildfires was not generalizable across the fire groups. Given that different assembly processes shaped arthropod communities among locations that had experienced similar disturbances over time, increased efforts to understand the processes governing arthropod community assembly following disturbance is required in this wildfire-prone landscape. [ABSTRACT FROM AUTHOR]

Published

2019

14. Terminus Ante Quem Constraint of Pueblo Occupation Periods in the Jemez Province, New Mexico

Author

Farella, Joshua and Farella, Joshua

Abstract

Using dendroecological and archaeological methods and data we investigated the temporal dynamics of forest regeneration and fire history following depopulation of four large Pueblo IV period (1300-1600) villages on the Jemez Plateau, New Mexico. With tree rings we reconstructed the timing of reforestation on village footprints after depopulation–a novel approach to terminus ante quem dating of site occupation. Our tree-ring based forest age structure and fire history chronologies enabled us to reduce by 51 to 70 years the range of previous estimates of village depopulation dates derived primarily from terminal ceramic assemblages. One of the four village sites we investigated was depopulated in 1696, two were depopulated between 1625 and 1700 CE, while the fourth village was depopulated earlier (pre 1500), but the area was likely in continued use for agriculture or other seasonal purposes until the mid-1600s. Our results indicate that the Jemez were highly influential ecological agents. Forest structure and fire regime dynamics changed greatly after the departure of most people from these landscapes after circa 1650 CE. The terminus ante quem methods that we demonstrate in the Jemez Mountains have strong potential to constrain and refine low temporal resolution chronologies of human occupation at archaeological sites within other forested ecosystems of the Southwest and elsewhere.

Published

2015

15. EVALUATING THE EFFECTS OF CATASTROPHIC WILDFIRE ON WATER QUALITY, WHOLE-STREAM METABOLISM AND FISH COMMUNITIES

Author

Reale, Justin K

Subjects

Rio Grande, Jemez Mountains, Las Conchas, river continuum, disturbance, high-frequency monitoring, Terrestrial and Aquatic Ecology

Abstract

This dissertation investigated the initial and multi-year effects of a catastrophic wildfire (Las Conchas fire in 2011) on adjacent and downstream aquatic ecosystems in comparison to pre-fire conditions. Specifically, the research looked at 1) multi-year water quality responses along the river continuum using data collected before, immediately after and for multiple years post-fire, 2) differential water quality and whole-stream metabolism responses of paired headwater catchments over multiple years after disturbance, and 3) fish communities at two sites on a larger river downstream of the extensive region impacted by the catastrophic wildfire.Overall, the research in this dissertation highlights the importance of long-term ecological data collection using advanced instrumentation that can be used to evaluate the effects of a changing climate and climate-mediated disturbances on water resources. Secondly, these studies emphasize the need to collect water quality and biological data at temporal and spatial scales that more effectively capture the hydrology and water quality dynamics of landscape-scale disturbances that are becoming more common and more destructive with climate change and growing human impingement on forested lands. Thirdly, this research highlights the importance of evaluating streamflow pathways, geomorphology, physiochemical properties with biogeochemical processes, and watershed-specific hydrologic connections within their landscapes prior to and following landscape-scale disturbance.

Published

2018

16. Geothermal influences on water quality in the Jemez River.

Author

MCGIBBON, CHRIS

Subjects

*WATER quality, *GEOTHERMAL resources, *STABLE isotopes, *AQUIFERS, *CLIMATE change

Abstract

The Valles Caldera is an ideal natural laboratory for testing multi-tracer hydrochemical models of geothermal fluid outflow and mixing in distal portions of geothermal systems. Springs with an endogenic component provide evidence of the plume, while the Jemez River provides a location for mixing of different end-member fluids. The models are of relevance for exploiting geothermal potential and understanding threats to water quality. The Valles Caldera is part of a hydrothermal system which has seen extensive study with focus on assessing geothermal potential. The outflow system, the Baca Plume, flows along the fault network in San Diego Canyon. Two pathways have been suggested for the plume, one discharging at Soda Dam and the other at Jemez springs. Questions remain about the extent of the plume and distal effects of the Valles Caldera, with current research suggesting a connection to springs across the Nacimiento Mountains. Geothermal groundwater components lead to degradation of water quality in the Jemez River, a snow melt dominated system, and associated alluvial aquifer; a problem for local stakeholders. With climate change forecasts predicting reduction in snow pack, the contributions to surface water from springs takes on greater significance. Our pilot studies and historical work have used major ion and gas chemistry, and stable isotopes to define the geothermal plume and highlight mixing of different end member fluids. Preliminary geochemical mixing models show that springs at Soda Dam and Jemez Springs do not fall along a simple binary continuum. The significant differences in hydrochemistry suggest complex fault-related flow-paths. [ABSTRACT FROM AUTHOR]

Published

2016