Your search keyword '"Badgley, Catherine"' showing total 7 results

1. Coupled influence of tectonics, climate, and surface processes on landscape evolution in southwestern North America.

Author

Bahadori, Alireza, Holt, William E., Feng, Ran, Austermann, Jacqueline, Loughney, Katharine M., Salles, Tristan, Moresi, Louis, Beucher, Romain, Lu, Neng, Flesch, Lucy M., Calvelage, Christopher M., Rasbury, E. Troy, Davis, Daniel M., Potochnik, Andre R., Ward, W. Bruce, Hatton, Kevin, Haq, Saad S. B., Smiley, Tara M., Wooton, Kathleen M., and Badgley, Catherine

Subjects

GRAVITATIONAL potential, EOCENE Epoch, GEOLOGICAL basins, LANDSCAPES, GRAVITATIONAL collapse, STRAIN rate

Abstract

The Cenozoic landscape evolution in southwestern North America is ascribed to crustal isostasy, dynamic topography, or lithosphere tectonics, but their relative contributions remain controversial. Here we reconstruct landscape history since the late Eocene by investigating the interplay between mantle convection, lithosphere dynamics, climate, and surface processes using fully coupled four-dimensional numerical models. Our quantified depth-dependent strain rate and stress history within the lithosphere, under the influence of gravitational collapse and sub-lithospheric mantle flow, show that high gravitational potential energy of a mountain chain relative to a lower Colorado Plateau can explain extension directions and stress magnitudes in the belt of metamorphic core complexes during topographic collapse. Profound lithospheric weakening through heating and partial melting, following slab rollback, promoted this extensional collapse. Landscape evolution guided northeast drainage onto the Colorado Plateau during the late Eocene-late Oligocene, south-southwest drainage reversal during the late Oligocene-middle Miocene, and southwest drainage following the late Miocene. Cenozoic landscape evolution of southwestern North America remains debated. Here, the authors reconstruct landscape using 4-D numerical models, which can explain extensional collapse and superficial geological record for the Basin and Range Province [ABSTRACT FROM AUTHOR]

Published

2022

2. Middle Miocene fire activity and C4 vegetation expansion in the Barstow Formation, California, USA.

Author

Loughney, Katharine M., Harkness, Anna, and Badgley, Catherine

Subjects

*MIOCENE Epoch, *ENVIRONMENTAL indicators, *CHARCOAL, *GRASSLANDS, *CHEATGRASS brome

Abstract

C4 grassland ecosystems expanded across North America between ca. 8 and 3 Ma. Studies of ungulate enamel and environmental indicators from the middle Miocene Barstow Formation of southern California (USA) have demonstrated the presence of C4 vegetation prior to the late Miocene expansion of C4 grasslands. Fire promotes the growth of modern C4 grasslands and may have contributed to the Miocene expansion of C4 vegetation. We analyzed the concentration and accumulation rate (CHAR) of microscopic charred particles from sediment samples spanning the Barstow Formation in order to investigate the relationship between fire activity, canopy cover, and the presence of C4 vegetation. Concentration and CHAR were low throughout the formation then increased dramatically at 13.5 Ma. Enriched values of δ13C from soil organic matter and phytolith counts indicate the presence of C4 grasses and seasonally dry, open-canopy habitats at this time. The spike in concentration coincides with climatic cooling and drying in southern California after the Miocene Climatic Optimum. Increased fire activity may have contributed to habitat opening from forest to woodland and promoted the spread of C4 plants. This is the first charcoal record of fire activity from the middle Miocene of southwestern North America. [ABSTRACT FROM AUTHOR]

Published

2023

3. The latitudinal gradient of beta diversity in relation to climate and topography for mammals in North America.

Author

Hong Qian, Badgley, Catherine, and Fox, David L.

Subjects

*LATITUDE, *ASTRONOMICAL instruments, *NAUTICAL instruments

Abstract

Aim Spatial turnover of species, or beta diversity, varies in relation to geographical distance and environmental conditions, as well as spatial scale. We evaluated the explanatory power of distance, climate and topography on beta diversity of mammalian faunas of North America in relation to latitude. Location North America north of Mexico. Methods The study area was divided into 313 equal-area quadrats (241 × 241 km). Faunal data for all continental mammals were compiled for these quadrats, which were divided among five latitudinal zones. These zones were comparable in terms of latitudinal and longitudinal span, climatic gradients and elevational gradients. We used the natural logarithm of the Jaccard index (ln J) to measure species turnover between pairs of quadrats within each latitudinal zone. The slope of ln J in relation to distance was compared among latitudinal zones. We used partial regression to partition the variance in ln J into the components uniquely explained by distance and by environmental differences, as well as jointly by distance and environmental differences. Results Mammalian faunas of North America differ more from each other at lower latitudes than at higher latitudes. Regression models of ln J in relation to distance, climatic difference and topographic difference for each zone demonstrated that these variables have high explanatory power that diminishes with latitude. Beta diversity is higher for zones with higher mean annual temperature, lower seasonality of temperature and greater topographic complexity. For each latitudinal zone, distance and environmental differences explain a greater proportion of the variance in ln J than distance, climate or topography does separately. Main conclusions The latitudinal gradient in beta diversity of North American mammals corresponds to a macroclimatic gradient of decreasing mean annual temperature and increasing seasonality of temperature from south to north. Most of the variance in spatial turnover is explained by distance and environmental differences jointly rather than distance, climate or topography separately. The high predictive power of geographical distance, climatic conditions and topography on spatial turnover could result from the direct effects of physical limiting factors or from ecological and evolutionary processes that are also influenced by the geographical template. [ABSTRACT FROM AUTHOR]

Published

2009

4. Ecological biography of North American mammals: species density and ecological structure in relation to environmental gradients.

Author

Badgley, Catherine and Fox, David L.

Subjects

*GEOMORPHOLOGY, *CLIMATOLOGY, *BIODIVERSITY, *MAMMALS

Abstract

Investigates the relationship of climate and physiography on the density and ecological diversity of mammals in North America. Percentage of environmental variables representing the entire continent; Variance in the environmental variables of predicted species density; Implication of changes in the size and trophic structure of mammalian fauna on species density.

Published

2000

5. Tectonic extension and paleoelevation influence mammalian diversity dynamics in the Basin and Range Province of western North America.

Author

Smiley, Tara M., Bahadori, Alireza, Rasbury, E. Troy, Holt, William E., and Badgley, Catherine

Subjects

*MAMMAL diversity, *SPECIES diversity, *STRAIN rate, *FOSSILS, *LANDSCAPE changes, *GEOLOGIC hot spots

Abstract

Landscape properties have a profound influence on the diversity and distribution of biota, with present-day bio-diversity hot spots occurring in topographically complex regions globally. Complex topography is created by tectonic processes and further shaped by interactions between climate and land-surface processes. These processes enrich diversity at the regional scale by promoting speciation and accommodating increased species richness along strong environmental gradients. Synthesis of the mammalian fossil record and a geophysical model of topographic evolution of the Basin and Range Province in western North America enable us to directly quantify relationships between mammal diversity and landscape dynamics over the past 30 million years. We analyze the covariation between tectonic history (extensional strain rates, paleotopography, and ruggedness), global temperature, and diversity dynamics. Mammal species richness and turnover exhibit stronger responses to rates of change in landscape properties than to the specific properties themselves, with peaks in diversity coinciding with high tectonic strain rates and large changes in elevation across spatial scales. [ABSTRACT FROM AUTHOR]

Published

2024

6. On the role of tectonics in stimulating the Cretaceous diversification of mammals.

Author

Weaver, Lucas N., Kelson, Julia R., Holder, Robert M., Niemi, Nathan A., and Badgley, Catherine

Subjects

*PALEONTOLOGICAL excavations, *CRETACEOUS-Paleogene boundary, *MAMMAL diversity, *OROGENIC belts, *SPECIES diversity, *PALEOGENE, *TAPHONOMY

Abstract

Mammals rose to prominence in terrestrial ecosystems after the Cretaceous–Paleogene mass extinction, but the mammalian lineages characteristic of Paleogene faunas began their evolutionary and ecological diversification in the Late Cretaceous, stimulated by the rise of angiosperms (flowering plants) according to the preeminent hypothesis. The Cretaceous rise of mammals is part of a larger expansion in biodiversity on land that has been termed the Cretaceous (or Angiosperm) Terrestrial Revolution, but the mechanisms underlying its initiation remain opaque. Here, we review data from the fossil and rock records of western North America—due to its relatively continuous fossil record and complete chronology of mountain-building events—to explore the role that tectonism might have played in catalyzing the rise of modern-aspect terrestrial biodiversity, especially that of mammals and angiosperms. We highlight that accelerated increases in mammal and angiosperm species richness in the Late Cretaceous, ca. 100–75 Ma, track the acceleration of tectonic processes that formed the North American Cordillera and occurred during the 'middle-Cretaceous greenhouse' climate. This rapid increase in both mammal and angiosperm diversity also occurred during the zenith of Western Interior Seaway transgression, a period when the availability of lowland habitats was at its minimum, and oscillatory transgression-regression cycles would have frequently forced upland range shifts among lowland populations. These changes to both landscapes and climates have all been linked to an abrupt, global tectonic-plate 'reorganization' that occurred ca. 100 Ma. That mammals and angiosperms both increased in species richness during this interval does not appear to be a taphonomic artifact—some of the largest spikes in diversity occur when the available mammal-bearing fossil localities are sparse. Noting that mountainous regions are engines for generating biodiversity, especially in warm climates, we propose that the Cretaceous/Angiosperm Terrestrial Revolution was ultimately catalyzed by accelerated tectonism and enhanced via cascading changes to landscapes and climate. In the fossil record of individual basins across western North America, we predict that (1) increases in mammalian diversity through the Late Cretaceous should be positively correlated with rates of tectonic uplift, which we infer to be a proxy for topographic relief, and are attended by increased climate heterogeneity, (2) the diversity of mountain-proximal mammalian assemblages should exceed that of coeval mountain-distal assemblages, especially in the latest Cretaceous, and (3) endemism should increase from the latest Cretaceous to early Paleogene as Laramide mountain belts fragmented the Western Interior. Empirical tests of these predictions will require increased fossil collecting in under-sampled regions and time intervals, description and systematic study of existing collections, and basin-scale integration of geological and paleontological data. Testing these predictions will further our understanding of the coevolutionary processes linking tectonics, climate, and life throughout Earth history. [ABSTRACT FROM AUTHOR]

Published

2024

7. Diversity dynamics of Miocene mammals in relation to the history of tectonism and climate.

Author

Finarelli JA and Badgley C

Subjects

Animals, Extinction, Biological, Fossils, Genetic Speciation, History, Ancient, North America, Population Dynamics, Biodiversity, Climate Change history, Geography history, Mammals

Abstract

Continental biodiversity gradients result not only from ecological processes, but also from evolutionary and geohistorical processes involving biotic turnover in landscape and climatic history over millions of years. Here, we investigate the evolutionary and historical contributions to the gradient of increasing species richness with topographic complexity. We analysed a dataset of 418 fossil rodent species from western North America spanning 25 to 5 Ma. We compared diversification histories between tectonically active (Intermontane West) and quiescent (Great Plains) regions. Although diversification histories differed between the two regions, species richness, origination rate and extinction rate per million years were not systematically different over the 20 Myr interval. In the tectonically active region, the greatest increase in originations coincided with a Middle Miocene episode of intensified tectonic activity and global warming. During subsequent global cooling, species richness declined in the montane region and increased on the Great Plains. These results suggest that interactions between tectonic activity and climate change stimulate diversification in mammals. The elevational diversity gradient characteristic of modern mammalian faunas was not a persistent feature over geologic time. Rather, the Miocene rodent record suggests that the elevational diversity gradient is a transient feature arising during particular episodes of Earth's history.

Published

2010