Your search keyword '"Sparkle L. Malone"' showing total 2 results

1. Beyond counts and averages: Relating geodiversity to dimensions of biodiversity

Author

Andrew O. Finley, John Grady, Kyla M. Dahlin, Jennifer K. Costanza, Sparkle L. Malone, Keith D. Gaddis, Sydne Record, Adam M. Wilson, Andrew M. Latimer, Scott V. Ollinger, Stephanie Pau, Martina L. Hobi, Phoebe L. Zarnetske, Quentin D. Read, and Bahn, Volker

Subjects

0106 biological sciences, breeding bird survey, Life on Land, Gamma diversity, Biodiversity, Beta diversity, Climate change, Context (language use), 010603 evolutionary biology, 01 natural sciences, Physical Geography and Environmental Geoscience, forest inventory, geodiversity, Ecology, Evolution, Behavior and Systematics, biodiversity, Global and Planetary Change, Ecology, 010604 marine biology & hydrobiology, conservation, gamma diversity, alpha diversity, 15. Life on land, Breeding bird survey, Climate Action, Geodiversity, 13. Climate action, Ecological Applications, Alpha diversity, beta diversity

Abstract

Author(s): Read, QD; Zarnetske, PL; Record, S; Dahlin, KM; Costanza, JK; Finley, AO; Gaddis, KD; Grady, JM; Hobi, ML; Latimer, AM; Malone, SL; Ollinger, SV; Pau, S; Wilson, AM | Abstract: Aim: We may be able to buffer biodiversity against the effects of ongoing climate change by prioritizing the protection of habitat with diverse physical features (high geodiversity) associated with ecological and evolutionary mechanisms that maintain high biodiversity. Nonetheless, the relationships between biodiversity and habitat vary with spatial and biological context. In this study, we compare how well habitat geodiversity (spatial variation in abiotic processes and features) and climate explain biodiversity patterns of birds and trees. We also evaluate the consistency of biodiversity–geodiversity relationships across ecoregions. Location: Contiguous USA. Time period: 2007–2016. Taxa studied: Birds and trees. Methods: We quantified geodiversity with remotely sensed data and generated biodiversity maps from the Forest Inventory and Analysis and Breeding Bird Survey datasets. We fitted multivariate regressions to alpha, beta and gamma diversity, accounting for spatial autocorrelation among Nature Conservancy ecoregions and relationships among taxonomic, phylogenetic and functional biodiversity. We fitted models including climate alone (temperature and precipitation), geodiversity alone (topography, soil and geology) and climate plus geodiversity. Results: A combination of geodiversity and climate predictor variables fitted most forms of bird and tree biodiversity with ln10% relative error. Models using geodiversity and climate performed better for local (alpha) and regional (gamma) diversity than for turnover-based (beta) diversity. Among geodiversity predictors, variability of elevation fitted biodiversity best; interestingly, topographically diverse places tended to have higher tree diversity but lower bird diversity. Main conclusions: Although climatic predictors tended to have larger individual effects than geodiversity, adding geodiversity improved climate-only models of biodiversity. Geodiversity was correlated with biodiversity more consistently than with climate across ecoregions, but models tended to have a poor fit in ecoregions held out of the training dataset. Patterns of geodiversity could help to prioritize conservation efforts within ecoregions. However, we need to understand the underlying mechanisms more fully before we can build models transferable across ecoregions.

Published

2020

2. Towards connecting biodiversity and geodiversity across scales with satellite remote sensing

Author

Jennifer K. Costanza, Adam M. Wilson, Andrew M. Latimer, Sydne Record, Phoebe L. Zarnetske, Quentin D. Read, Scott V. Ollinger, Keith D. Gaddis, Andrew O. Finley, John Grady, Sparkle L. Malone, Kyla M. Dahlin, Stephanie Pau, Martina L. Hobi, and Gillespie, Thomas

Subjects

0106 biological sciences, Gamma diversity, Life on Land, elevation, satellite, Biodiversity, Beta diversity, Climate change, Shuttle Radar Topography Mission, 010603 evolutionary biology, 01 natural sciences, Physical Geography and Environmental Geoscience, remote sensing, geodiversity, Ecology, Evolution, Behavior and Systematics, biodiversity, Global and Planetary Change, Forest inventory, Ecology, 010604 marine biology & hydrobiology, gamma diversity, alpha diversity, trees, 15. Life on land, Geography, Geodiversity, 13. Climate action, scale dependence, Ecological Applications, Alpha diversity, beta diversity, Physical geography, Ecological Soundings

Abstract

Author(s): Zarnetske, Phoebe L; Read, Quentin D; Record, Sydne; Gaddis, Keith D; Pau, Stephanie; Hobi, Martina L; Malone, Sparkle L; Costanza, Jennifer; M Dahlin, Kyla; Latimer, Andrew M; Wilson, Adam M; Grady, John M; Ollinger, Scott V; Finley, Andrew O | Abstract: IssueGeodiversity (i.e., the variation in Earth's abiotic processes and features) has strong effects on biodiversity patterns. However, major gaps remain in our understanding of how relationships between biodiversity and geodiversity vary over space and time. Biodiversity data are globally sparse and concentrated in particular regions. In contrast, many forms of geodiversity can be measured continuously across the globe with satellite remote sensing. Satellite remote sensing directly measures environmental variables with grain sizes as small as tens of metres and can therefore elucidate biodiversity-geodiversity relationships across scales.EvidenceWe show how one important geodiversity variable, elevation, relates to alpha, beta and gamma taxonomic diversity of trees across spatial scales. We use elevation from NASA's Shuttle Radar Topography Mission (SRTM) and c.n16,000 Forest Inventory and Analysis plots to quantify spatial scaling relationships between biodiversity and geodiversity with generalized linear models (for alpha and gamma diversity) and beta regression (for beta diversity) across five spatial grains ranging from 5 to 100nkm. We illustrate different relationships depending on the form of diversity; beta and gamma diversity show the strongest relationship with variation in elevation.ConclusionWith the onset of climate change, it is more important than ever to examine geodiversity for its potential to foster biodiversity. Widely available satellite remotely sensed geodiversity data offer an important and expanding suite of measurements for understanding and predicting changes in different forms of biodiversity across scales. Interdisciplinary research teams spanning biodiversity, geoscience and remote sensing are well poised to advance understanding of biodiversity-geodiversity relationships across scales and guide the conservation of nature.

Published

2019