Your search keyword '"Sarah C. Elmendorf"' showing total 3 results

1. Introduction to the sampling designs of the National Ecological Observatory Network Terrestrial Observation System

Author

Andrea S. Thorpe, David T. Barnett, Sarah C. Elmendorf, Eve‐Lyn S. Hinckley, David Hoekman, Katherine D. Jones, Katherine E. LeVan, Courtney L. Meier, Lee F. Stanish, and Katherine M. Thibault

Subjects

beetles, biogeochemistry, birds, disease, mosquitoes, plants, Ecology, QH540-549.5

Abstract

Abstract Global change drivers influence ecological processes at multiple scales and manifest across most of Earth as changes in biodiversity, biogeochemical cycles, infectious disease incidence, and ecohydrology. Small‐scale investigations provide compelling evidence of specific effects of global change on local systems, but are of limited use in modeling complex ecological processes at continental‐to‐global scales. Long‐term observations distributed across a diversity of habitat types are needed to improve the ability to forecast ecological change at large spatial and temporal scales. This special issue introduces the Terrestrial Observation System (TOS) of the National Ecological Observatory Network (NEON), a long‐term, continental‐scale ecological research platform designed to deliver these large‐scale datasets. The TOS measures biodiversity of key biota (soil microbes, insects, plants, small mammals), ecosystem productivity and biogeochemistry, infectious disease dynamics, phenology, and population dynamics. The articles in this special issue describe the scientific rationale for the sampling designs of the TOS, including an overview of protocols, locations, and frequencies of measurements. The science designs are a culmination of design requirements scoped by NEON and the National Science Foundation, best available practices put forth by the scientific community, input from technical working groups, and consideration of logistical and financial constraints by NEON staff. Within each site, measurements have been collocated to the extent possible to optimize linkages among different sampling elements. Integrated analyses of terrestrial observations with sensor‐based, imagery, and remote‐sensing data collected by other NEON subsystems can facilitate scaling of measured parameters to larger spatial and temporal scales. NEON is designed to collect data for 30 years, and make these data freely available on a public data portal (data.neonscience.org). Samples and specimens will be archived and available to the scientific community upon request. The open access approach to the Observatory will provide users with the resources necessary to map, understand, and predict the effects of global change drivers on ecological processes at a continental scale.

Published

2016

2. The plant phenology monitoring design for The National Ecological Observatory Network

Author

Sarah C. Elmendorf, Katherine D. Jones, Benjamin I. Cook, Jeffrey M. Diez, Carolyn A. F. Enquist, Rebecca A. Hufft, Matthew O. Jones, Susan J. Mazer, Abraham J. Miller‐Rushing, David J. P. Moore, Mark D. Schwartz, and Jake F. Weltzin

Subjects

long‐term monitoring, NEON, open‐source data, plant phenology, sample design, Special Feature: NEON Design, Ecology, QH540-549.5

Abstract

Abstract Phenology is an integrative science that comprises the study of recurring biological activities or events. In an era of rapidly changing climate, the relationship between the timing of those events and environmental cues such as temperature, snowmelt, water availability, or day length are of particular interest. This article provides an overview of the observer‐based plant phenology sampling conducted by the U.S. National Ecological Observatory Network (NEON), the resulting data, and the rationale behind the design. Trained technicians will conduct regular in situ observations of plant phenology at all terrestrial NEON sites for the 30‐yr life of the observatory. Standardized and coordinated data across the network of sites can be used to quantify the direction and magnitude of the relationships between phenology and environmental forcings, as well as the degree to which these relationships vary among sites, among species, among phenophases, and through time. Vegetation at NEON sites will also be monitored with tower‐based cameras, satellite remote sensing, and annual high‐resolution airborne remote sensing. Ground‐based measurements can be used to calibrate and improve satellite‐derived phenometrics. NEON's phenology monitoring design is complementary to existing phenology research efforts and citizen science initiatives throughout the world and will produce interoperable data. By collocating plant phenology observations with a suite of additional meteorological, biophysical, and ecological measurements (e.g., climate, carbon flux, plant productivity, population dynamics of consumers) at 47 terrestrial sites, the NEON design will enable continental‐scale inference about the status, trends, causes, and ecological consequences of phenological change.

Published

2016

3. Introduction to the sampling designs of the <scp>N</scp> ational <scp>E</scp> cological <scp>O</scp> bservatory <scp>N</scp> etwork <scp>T</scp> errestrial <scp>O</scp> bservation <scp>S</scp> ystem

Author

Katherine M. Thibault, Courtney L. Meier, David T. Barnett, Eve-Lyn S. Hinckley, David Hoekman, Katherine E. LeVan, Lee F. Stanish, Sarah C. Elmendorf, Andrea S. Thorpe, and Katherine D. Jones

Subjects

0106 biological sciences, education.field_of_study, 010504 meteorology & atmospheric sciences, Ecology, Population, Biodiversity, Global change, Biota, Biology, 010603 evolutionary biology, 01 natural sciences, Observatory, Ecohydrology, Ecosystem, education, Temporal scales, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Global change drivers influence ecological processes at multiple scales and manifest across most of Earth as changes in biodiversity, biogeochemical cycles, infectious disease incidence, and ecohydrology. Small-scale investigations provide compelling evidence of specific effects of global change on local systems, but are of limited use in modeling complex ecological processes at continental-to-global scales. Long-term observations distributed across a diversity of habitat types are needed to improve the ability to forecast ecological change at large spatial and temporal scales. This special issue introduces the Terrestrial Observation System (TOS) of the National Ecological Observatory Network (NEON), a long-term, continental-scale ecological research platform designed to deliver these large-scale datasets. The TOS measures biodiversity of key biota (soil microbes, insects, plants, small mammals), ecosystem productivity and biogeochemistry, infectious disease dynamics, phenology, and population dynamics. The articles in this special issue describe the scientific rationale for the sampling designs of the TOS, including an overview of protocols, locations, and frequencies of measurements. The science designs are a culmination of design requirements scoped by NEON and the National Science Foundation, best available practices put forth by the scientific community, input from technical working groups, and consideration of logistical and financial constraints by NEON staff. Within each site, measurements have been collocated to the extent possible to optimize linkages among different sampling elements. Integrated analyses of terrestrial observations with sensor-based, imagery, and remote-sensing data collected by other NEON subsystems can facilitate scaling of measured parameters to larger spatial and temporal scales. NEON is designed to collect data for 30 years, and make these data freely available on a public data portal (data.neonscience.org). Samples and specimens will be archived and available to the scientific community upon request. The open access approach to the Observatory will provide users with the resources necessary to map, understand, and predict the effects of global change drivers on ecological processes at a continental scale.

Published

2016