Your search keyword '"Laney, Christine M"' showing total 9 results

1. Provoking a Cultural Shift in Data Quality

Author

MCCORD, SARAH E., WEBB, NICHOLAS P., VAN ZEE, JUSTIN W., BURNETT, SARAH H., CHRISTENSEN, ERICA M., COURTRIGHT, ERICHA M., LANEY, CHRISTINE M., LUNCH, CLAIRE, MAXWELL, CONNIE, KARL, JASON W., SLAUGHTER, AMALIA, STAUFFER, NELSON G., and TWEEDIE, CRAIG

Published

2021

2. Iterative near-term ecological forecasting: Needs, opportunities, and challenges

Author

Dietze, Michael C, Fox, Andrew, Beck-Johnson, Lindsay M, Betancourt, Julio L, Hooten, Mevin B, Jarnevich, Catherine S, Keitt, Timothy H, Kenney, Melissa A, Laney, Christine M, Larsen, Laurel G, Loescher, Henry W, Lunch, Claire K, Pijanowski, Bryan C, Randerson, James T, Read, Emily K, Tredennick, Andrew T, Vargas, Rodrigo, Weathers, Kathleen C, and White, Ethan P

Subjects

Bayes Theorem, Climate Change, Ecology, Ecosystem, Forecasting, Humans, Models, Theoretical, forecast, ecology, prediction

Abstract

Two foundational questions about sustainability are "How are ecosystems and the services they provide going to change in the future?" and "How do human decisions affect these trajectories?" Answering these questions requires an ability to forecast ecological processes. Unfortunately, most ecological forecasts focus on centennial-scale climate responses, therefore neither meeting the needs of near-term (daily to decadal) environmental decision-making nor allowing comparison of specific, quantitative predictions to new observational data, one of the strongest tests of scientific theory. Near-term forecasts provide the opportunity to iteratively cycle between performing analyses and updating predictions in light of new evidence. This iterative process of gaining feedback, building experience, and correcting models and methods is critical for improving forecasts. Iterative, near-term forecasting will accelerate ecological research, make it more relevant to society, and inform sustainable decision-making under high uncertainty and adaptive management. Here, we identify the immediate scientific and societal needs, opportunities, and challenges for iterative near-term ecological forecasting. Over the past decade, data volume, variety, and accessibility have greatly increased, but challenges remain in interoperability, latency, and uncertainty quantification. Similarly, ecologists have made considerable advances in applying computational, informatic, and statistical methods, but opportunities exist for improving forecast-specific theory, methods, and cyberinfrastructure. Effective forecasting will also require changes in scientific training, culture, and institutions. The need to start forecasting is now; the time for making ecology more predictive is here, and learning by doing is the fastest route to drive the science forward.

Published

2018

3. Analysis of abrupt transitions in ecological systems

Author

Bestelmeyer, Brandon T, Ellison, Aaron M, Fraser, William R, Gorman, Kristen B, Holbrook, Sally J, Laney, Christine M, Ohman, Mark D, Peters, Debra PC, Pillsbury, Finn C, Rassweiler, Andrew, Schmitt, Russell J, and Sharma, Sapna

Subjects

alternative states, Bouteloua eriopoda, desert grassland, krill, leading indicators, Nyctiphanes simplex, Pachythyone rubra, penguins, Pygoscelis, regime shifts, sea cucumbers, thresholds, Ecological Applications, Ecology, Zoology

Published

2011

4. Filling the gaps: sensor network use and data-sharing practices in ecological research

Author

Laney, Christine M, Pennington, Deana D, and Tweedie, Craig E

Published

2015

5. Emerging technological and cultural shifts advancing drylands research and management

Author

Browning, Dawn M, Rango, Albert, Karl, Jason W, Laney, Christine M, Vivoni, Enrique R, and Tweedie, Craig E

Published

2015

6. The US National Ecological Observatory Network and the Global Biodiversity Framework: national research infrastructure with a global reach.

Author

Thibault, Katherine M., Laney, Christine M., Yule, Kelsey M., Franz, Nico M., and Mabee, Paula M.

Subjects

*WEB portals, *INTERNET protocol address, *DOWNLOADING, *DATA libraries, *OBSERVATORIES, *NEON, *BIODIVERSITY

Abstract

The US National Science Foundation's National Ecological Observatory Network (NEON) is a continental-scale program intended to provide open data, samples, and infrastructure to understand changing ecosystems for a period of 30 years. NEON collects co-located measurements of drivers of environmental change and biological responses, using standardized methods at 81 field sites to systematically sample variability and trends to enable inferences at regional to continental scales. Alongside key atmospheric and environmental variables, NEON measures the biodiversity of many taxa, including microbes, plants, and animals, and collects samples from these organisms for long-term archiving and research use. Here we review the composition and use of NEON resources to date as a whole and specific to biodiversity as an exemplar of the potential of national research infrastructure to contribute to globally relevant outcomes. Since NEON initiated full operations in 2019, NEON has produced, on average, 1.4 M records and over 32 TB of data per year across more than 180 data products, with 85 products that include taxonomic or other organismal information relevant to biodiversity science. NEON has also collected and curated more than 503,000 samples and specimens spanning all taxonomic domains of life, with up to 100,000 more to be added annually. Various metrics of use, including web portal visitation, data download and sample use requests, and scientific publications, reveal substantial interest from the global community in NEON. More than 47,000 unique IP addresses from around the world visit NEON's web portals each month, requesting on average 1.8 TB of data, and over 200 researchers have engaged in sample use requests from the NEON Biorepository. Through its many global partnerships, particularly with the Global Biodiversity Information Facility, NEON resources have been used in more than 900 scientific publications to date, with many using biodiversity data and samples. These outcomes demonstrate that the data and samples provided by NEON, situated in a broader network of national research infrastructures, are critical to scientists, conservation practitioners, and policy makers. They enable effective approaches to meeting global targets, such as those captured in the Kunming-Montreal Global Biodiversity Framework. [ABSTRACT FROM AUTHOR]

Published

2023

7. The founding charter of the Omic Biodiversity Observation Network (Omic BON).

Author

Meyer, Raïssa, Davies, Neil, Pitz, Kathleen J, Meyer, Chris, Samuel, Robyn, Anderson, Jane, Appeltans, Ward, Barker, Katharine, Chavez, Francisco P, Duffy, J Emmett, Goodwin, Kelly D, Hudson, Maui, Hunter, Margaret E, Karstensen, Johannes, Laney, Christine M, Leinen, Margaret, Mabee, Paula, Macklin, James A, Muller-Karger, Frank, and Pade, Nicolas

Subjects

BIODIVERSITY, FOUNDING, CHARTERS

Abstract

Omic BON is a thematic Biodiversity Observation Network under the Group on Earth Observations Biodiversity Observation Network (GEO BON), focused on coordinating the observation of biomolecules in organisms and the environment. Our founding partners include representatives from national, regional, and global observing systems; standards organizations; and data and sample management infrastructures. By coordinating observing strategies, methods, and data flows, Omic BON will facilitate the co-creation of a global omics meta-observatory to generate actionable knowledge. Here, we present key elements of Omic BON's founding charter and first activities. [ABSTRACT FROM AUTHOR]

Published

2023

8. Analysis of Abrupt Transitions in Ecological Systems

Author

Bestelmeyer, Brandon T., Ellison, Aaron M., Fraser, William R., Gorman, Kristen B., Holbrook, Sally J., Laney, Christine M., Ohman, Mark D., Peters, Debra P. C., Pillsbury, Finn C., Rassweiler, Andrew, Schmitt, Russell J., and Sharma, Sapna

Subjects

alternative states, Bouteloua eriopoda, desert grassland, krill, leading indicators, Nyctiphanes simplex, Pachythyone rubra, penguins, Pygoscelis, regime shifts, sea cucumbers, thresholds

Abstract

The occurrence and causes of abrupt transitions, thresholds, or regime shifts between ecosystem states are of great concern and the likelihood of such transitions is increasing for many ecological systems. General understanding of abrupt transitions has been advanced by theory, but hindered by the lack of a common, accessible, and data-driven approach to characterizing them. We apply such an approach to 30–60 years of data on environmental drivers, biological responses, and associated evidence from pelagic ocean, coastal benthic, polar marine, and semi-arid grassland ecosystems. Our analyses revealed one case in which the response (krill abundance) linearly tracked abrupt changes in the driver (Pacific Decadal Oscillation), but abrupt transitions detected in the three other cases (sea cucumber abundance, penguin abundance, and black grama grass production) exhibited hysteretic relationships with drivers (wave intensity, sea-ice duration, and amounts of monsoonal rainfall, respectively) through a variety of response mechanisms. The use of a common approach across these case studies illustrates that: the utility of leading indicators is often limited and can depend on the abruptness of a transition relative to the lifespan of responsive organisms and observation intervals; information on spatiotemporal context is useful for comparing transitions; and ancillary information from associated experiments and observations aids interpretation of response-driver relationships. The understanding of abrupt transitions offered by this approach provides information that can be used to manage state changes and underscores the utility of long-term observations in multiple sentinel sites across a variety of ecosystems., Organismic and Evolutionary Biology

Published

2011

9. Sample Management Across the National Ecological Observatory Network.

Author

Laney, Christine M., LeVan, Katherine E., Lunch, Claire K., and Thibault, Katherine M.

Subjects

ECOLOGICAL research, ARCHIVES collection management

Abstract

From 81 study sites across the United States, the US National Ecological Observatory Network (NEON), generates >75,000 samples per year. Samples range from soil and dust deposition material, tissue samples (e.g., small mammals and fish), DNA extracts, and whole organisms (e.g., ground beetles and ticks). Samples are collected, processed, and documented according to protocols that are standardized across study sites and according to the needs of the ecological research community for future studies. NEON has faced numerous challenges with managing data related to these many diverse physical samples, particularly when data are gathered at numerous steps throughout processing. Here, we share these challenges as well as solutions, including innovative semantically driven software tools and processing pipelines that manage data from each sample's point of collection to its ultimate fate (consumption, archive facility, or partnering data repository) while maintaining links across sample hierarchies. [ABSTRACT FROM AUTHOR]

Published

2018