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National Ecological Observatory Network

From Wikipedia, the free encyclopedia
National Ecological Observatory Network
AbbreviationNEON
TypeNonprofit organization
PurposeEcological monitoring
HeadquartersBoulder, Colorado
Region served
United States
Websitewww.neonscience.org

National Ecological Observatory Network (NEON) is a facility program operated by Battelle Memorial Institute and funded by the National Science Foundation. In full operation since 2019, NEON gathers and provides long-term, standardized data on ecological responses of the biosphere to changes in land use and climate, and on feedback with the geosphere, hydrosphere, and atmosphere.[1] NEON is a continental-scale research platform for understanding how and why our ecosystems are changing.[2]

Vision and mission

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A short documentary demonstrating the goals of NEON

The vision for NEON is to guide global understanding and decisions in a changing environment with scientific information about continental-scale ecology through integrated observations, experiments and forecasts. NEON's mission is to design, implement and operate the first and foremost integrated continental‐scale scientific infrastructure to enable research, discovery and education about ecological change.

NEON collects ecological and climatic observations across the United States, including Alaska, Hawaii and Puerto Rico. The observatory is among the first to detect and enable forecasting of ecological change at continental scales over multiple decades. NEON has partitioned the United States into 20 ecoclimatic domains, each of which represents different regions of vegetation, landforms, climate, and ecosystem performance. Data is collected by field technicians and passive sensors at strategically selected sites within each domain and synthesized into information products that can be used to describe changes in the nation's ecosystem through space and time. NEON data products are freely available via a web portal.

Purpose and function

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Science

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NEON headquarters in Boulder
NEON tower at the Jornada Experimental Range

The data NEON collects are defined by a series of Grand Challenges, as identified by the National Research Council at the request of the National Science Foundation.[3] The National Research Council established a committee to evaluate the major ecological, environmental, and national concerns that require a continental-scale observatory, and it identified the following Environmental Grand Challenges:

  • Biogeochemistry: The study of how chemical, physical, geological, and biological processes combine to create the natural environment.
  • Biodiversity: The full range of life forms on earth, or in a particular region.
  • Climate change: A significant long-term change in the kind of weather we would expect based on averages calculated from climate data.
  • Ecohydrology: The study of how organisms interact with their environment and with the constant movement of water.
  • Infectious Diseases: Diseases spread by viruses, parasites, and bacteria that are sometimes transmitted to people by animals, birds, and insects.
  • Land Use: The many ways that people change the natural landscape and environment, such as by building cities, cutting down forests, or planting crops.
  • Invasive Species: Plants and organisms that overpopulate a particular place, or species that move into areas they have not lived in before.

Thus, the data and observations that NEON collects focuses on how land use, climate change and invasive species affect biodiversity, disease ecology, and ecosystem services. Obtaining integrated data on these relationships over a long-term period is crucial to improving forecast models and resource management for environmental change.

The National Science Foundation's vision for NEON is described as:

"A continental scale research instrument consisting of geographically distributed infrastructure, networked via state-of-the-art communications. Cutting-edge lab and field instrumentation, site-based experimental infrastructure, natural history archive facilities and/or computational, analytical and modeling capabilities, linked via a computational network will comprise NEON. NEON will transform ecological research by enabling studies on major environmental challenges at regional to continental scales. Scientists and engineers will use NEON to conduct real-time ecological studies spanning all levels of biological organization and temporal and geographical scales. NSF disciplinary and multi-disciplinary programs will support NEON research projects and educational activities. Data from standard measurements made using NEON will be publicly available.” (NSF 04549, 2004)[4]

NEON is specifically designed to address central scientific questions about the interactions of ecosystems, climate, and land use:

  • How will ecosystems and their components respond to changes in natural- and human-induced forcings such as climate, land use, and invasive species across a range of spatial and temporal scales? And, what is the pace and pattern of the responses?
  • How do the internal responses and feedbacks of biogeochemistry, biodiversity, hydroecology, and biotic structure and function interact with changes in climate, land use, and invasive species? And, how do these feedbacks vary with ecological context and spatial and temporal scales?

Education

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The data and information products that NEON collects and provides is readily available to scientists, educators, students, decision makers and the public to use to understand and address ecological questions and issues. Data is provided as meaningful information and learning tools that engage many audiences, including members of underserved communities, and promote broad ecological literacy.

History

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NEON was initially conceived in 2000, with a preliminary plan being developed in 2006. The National Science Foundation, the National Science Board and Congress approved funding for NEON in 2011.[5] The program was fully operational in 2019.[1]

Beginning in 2011, NEON, Inc., the entity in charge of initially running the NEON project, was audited by the Defense Contract Audit Agency on behalf of the National Science Foundation Office of the Inspector General. Auditor-in-Charge J. Kirk McGill determined that NEON, Inc. had poor control over taxpayer funds and could easily go over budget with little or no warning. He also found that NEON, Inc. had spent taxpayer funds on illegal expenditures including alcohol, lobbying, parties, and luxury travel. When McGill's findings were not addressed, he disclosed the matter directly to Congress.[6] Hearings were held in 2014 and 2015.[7][4][8] The House Committee on Science, Space, and Technology ultimately substantiated McGill's allegations, and NEON, Inc., was dismissed from the project.[9] This represents one of the largest Federal agreement terminations for cause in history. The NSF chose Battelle to complete the construction of the observatory.[10]

Layout

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Instrumentation hut at Frog Rock, Yellowstone

NEON has categorized five types of measurement systems: the Airborne Observation Platform, Aquatic Instrument System, Aquatic Observation System, Terrestrial Instrument System, and Terrestrial Observation System.[11]

Airborne observations

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NEON takes airborne photography and performs aerial LiDAR observations of the sites being studied.[12] This is accomplished by slow flying aircraft surveying at 1,000 meters above the ground.[13]

Aquatic sites

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Aquatic site sampling depends on the type of environment, varying between streams, rivers, and lakes. Automated sensors assess water quality and depth and manual observations study organisms, biogeochemistry, hydrology, and morphology.[11]

Terrestrial sites

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Each terrestrial site studied by NEON includes 30 randomly distributed plots. At select plots, technicians monitor soil biogeochemistry and microbes; plant diversity, biogeochemistry, biomass, productivity, and leaf area index; beetle diversity; mosquito prevalence, diversity, phenology, and infectious disease; small mammal diversity, demography, and disease; avian diversity; and tick‐borne diseases.[11] Each terrestrial site is outfitted with soil sensor arrays and a tower mounted with sensory equipment. Towers are built to extend above the vegetation canopy and take measurements such as on air quality, carbon dioxide flux, temperature, and atmospheric pressure.[14] Additional sampling plots are located within the airshed of the tower.[11]

Locations

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Map of established NEON sites
NEON tower in Delta Junction, Alaska

Sites are organized within 20 separate ecoclimatic domains throughout the United States. They are divided by terrestrial and aquatic sampling.[15]

See also

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References

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  1. ^ a b Pennisi, Elizabeth (29 August 2019). "NSF's huge ecological observatory is open for business. But tensions remain". Science Mag. Retrieved 2 June 2020.
  2. ^ "About | NSF NEON | Open Data to Understand our Ecosystems". www.neonscience.org.
  3. ^ "US NSF - NEON". www.nsf.gov. Retrieved 3 June 2020.
  4. ^ a b NSF Synopsis for NEON
  5. ^ "History | NSF NEON | Open Data to Understand our Ecosystems". www.neonscience.org.
  6. ^ McGill, J. Kirk (2014-04-27), English: J. Kirk McGill's April 27, 2014 Whistleblower Disclosure (PDF), retrieved 2016-01-06
  7. ^ "Full Committee Hearing - Review of the Results of Two Audits of the National Ecological Observatory Network". Committee on Science, Space, and Technology. 3 December 2014. Retrieved 2016-01-06.
  8. ^ "Subcommittee on Research and Technology and Subcommittee on Oversight Hearing: NEON Warning Signs: Examining the Management of the National Ecological Observatory Network". Committee on Science, Space, and Technology. 18 September 2015. Retrieved 2016-01-06.
  9. ^ "NSF fires managers of troubled NEON ecology project". news.sciencemag.org. Retrieved 2016-01-06.
  10. ^ Mervis, Jeffrey. "NSF picks Battelle to run NEON". Science Mag. American Association for the Advancement of Science. Retrieved 7 April 2016.
  11. ^ a b c d Thorpe, Andrea S.; Barnett, David T.; Elmendorf, Sarah C.; Hinckley, Eve-Lyn S.; Hoekman, David; Jones, Katherine D.; LeVan, Katherine E.; Meier, Courtney L.; Stanish, Lee F.; Thibault, Katherine M. (2016). "Introduction to the sampling designs of the National Ecological Observatory Network Terrestrial Observation System". Ecosphere. 7 (12): e01627. Bibcode:2016Ecosp...7E1627T. doi:10.1002/ecs2.1627. ISSN 2150-8925.
  12. ^ Krause, Keith; Kampe, Thomas; Musinsky, John (2013). "Ecological Mapping - Using Integrated LiDAR and Hyperspectral Airborne Remote Sensing at NEON" (PDF). LiDAR Magazine. 3 (6). Retrieved 3 June 2020.
  13. ^ "Airborne Remote Sensing | NSF NEON | Open Data to Understand our Ecosystems". www.neonscience.org. Retrieved 3 June 2020.
  14. ^ "Flux Tower Measurements | NSF NEON | Open Data to Understand our Ecosystems". www.neonscience.org.
  15. ^ "Types of NEON Field Sites". www.neonscience.org.
  16. ^ a b c d e f g h i j k l m n o p q r s t "Field Sites". www.neonscience.org.
  17. ^ a b c d e f g h i j k l m n o p q r s t "Field Offices | NSF NEON | Open Data to Understand our Ecosystems". www.neonscience.org.
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