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Phenological Monitoring: A key approach to assessing the impact of spring starting earlier

Phenological Monitoring: A key approach to assessing the impact of spring starting earlier. Mark D. Schwartz Department of Geography UW-Milwaukee. Research Contributions. Collaborators: R. Ahas, A. Aasa, L. Liang Phenology data from J. Caprio, X. Chen, DWD, and A. Menzel

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Phenological Monitoring: A key approach to assessing the impact of spring starting earlier

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  1. Phenological Monitoring: A key approach to assessing the impact of spring starting earlier Mark D. Schwartz Department of Geography UW-Milwaukee

  2. Research Contributions • Collaborators: R. Ahas, A. Aasa, L. Liang • Phenology data from J. Caprio, X. Chen, DWD, and A. Menzel • Climate data from Chinese Academy of Meteorological Sciences, Environment Canada, German Weather Service (DWD), European Climate Assessment, Instytut Meteorologii i Gospodarki Wodnej (Poland), USA Carbon Dioxide Information and Analysis Center, USA National Climatic Data Center • NSF Grants ATM-9510342, 9809460, and 0085224 • Estonian Science Foundation Grant 5836 (Ahas) • Base maps from ESRI data

  3. Definition of Phenology • Phenologywhich is derived from the Greek word phaino meaning to show or to appear, is the study of plant and animal life cycle events, which are triggered by environmental changes, especially temperature and precipitation. Thus, timings of phenological events are ideal indicators of global change impacts. • Seasonality is a related term, referring to similar non-biological events, such as timing of the fall formation and spring break-up of ice on fresh water lakes.

  4. Phenological Research • Traditional approach: agriculture-centered, and local-scale events • Recent approach: Earth systems interactions, and global-scale events

  5. Integrated Approach • Satellite Observations (MODIS-NDVI/EVI) • Indicator Species Phenology • Native Species Phenology

  6. Cloned Species Phenology • Advantages: 1) Ideal for model development; 2) Standardized response to environment; 3) Broad range • Limitations: 1) Lack of network geographical coverage; 2) Not adapted to local environment

  7. Lilac First Leaf

  8. Lilac First Bloom

  9. Simulated Phenology • Advantages: 1) Broad coverage if using simple input; 2) Standardized response • Limitations: 1) Model inadequacies; 2) Small set of events and plants

  10. Spring IndicesSuite of Measures • First -2.2oC freeze date in autumn • Composite chill date (SI models) • First leaf date, “early spring” (SI models) • First bloom date, “late spring” (SI models) • Last -2.2oC freeze date in spring • -2.2oC Freeze period • Damage index value (first leaf date – last frost date) • Average annual, average seasonal, and twelve average monthly temperatures

  11. SI First Leaf Date 1961-2000 Slope Source: Schwartz et al. 2006, Figure 1

  12. North. Hem. SI First Leaf Date Departures Source: Schwartz et al. 2006, Figure 2 (modified)

  13. SI First Leaf Date in North America Source: Schwartz and Reiter 2000, Plate 4 (updated)

  14. SI First Bloom Date 1961-2000 Slope

  15. North Hem. SI First Bloom Date Departures

  16. Last Spring –2.2oC Freeze Date 1961-2000 Slope Source: Schwartz et al. 2006, Figure 3

  17. North. Hem. Last –2.2oC Freeze Date Departures Source: Schwartz et al. 2006, Figure 4 (modified)

  18. North. Hem. 5oC Growing Season Length Departures

  19. Conclusions • The onset of spring has become significantly earlier across most temperate land areas of the Northern Hemisphere from 1955-2002. • Important regional differences exist among the indices. • These results provide a consistent and conventional framework for comparison to past and future studies, and a first approximation of likely impacts. • These results reinforce the results from previous regional-scale phenological and climatological studies. • National and global scale phenological networks, like the developing USA-NPN are needed to enhance understanding of these important changes, see http://www.npn.uwm.edu

  20. Plan for a USA National Phenology Network (USA-NPN)http://www.npn.uwm.edu • a continental-scale network observing regionally appropriate native plant species, cloned indicator plants (lilac + others), and selected agricultural crops • designed to complement remote sensing observations • data collected will be freely available to the research community and general public

  21. USA-NPN Monitoring Framework AmeriFlux, AgriFlux NSF LTER, NEON USGS WEBB USDA FS Exp. F & R Intensive Sites NWS Coop NPS Inv. & Mon. USDA FIA State Ag. Exp. Sta. Spatially Extensive Science Networks Increasing Process Knowledge Data Quality # of Measurements Decreasing Spatial Coverage GLOBE Garden clubs Nat. Plant Soc. Campuses Spatially Extensive Volunteer & Education Networks NASA USGS NOAA Remote Sensing and Synoptic (wall-to-wall) Data

  22. USA-NPN PlantObservation Strategy • Cloned plants (lilac, dogwood, ocotillo) • “Calibration” species (about 20 with 1-4 each from allergans, coniferous, crops, coniferous, deciduous, herbaceous, and “showy”) • Additional species of interest to the observer or local/regional networks

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