Relationships between tree rings and Landsat EVI in the Northeast United States

Farina, Mary K.

12 March 2016

Changes in the productivity of temperate forests have important implications for atmospheric carbon dioxide (CO2) concentrations, and many efforts have focused on methods to monitor both gross and net primary productivity in temperate forests. Remotely sensed vegetation indices provide spatially extensive measures of vegetation activity, and the Enhanced Vegetation Index (EVI) has been widely linked to photosynthetic activity of vegetation. Networks of tree ring width (TRW) chronologies provide ground-based estimates of annual net carbon (C) uptake in forests, and time series of EVI and TRW may capture common productivity signals. Robust correlations between mean TRW and EVI may enhance spatial extrapolations of TRW-based productivity estimates, ultimately improving understanding of spatio-temporal variability in forest productivity. The research presented in this thesis investigates potential empirical relationships between networks of TRW chronologies and time series of Landsat EVI and Landsat-based phenological metrics in the Northeast United States. We hypothesized that mean TRW is positively correlated with mean monthly EVI during the growing season, EVI integrated over the growing season, and growing season length. Results indicate that correlations between TRW and EVI are largely not significant in this region. The complex response of tree growth to a variety of limiting climatic factors in temperate forests may decouple measures of TRW growth and canopy reflectance. However, results also indicate that there may be important lag effects in which EVI affects mean TRW during the following year. These findings may improve understanding of links between C uptake and growth of tree stems over large spatial scales.

Remote sensing

Carbon uptake in temperate forests

Dendrochronology

Landsat

Tree ring width

Vegetation productivity

Enhanced vegetation Index

ESTIMATING EVAPOTRANSPIRATION USING REMOTE SENSING: A HYBRID APPROACH BETWEEN MODIS DERIVED ENHANCED VEGETATION INDEX, BOWEN RATIO SYSTEM, AND GROUND BASED MICRO-METEOROLOGICAL DATA

Chatterjee, Sumantra

20 April 2010

No description available.

Atmosphere

Environmental Science

Evapotranspiration

Remote Sensing

Enhanced Vegetation Index

Bowen Ratio

Vegetation productivity responds to sub-annual climate conditions across semiarid biomes

Barnes, Mallory L., Moran, M. Susan, Scott, Russell L., Kolb, Thomas E., Ponce-Campos, Guillermo E., Moore, David J. P., Ross, Morgan A., Mitra, Bhaskar, Dore, Sabina

05 1900

In the southwest United States, the current prolonged warm drought is similar to the predicted future climate change scenarios for the region. This study aimed to determine patterns in vegetation response to the early 21st century drought across multiple biomes. We hypothesized that different biomes (forests, shrublands, and grasslands) would have different relative sensitivities to both climate drivers (precipitation and temperature) and legacy effects (previous-year's productivity). We tested this hypothesis at eight Ameriflux sites in various Southwest biomes using NASA Moderate-resolution Imaging Spectroradiometer Enhanced Vegetation Index (EVI) from 2001 to 2013. All sites experienced prolonged dry conditions during the study period. The impact of combined precipitation and temperature on Southwest ecosystems at both annual and sub-annual timescales was tested using Standardized Precipitation Evapotranspiration Index (SPEI). All biomes studied had critical sub-annual climate periods during which precipitation and temperature influenced production. In forests, annual peak greenness (EVImax) was best predicted by 9-month SPEI calculated in July (i.e., January-July). In shrublands and grasslands, EVImax was best predicted by SPEI in July through September, with little effect of the previous year's EVImax. Daily gross ecosystem production (GEP) derived from flux tower data yielded further insights into the complex interplay between precipitation and temperature. In forests, GEP was driven by cool-season precipitation and constrained by warm-season maximum temperature. GEP in both shrublands and grasslands was driven by summer precipitation and constrained by high daily summer maximum temperatures. In grasslands, there was a negative relationship between temperature and GEP in July, but no relationship in August and September. Consideration of sub-annual climate conditions and the inclusion of the effect of temperature on the water balance allowed us to generalize the functional responses of vegetation to predicted future climate conditions. We conclude that across biomes, drought conditions during critical sub-annual climate periods could have a strong negative impact on vegetation production in the southwestern United States.

aboveground net primary production

drought

eddy covariance

Enhanced Vegetation Index (EVI)

forests

global change

grasslands

gross ecosystem production

shrublands

US Southwest

Monitoring Crop Evapotranspiration in the Western Lake Erie Basin Using Optical Sensors

Marambe Kodippili Arachchilage, Yahampath Anuruddha Marambe

26 November 2018

No description available.

Geology

Geobiology

Earth

Ecology

Environmental Geology

Remote Sensing

Agriculture

Agronomy

BEPS

ET

Evapotranspiration

WLEB

Landsat

Sentinel

Leaf Area Index

Enhanced Vegetation Index

Classification

Corn

Soybean

Alfalfa

Spatial ET

Boreal Ecosystem Productivity Simulator

Land cover

Crop frequency

Crop evapotranspiration