Your search keyword '"Bathke, Deborah"' showing total 3 results

1. Monitoring Climate Impacts on Annual Forage Production across U.S. Semi-Arid Grasslands

Author

Poděbradská, Markéta, primary, Wylie, Bruce K., additional, Bathke, Deborah J., additional, Bayissa, Yared A., additional, Dahal, Devendra, additional, Derner, Justin D., additional, Fay, Philip A., additional, Hayes, Michael J., additional, Schacht, Walter H., additional, Volesky, Jerry D., additional, Wagle, Pradeep, additional, and Wardlow, Brian D., additional

Published

2021

2. Monitoring Climate Impacts on Annual Forage Production across U.S. Semi-Arid Grasslands.

Author

Poděbradská, Markéta, Wylie, Bruce K., Bathke, Deborah J., Bayissa, Yared A., Dahal, Devendra, Derner, Justin D., Fay, Philip A., Hayes, Michael J., Schacht, Walter H., Volesky, Jerry D., Wagle, Pradeep, and Wardlow, Brian D.

Subjects

ECOSYSTEMS, NORMALIZED difference vegetation index, GEODATABASES, REGRESSION trees, VEGETATION greenness, SOIL surveys, GRASSLANDS, ADAPTIVE natural resource management

Abstract

The ecosystem performance approach, used in a previously published case study focusing on the Nebraska Sandhills, proved to minimize impacts of non-climatic factors (e.g., overgrazing, fire, pests) on the remotely-sensed signal of seasonal vegetation greenness resulting in a better attribution of its changes to climate variability. The current study validates the applicability of this approach for assessment of seasonal and interannual climate impacts on forage production in the western United States semi-arid grasslands. Using a piecewise regression tree model, we developed the Expected Ecosystem Performance (EEP), a proxy for annual forage production that reflects climatic influences while minimizing impacts of management and disturbances. The EEP model establishes relations between seasonal climate, site-specific growth potential, and long-term growth variability to capture changes in the growing season greenness measured via a time-integrated Normalized Difference Vegetation Index (NDVI) observed using a Moderate Resolution Imaging Spectroradiometer (MODIS). The resulting 19 years of EEP were converted to expected biomass (EB, kg ha−1 year−1) using a newly-developed relation with the Soil Survey Geographic Database range production data (R2 = 0.7). Results were compared to ground-observed biomass datasets collected by the U.S. Department of Agriculture and University of Nebraska-Lincoln (R2 = 0.67). This study illustrated that this approach is transferable to other semi-arid and arid grasslands and can be used for creating timely, post-season forage production assessments. When combined with seasonal climate predictions, it can provide within-season estimates of annual forage production that can serve as a basis for more informed adaptive decision making by livestock producers and land managers. [ABSTRACT FROM AUTHOR]

Published

2022

3. Monitoring Drought Impact on Annual Forage Production in Semi-Arid Grasslands: A Case Study of Nebraska Sandhills.

Author

Poděbradská, Markéta, Wylie, Bruce K., Hayes, Michael J., Wardlow, Brian D., Bathke, Deborah J., Bliss, Norman B., and Dahal, Devendra

Subjects

DROUGHT management, FORAGE, BIOMASS production, DROUGHTS, GEODATABASES, GRASSLANDS, SOIL surveys, HEATHLANDS

Abstract

Land management practices and disturbances (e.g. overgrazing, fire) have substantial effects on grassland forage production. When using satellite remote sensing to monitor climate impacts, such as drought stress on annual forage production, minimizing land management practices and disturbance effects sends a clear climate signal to the productivity data. This study investigates the effect of this climate signal by: (1) providing spatial estimates of expected biomass under specific climate conditions, (2) determining which drought indices explain the majority of interannual variability in this biomass, and (3) developing a predictive model that estimates the annual biomass early in the growing season. To address objective 1, this study uses an established methodology to determine Expected Ecosystem Performance (EEP) in the Nebraska Sandhills, US, representing annual forage levels after accounting for non-climatic influences. Moderate Resolution Imaging Spectroradiometer (MODIS)-based Normalized Difference Vegetation Index (NDVI) data were used to approximate actual ecosystem performance. Seventeen years (2000–2016) of annual EEP was calculated using piecewise regression tree models of site potential and climate data. Expected biomass (EB), EEP converted to biomass in kg*ha−1*yr−1, was then used to examine the predictive capacity of several drought indices and the onset date of the growing season. Subsets of these indices were used to monitor and predict annual expected grassland biomass. Independent field-based biomass production data available from two Sandhills locations were used for validation of the EEP model. The EB was related to field-based biomass production (R2 = 0.66 and 0.57) and regional rangeland productivity statistics of the Soil Survey Geographic Database (SSURGO) dataset. The Evaporative Stress Index (ESI), the 3- and 6-month Standardized Precipitation Index (SPI), and the U.S. Drought Monitor (USDM), which represented moisture conditions during May, June and July, explained the majority of the interannual biomass variability in this grassland system (three-month ESI explained roughly 72% of the interannual biomass variability). A new model was developed to use drought indices from early in the growing season to predict the total EB for the whole growing season. This unique approach considers only climate-related drought signal on productivity. The capability to estimate annual EB by the end of May will potentially enable land managers to make informed decisions about stocking rates, hay purchase needs, and other management issues early in the season, minimizing their potential drought losses. [ABSTRACT FROM AUTHOR]

Published

2019