Your search keyword '"Sayler, Kristi L."' showing total 6 results

1. Spatially explicit land-use and land-cover scenarios for the Great Plains of the United States

Author

Sohl, Terry L., Sleeter, Benjamin M., Sayler, Kristi L., Bouchard, Michelle A., Reker, Ryan R., Bennett, Stacie L., Sleeter, Rachel R., Kanengieter, Ronald L., and Zhu, Zhiliang

Published

2012

2. Land-cover change in the conterminous United States from 1973 to 2000.

Author

Sleeter, Benjamin M., Sohl, Terry L., Loveland, Thomas R., Auch, Roger F., Acevedo, William, Drummond, Mark A., Sayler, Kristi L., and Stehman, Stephen V.

Subjects

LAND cover, LAND use, FARMS, ANTHROPOGENIC soils, ECOSYSTEMS

Abstract

Highlights: [•] Changes in land use and cover affected 8.6% of the conterminous United States between 1973 and 2000. [•] Change impacted 16.6% of US forests with net forest cover declining by 4.2%. [•] Agricultural land declined by 4.2% while grass/shrubland increased by 2%. [•] Developed areas increased by 33%. [•] Natural and anthropogenic ecosystem disturbance impacted 236,000km2. [Copyright &y& Elsevier]

Published

2013

3. Scenarios of land use and land cover change in the conterminous United States: Utilizing the special report on emission scenarios at ecoregional scales.

Author

Sleeter, Benjamin M., Sohl, Terry L., Bouchard, Michelle A., Reker, Ryan R., Soulard, Christopher E., Acevedo, William, Griffith, Glenn E., Sleeter, Rachel R., Auch, Roger F., Sayler, Kristi L., Prisley, Stephen, and Zhu, Zhiliang

Subjects

LAND use, LAND cover, EMISSIONS (Air pollution), ECOLOGICAL regions, GLOBAL environmental change, SPATIAL analysis (Statistics), THEMATIC analysis

Abstract

Abstract: Global environmental change scenarios have typically provided projections of land use and land cover for a relatively small number of regions or using a relatively coarse resolution spatial grid, and for only a few major sectors. The coarseness of global projections, in both spatial and thematic dimensions, often limits their direct utility at scales useful for environmental management. This paper describes methods to downscale projections of land-use and land-cover change from the Intergovernmental Panel on Climate Change''s Special Report on Emission Scenarios to ecological regions of the conterminous United States, using an integrated assessment model, land-use histories, and expert knowledge. Downscaled projections span a wide range of future potential conditions across sixteen land use/land cover sectors and 84 ecological regions, and are logically consistent with both historical measurements and SRES characteristics. Results appear to provide a credible solution for connecting regionalized projections of land use and land cover with existing downscaled climate scenarios, under a common set of scenario-based socioeconomic assumptions. [Copyright &y& Elsevier]

Published

2012

4. Land change variability and human–environment dynamics in the United States Great Plains.

Author

Drummond, Mark A., Auch, Roger F., Karstensen, Krista A., Sayler, Kristi L., Taylor, Janis L., and Loveland, Thomas R.

Subjects

LAND use, LANDSAT satellites, LAND cover, CLIMATE change, SOCIOECONOMIC factors, ECOLOGICAL regions

Abstract

Abstract: Land use and land cover changes have complex linkages to climate variability and change, biophysical resources, and socioeconomic driving forces. To assess these land change dynamics and their causes in the Great Plains, we compare and contrast contemporary changes across 16 ecoregions using Landsat satellite data and statistical analysis. Large-area change analysis of agricultural regions is often hampered by change detection error and the tendency for land conversions to occur at the local-scale. To facilitate a regional-scale analysis, a statistical sampling design of randomly selected 10km×10km blocks is used to efficiently identify the types and rates of land conversions for four time intervals between 1973 and 2000, stratified by relatively homogenous ecoregions. Nearly 8% of the overall Great Plains region underwent land-use and land-cover change during the study period, with a substantial amount of ecoregion variability that ranged from less than 2% to greater than 13%. Agricultural land cover declined by more than 2% overall, with variability contingent on the differential characteristics of regional human–environment systems. A large part of the Great Plains is in relatively stable land cover. However, other land systems with significant biophysical and climate limitations for agriculture have high rates of land change when pushed by economic, policy, technology, or climate forcing factors. The results indicate the regionally based potential for land cover to persist or fluctuate as land uses are adapted to spatially and temporally variable forcing factors. [Copyright &y& Elsevier]

Published

2012

5. A land-use and land-cover modeling strategy to support a national assessment of carbon stocks and fluxes

Author

Sohl, Terry L., Sleeter, Benjamin M., Zhu, Zhiliang, Sayler, Kristi L., Bennett, Stacie, Bouchard, Michelle, Reker, Ryan, Hawbaker, Todd, Wein, Anne, Liu, Shuguang, Kanengieter, Ronald, and Acevedo, William

Subjects

*LAND use, *GREENHOUSE gas mitigation, *LAND cover, *BIOTIC communities, *CARBON cycle, *CARBON sequestration, *BIOGEOCHEMISTRY, *ECOLOGICAL regions

Abstract

Abstract: Changes in land use, land cover, disturbance regimes, and land management have considerable influence on carbon and greenhouse gas (GHG) fluxes within ecosystems. Through targeted land-use and land-management activities, ecosystems can be managed to enhance carbon sequestration and mitigate fluxes of other GHGs. National-scale, comprehensive analyses of carbon sequestration potential by ecosystem are needed, with a consistent, nationally applicable land-use and land-cover (LULC) modeling framework a key component of such analyses. The U.S. Geological Survey has initiated a project to analyze current and projected future GHG fluxes by ecosystem and quantify potential mitigation strategies. We have developed a unique LULC modeling framework to support this work. Downscaled scenarios consistent with IPCC Special Report on Emissions Scenarios (SRES) were constructed for U.S. ecoregions, and the FORE-SCE model was used to spatially map the scenarios. Results for a prototype demonstrate our ability to model LULC change and inform a biogeochemical modeling framework for analysis of subsequent GHG fluxes. The methodology was then successfully used to model LULC change for four IPCC SRES scenarios for an ecoregion in the Great Plains. The scenario-based LULC projections are now being used to analyze potential GHG impacts of LULC change across the U.S. [Copyright &y& Elsevier]

Published

2012

6. Lessons learned implementing an operational continuous United States national land change monitoring capability: The Land Change Monitoring, Assessment, and Projection (LCMAP) approach.

Author

Brown, Jesslyn F., Tollerud, Heather J., Barber, Christopher P., Zhou, Qiang, Dwyer, John L., Vogelmann, James E., Loveland, Thomas R., Woodcock, Curtis E., Stehman, Stephen V., Zhu, Zhe, Pengra, Bruce W., Smith, Kelcy, Horton, Josephine A., Xian, George, Auch, Roger F., Sohl, Terry L., Sayler, Kristi L., Gallant, Alisa L., Zelenak, Daniel, and Reker, Ryan R.

Subjects

*LAND cover, *RANDOM forest algorithms, *NATION-state

Abstract

Growing demands for temporally specific information on land surface change are fueling a new generation of maps and statistics that can contribute to understanding geographic and temporal patterns of change across large regions, provide input into a wide range of environmental modeling studies, clarify the drivers of change, and provide more timely information for land managers. To meet these needs, the U.S. Geological Survey has implemented a capability to monitor land surface change called the Land Change Monitoring, Assessment, and Projection (LCMAP) initiative. This paper describes the methodological foundations and lessons learned during development and testing of the LCMAP approach. Testing and evaluation of a suite of 10 annual land cover and land surface change data sets over six diverse study areas across the United States revealed good agreement with other published maps (overall agreement ranged from 73% to 87%) as well as several challenges that needed to be addressed to meet the goals of robust, repeatable, and geographically consistent monitoring results from the Continuous Change Detection and Classification (CCDC) algorithm. First, the high spatial and temporal variability of observational frequency led to differences in the number of changes identified, so CCDC was modified such that change detection is dependent on observational frequency. Second, the CCDC classification methodology was modified to improve its ability to characterize gradual land surface changes. Third, modifications were made to the classification element of CCDC to improve the representativeness of training data, which necessitated replacing the random forest algorithm with a boosted decision tree. Following these modifications, assessment of prototype Version 1 LCMAP results showed improvements in overall agreement (ranging from 85% to 90%). • We developed a robust capability for operational monitoring of land surface change. • Landsat ARD and Continuous Change Detection and Classification are foundational. • Landsat's rich time series has substantial variability in observation frequency. • The algorithm was modified reducing variability in results between scene centers and overlap zones. • Classification was modified to improve training data representativeness and reduce artifacts. [ABSTRACT FROM AUTHOR]

Published

2020