Abstract
Agricultural production in the Texas High Plains (THP) relies heavily on irrigation and is susceptible to drought due to the declining availability of groundwater and climate change. Therefore, it is meaningful to perform an overview of possible climate change scenarios to provide appropriate strategies for climate change adaptation in the THP. In this study, spatio-temporal variations of climate data were mapped in the THP during 2000–2009, 2050–2059, and 2090–2099 periods using 14 research-grade meteorological stations and 19 bias-corrected General Circulation Models (GCMs) under representative concentration pathway (RCP) scenarios RCP 4.5 and 8.5. Results indicated different bias correction methods were needed for different climatic parameters and study purposes. For example, using high-quality data from the meteorological stations, the linear scaling method was selected to alter the projected precipitation while air temperatures were bias corrected using the quantile mapping method. At the end of the 21st century (2090–2099) under the severe CO2 emission scenario (RCP 8.5), the maximum and minimum air temperatures could increase from 3.9 to 10.0 °C and 2.8 to 8.4 °C across the entire THP, respectively, while precipitation could decrease by ~7.5% relative to the historical (2000–2009) observed data. However, large uncertainties were found according to 19 GCM projections.
Highlights
Future climatic changes may have significant impacts on water resources and food production at regional and global scales [1,2]
This study aimed to (1) map the spatial and temporal patterns of precipitation, maximum air temperature, and minimum air temperature during 2000–2009, 2050–2059, and 2090–2099 time intervals using geospatial analysis; (2) determine the climate change trends and uncertainties for each of the 14 research-grade agro-meteorological stations according to 19 General Circulation Models (GCMs) projections; and (3) explore the possible impacts of future climate change on the Texas High Plains (THP)
The Texas Southern High Plains (TSHP) consists of 16 counties extending from northwest of Lubbock to Midland, while the Texas Northern High Plains (TNHP) region is comprised of 25 counties in the northern panhandle of the state
Summary
Future climatic changes may have significant impacts on water resources and food production at regional and global scales [1,2]. The increase of future temperatures can cause a reduced maturity period of corn, which could decrease time duration of corn to use solar radiation and assimilate CO2 and adversely influence the accumulation of corn biomass and final yield [14,15,16,17]. Climate change adaptation, such as alternative planting dates, land use change, and stress tolerant cultivars, can be time-consuming and costly. Assessing climate change trends under current and future climate scenarios enables the development of best agricultural management practices (BMPs) with potential adoption rates and strategies in the future, and the awareness, preparation, and precautionary actions of possible associated environmental issues
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