Simulated, future total annual discharge for the ACF and ACT rivers (left) and for the Coosa River below Plant Hammond and the Chattahoochee River below Plant Wansley
D Yates
J Meldrum
F Flores-Lopez
Michelle Davis
10.6084/m9.figshare.1011876.v1
https://iop.figshare.com/articles/figure/_Simulated_future_total_annual_discharge_for_the_ACF_and_ACT_rivers_left_and_for_the_Coosa_River_bel/1011876
<p><strong>Figure 6.</strong> Simulated, future total annual discharge for the ACF and ACT rivers (left) and for the Coosa River below Plant Hammond and the Chattahoochee River below Plant Wansley. The dashed line is the historic average of the river flows for the period 1950–2010 and the solid, thin lines are the trend through the future simulated series.</p> <p><strong>Abstract</strong></p> <p>Recent studies on the relationship between thermoelectric cooling and water resources have been made at coarse geographic resolution and do not adequately evaluate the localized water impacts on specific rivers and water bodies. We present the application of an integrated electricity generation–water resources planning model of the Apalachicola/Chattahoochee/Flint (ACF) and Alabama–Coosa–Tallapoosa (ACT) rivers based on the regional energy deployment system (ReEDS) and the water evaluation and planning (WEAP) system. A future scenario that includes a growing population and warmer, drier regional climate shows that benefits from a low-carbon, electricity fuel-mix could help maintain river temperatures below once-through coal-plants. These impacts are shown to be localized, as the cumulative impacts of different electric fuel-mix scenarios are muted in this relatively water-rich region, even in a warmer and drier future climate.</p>
2013-09-11 00:00:00
future scenario
water bodies
Plant Wansley
river flows
water evaluation
drier future climate
ACT rivers
river temperatures
water impacts
electricity
water resources
weap
planning
Chattahoochee River
Coosa River
Plant Hammond
acf
energy deployment system
Environmental Science