Abstract
Thermoelectric generation contributes to 80% of global electricity production. Cooling of thermoelectric plants is often achieved by water abstractions from the natural environment. In England and Wales, the electricity sector is responsible for approximately half of all water abstractions and 40% of non-tidal surface water abstractions. We present a model that quantifies current water use of the UK electricity sector and use it to test six decarbonisation pathways to 2050. The pathways consist of a variety of generation technologies, with associated cooling methods, water use factors and cooling water sources. We find that up to 2030, water use across the six pathways is fairly consistent and all achieve significant reductions in both carbon and water intensity, based upon a transition to closed loop and hybrid cooling systems. From 2030 to 2050 our results diverge. Pathways with high levels of carbon capture and storage result in freshwater consumption that exceeds current levels (37–107%), and a consumptive intensity that is 30–69% higher. Risks to the aquatic environment will be intensified if generation with carbon capture and storage is clustered. Pathways of high nuclear capacity result in tidal and coastal abstraction that exceed current levels by 148–399%. Whilst reducing freshwater abstractions, the marine environment will be impacted if a shortage of coastal sites leads to clustering of nuclear reactors and concentration of heated water discharges. The pathway with the highest level of renewables has both lowest abstraction and consumption of water. Freshwater consumption can also be minimised through use of hybrid cooling, which despite marginally higher costs and emissions, would reduce dependence on scarce water resources thus increase security of supply.
Highlights
Introduction80% of electricity generation comes from thermoelectric power stations (such as fossil fuels and nuclear), all of which require cooling for efficient and safe operation (International Energy Agency, 2009)
80% of electricity generation comes from thermoelectric power stations, all of which require cooling for efficient and safe operation (International Energy Agency, 2009)
First we present a comprehensive set of results that breakdown the water abstraction and consumption of current UK thermoelectric capacity and generation (Table 5)
Summary
80% of electricity generation comes from thermoelectric power stations (such as fossil fuels and nuclear), all of which require cooling for efficient and safe operation (International Energy Agency, 2009). Most of this cooling is provided by water abstractions from, and thermal discharges to, the natural environment, including rivers, tidal estuaries and coasts. Electricity sector abstractions can be in the order of 40% of abstractions from freshwater sources Freshwater resources and the marine environment are under increasing pressure, primarily from growing populations and changing socioeconomic conditions (Vorosmarty, 2000), and climate change (Arnell et al, 2001; Kundzewicz et al, 2007)
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