Abstract
Due to the alarming speed of global warming, greenhouse gas removal from atmosphere will be absolutely necessary in the coming decades. Methane is the second most harmful greenhouse gas in the atmosphere. There is an emerging technology proposed to incorporating photocatalysis with solar updraft Towers (SUT) to remove methane from the air at a planetary scale. In this study, we present a deep analysis by calculating the potential of methane removal in relation to the dimensions and configuration of SUT using different photocatalysts. The analysis shows that the methane removal rate increases with the SUT dimensions and can be enhanced by changing the configuration design. More importantly, the low methane removal rate on conventional TiO2 photocatalyst can be significantly improved to, for example, 42.5% on a more effective Ag-doped ZnO photocatalyst in a 200 MW SUT while the photocatalytic reaction is the rate limiting step. The factors that may further affect the removal of methane, such as more efficient photocatalysts, night operation and reaction zone are discussed as possible solutions to further improve the system.
Highlights
One of the grand challenges humankind is facing is global warming
The negative emission technologies (NETs) proposed until today are mainly based on carbon dioxide removal (CDR), but require safe and reliable sequestration of billions of tons of CO2, including capture, purification, compression and transportation to the storage sites (Kuramochi et al, 2012; Leung et al, 2014; Wetenhall et al, 2014; Kolster et al, 2017)
The analyses are based on the experimental results of the solar updraft Towers (SUT) in Spain collected in 1982 (Haaf et al, 1983; Haaf, 1984)
Summary
One of the grand challenges humankind is facing is global warming. The 2018 report of Intergovernmental Panel on Climate Change (IPCC) emphasizes the need for “rapid and farreaching” actions to curb carbon emission to limit global warming and climate change impact (Masson-Delmotte et al, 2018). By deeper analysis of the main relevant processes, this study, for the first time, presents such a comprehensive and reliable analysis of the effectiveness of SUT enabled photocatalysis for methane removal at planetary scale. HT Radius of tower, RT Mean radius of collector, Rc Average height of canopy, Hc Solar radiation Ambient temperature Temperature rise Velocity of air flow (load conditions) Velocity of air flow (release) Power output
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