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Toward a versatile spaceborne architecture for immediate monitoring of the global methane pledge

Yuchen Wang, Xvli Guo, Yajie Huo, Mengying Li, Yuqing Pan, Shaocai Yu, Alexander Baklanov, Daniel Rosenfeld, John H. Seinfeld, Pengfei Li

2023Atmospheric chemistry and physics10 citationsDOIOpen Access PDF

Abstract

Abstract. The global methane pledge paves a fresh, critical way toward carbon neutrality. However, it remains largely invisible and highly controversial due to the fact that planet-scale and plant-level methane retrievals have rarely been coordinated. This has never been more essential within the narrow window to reach the Paris target. Here we present a two-tiered spaceborne architecture to address this issue. Using this framework, we focused on the United States, China, the Middle East, and North Africa, and simultaneously uncovered methane-abundant regions and plumes. These include new super-emitters, potential leakages, and unprecedented multiple plumes in a single source. More importantly, this framework is shown to challenge official emission reports that possibly mislead estimates from global, regional, and site scales, particularly by missing super-emitters. Our results show that, in principle, the above framework can be extended to be multi-tiered by adding upcoming stereoscopic measurements and suitable artificial intelligence, and thus it is sufficiently versatile for immediate and future monitoring of the global methane pledge.

Topics & Concepts

PledgeMethaneEnvironmental scienceRemote sensingScale (ratio)Greenhouse gasArchitectureComputer scienceMeteorologyGeologyGeographyPolitical scienceCartographyLawEcologyOceanographyArchaeologyBiologyAtmospheric and Environmental Gas DynamicsAtmospheric chemistry and aerosolsHydrocarbon exploration and reservoir analysis
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