Demonstrating Regional Climate and Meteorological Sensitivity in Landfill Methane Inventories from Historical Californian Databases

Advances in Environmental and Engineering Research Pub Date : 2022-12-20 DOI:10.21926/aeer.2204054

P. Dumble

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Abstract

The urgency to manage global methane emissions has been acknowledged with international pledges to reduce 2020 levels by 30% by 2030. Carbon management requires effective tools to monitor changes, including those from significant sources including waste disposed on land. The first order degradation model used to determine landfill methane emissions, has been described by researchers as highly variable, insensitive and inadequate, despite recent attempts to explain microclimate impacts on methane oxidation. The development of detailed regional inventories is hampered by these variables. The availability of historical waste management and meteorological data in California, enables a theoretical review and modelling of meteorological moisture changes with methane generation data in a region of decadal drought. This study identifies a novel approach in the modelling of regional optimisation of variable seasonal parameters of moisture and methane oxidation based on the adjustment of the methane correction factor (MCF) generally assumed to be MCF = 1 for managed sites, that is optimised as MCFsite ≠ 1 as the average regional MCFall sites, → 1 (Range: <1, ≥1). Regional annual unmitigated methane emitted in December 2010 after methane recovery, oxidation and flaring is estimated at 0.40 million tonnes, falling to 0.31 million tonnes in 2011 and back to 0.40 million tonnes in 2012 (Pr < 0.01, n = 370). as meteorological conditions returned to the changing decadal norm. Meteorological and climate sensitivity is demonstrated in relation to the regional water balance, spatial distribution of landfill site moisture levels, satellite imagery of 2012 wildfire intensity ranges, the 2011 El Nino impacts and independent data sources. The method provides accurate regional methane assessments inclusive of soil and cover material oxidation. This will primarily benefit developing countries where landfill remains a dominant option, enabling the development of database linked satellite monitoring and detailed regional landfill climate emission inventories.

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从历史加利福尼亚数据库中论证垃圾填埋场甲烷清单的区域气候和气象敏感性

管理全球甲烷排放的紧迫性已得到承认，国际社会承诺到2030年将2020年的水平减少30%。碳管理需要有效的工具来监测变化，包括来自陆地上处置的废物等重要来源的变化。用于确定垃圾填埋场甲烷排放的一级降解模型被研究人员描述为高度可变、不敏感和不充分，尽管最近试图解释小气候对甲烷氧化的影响。这些变数妨碍了详细区域清单的编制。加利福尼亚的历史废物管理和气象数据的可用性，使在十年干旱地区利用甲烷生成数据对气象湿度变化进行理论审查和建模成为可能。本研究确定了一种基于甲烷校正因子(MCF)调整的湿度和甲烷氧化变季节参数区域优化建模的新方法，该方法通常假设管理站点的甲烷校正因子(MCF) = 1，即MCFsite≠1时优化为平均区域MCFall站点→1(范围:<1，≥1)。2010年12月，经甲烷回收、氧化和燃除后，区域年度未减除甲烷排放量估计为40万吨，2011年降至31万吨，2012年回落至40万吨(Pr < 0.01, n = 370)。随着气象条件回归到变化的年代际标准。气象和气候敏感性与区域水平衡、填埋场湿度空间分布、2012年野火强度范围卫星图像、2011年厄尔尼诺影响和独立数据源有关。该方法提供准确的区域甲烷评估，包括土壤和覆盖材料氧化。这将主要使填埋仍然是主要选择的发展中国家受益，从而能够发展与数据库有关的卫星监测和详细的区域填埋气候排放清单。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advances in Environmental and Engineering Research

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