Abstract
Methane is the second most important greenhouse gas after carbon dioxide contributing to human-made global warming. Keeping to the Paris Agreement of staying well below two degrees warming will require a concerted effort to curb methane emissions in addition to necessary decarbonization of the energy systems. The fastest way to achieve emission reductions in the 2050 timeframe is likely through implementation of various technical options. The focus of this study is to explore the technical abatement and cost pathways for reducing global methane emissions, breaking reductions down to regional and sector levels using the most recent version of IIASA’s Greenhouse gas and Air pollution Interactions and Synergies (GAINS) model. The diverse human activities that contribute to methane emissions make detailed information on potential global impacts of actions at the regional and sectoral levels particularly valuable for policy-makers. With a global annual inventory for 1990–2015 as starting point for projections, we produce a baseline emission scenario to 2050 against which future technical abatement potentials and costs are assessed at a country and sector/technology level. We find it technically feasible in year 2050 to remove 54 percent of global methane emissions below baseline, however, due to locked in capital in the short run, the cumulative removal potential over the period 2020–2050 is estimated at 38 percent below baseline. This leaves 7.7 Pg methane released globally between today and 2050 that will likely be difficult to remove through technical solutions. There are extensive technical opportunities at low costs to control emissions from waste and wastewater handling and from fossil fuel production and use. A considerably more limited technical abatement potential is found for agricultural emissions, in particular from extensive livestock rearing in developing countries. This calls for widespread implementation in the 2050 timeframe of institutional and behavioural options in addition to technical solutions.
Highlights
Coal mining The methodology for estimating global CH4 emissions from coalmines in GAINSv4 has been described in detail in the Supplement of Höglund‐Isaksson (2012)
A general assumption is made in GAINSv4 that it is technically possible to keep CH4 concentration levels at a steady rate of at least 0.3 percent, and to install self‐ sustained ventilation air methane (VAM) oxidizers (Mattus and Källstrand, 2010), on 50 percent of the ventilation air emitted from underground coal mines in all countries
The corresponding weighted average composition in vol% is 60.1% CH4, 8.6% ethane, 17.9% propane, 12.0% other heavier hydrocarbons, and the rest being nitrogen gas and carbon dioxide. This is in contrast to the assumption in Höglund‐Isaksson (2017), where the vol% composition of Russian associated gas was taken to be 81% CH4, 5.5% ethane, 6.6% propane and 5.4% heavier hydrocarbons. Another update concern the recovery rate for Russian associated petroleum gas (APG), which with the recent data from NOAA (Elvidge et al, 2016) suggest that the volume of gas flared from Russian sources is 24.6 bc m 1980 1982 1984 1986 1988 1990 1992 1994 1996 1998 2000 2002 2004 2006 2008 2010 2012 2014 2016 bcm in 2016, down from 35.2 bcm in 2010
Summary
Solid/Liquid manure management; Enteric fermentation/Manure management modelled separately only for animals on liquid manure management; Animals by farmsize (0-15 LSU, 15-50 LSU, 50-100 LSU, 100-500 LSU, > 500 LSU). Mt coal mined hard coal/brown coal; pre-mining/during mining/post-mining kt CH4 no further sub-sectors
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