Abstract
An improvement of methods for the inventory of greenhouse gas (GHG) emissions is necessary to ensure effective control of commitments to emission reduction. The national inventory reports play an important role, but do not reflect specifics of regional processes of GHG emission and absorption for large-area countries. In this article, a GIS approach for the spatial inventory of GHG emissions in the energy sector, based on IPCC guidelines, official statistics on fuel consumption, and digital maps of the region under investigation, is presented. We include mathematical background for the spatial emission inventory of point, line and area sources, caused by fossil-fuel use for power and heat production, the residential sector, industrial and agricultural sectors, and transport. Methods for the spatial estimation of emissions from stationary and mobile sources, taking into account the specifics of fuel used and technological processes, are described. Using the developed GIS technology, the territorial distribution of GHG emissions, at the level of elementary grid cells 2 km × 2 km for the territory of Western Ukraine, is obtained. Results of the spatial analysis are presented in the form of a geo-referenced database of emissions, and visualized as layers of digital maps. Uncertainty of inventory results is calculated using the Monte Carlo approach, and the sensitivity analysis results are described. The results achieved demonstrated that the relative uncertainties of emission estimates, for CO2 and for total emissions (in CO2 equivalent), depend largely on uncertainty in the statistical data and on uncertainty in fuels’ calorific values. The uncertainty of total emissions stays almost constant with the change of uncertainty of N2O emission coefficients, and correlates strongly with an improvement in knowledge about CH4 emission processes. The presented approach provides an opportunity to create a spatial cadastre of emissions, and to use this additional knowledge for the analysis and reduction of uncertainty. It enables us to identify territories with the highest emissions, and estimate an influence of uncertainty of the large emission sources on the uncertainty of total emissions. Ascribing emissions to the places where they actually occur helps to improve the inventory process and to reduce the overall uncertainty.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Bucki R (2010) Modelling synthetic environment control. Artificial Intelligence 4:315–321
Bun A (2009) Methods and tools for analysis of greenhouse gas emission processes in consideration of input data uncertainty. Dissertation, Lviv Polytechnic National University
Bun R, Hamal KH, Gusti M, Bun A (2010) Spatial GHG inventory on regional level: Accounting for uncertainty. Climatic Change 103:227–244
Feliciano D, Slee B, Hunter C, Smith P (2013) Estimating the contribution of rural land uses to greenhouse gas emissions: A case study of North East Scotland. Environmental Science & Policy 25:36–49
Hamal K (2008) Carbon dioxide emissions inventory with GIS. Artificial Intelligence 3:55–62
Hamal Kh (2009) Geoinformation technology for spatial analysis of greenhouse gas emissions in Energy sector. Dissertation, Lviv Polytechnic National University
Horabik J, Nahorski Z (2010) A statistical model for spatial inventory data: a case study of N2O emissions in municipalities of southern Norway. Climatic Change 103:263–276
Horabik J, Nahorski Z (2014) Improving resolution of spatial inventory with a statistical inference approach. This issue.
IPCC (2006) IPCC Guidelines for National Greenhouse Gas Inventories, Prepared by the National Greenhouse Gas Inventories Programme, Eggleston HS, Buendia L, Miwa K, Ngara T, Tanabe K (eds).
Joerss W (2014) Determination of the uncertainties of the German emission inventories for particulate matter and aerosol precursors using Monte-Carlo analysis. This issue.
Jonas M, White T, Marland G, Lieberman D, Nahorski Z, Nilsson S (2010) Dealing with uncertainty in GHG inventories: How to go about it? Lecture Notes in Economics and Mathematical Systems 633:229–245
Jonas M, Krey V, Wagner F, Marland G, Nahorski Z (2014) Uncertainty in an emissions constrained world. This issue.
Lesiv M (2011) Mathematical modeling and spatial analysis of greenhouse gas emissions in regions bordering Ukraine. Dissertation, Lviv Polytechnic National University
Lesiv M, Bun A, Jonas M (2014) Analysis of change in total uncertainty in GHG emissions for the EU-15 countries. This issue.
Marland G, Hamal K, Jonas M (2009) How uncertain are estimates of CO2 emissions? Journal of Industrial Ecology 13:4–7
Mendoza D, Gurney K, Geethakumar S, Chandrasekaran V, Zhou Y, Razlivanov I (2013) Implications of uncertainty on regional CO2 mitigation policies for the U.S. onroad sector based on a high-resolution emissions estimate. Energy Policy 55:386–395
Nahorski Z, Horabik J, Jonas M (2007) Compliance and emissions trading under the Kyoto protocol: Rules for uncertain inventories. Water, Air, and Soil Pollution: Focus 7(4–5):539–558
TSLR (2009) Transport Statistics of Lviv Region: Statistical Yearbook. Main Statistical Agency of Lviv Region, Lviv
Uvarova N, Paramonov S, Gytarsky M (2014) The improvement of greenhouse gas inventory as a tool for reduction emission uncertainties for operations with oil in the Russian Federation. This issue.
Winiwarter W (2007) National greenhouse gas inventories: understanding uncertainties versus potential for improving reliability. Water Air Soil Pollution: Focus 7:443–450
Yohe G, Oppenheimer M (2011) Evaluation, characterization, and communication of uncertainty by the intergovernmental panel on climate change – an introductory essay. Climatic Change 108:629–639
Acknowledgments
The study was conducted within the 7FP Marie Curie Actions IRSES project No. 247645, and was partially supported by Ministry of Education and Science of Ukraine.
Author information
Authors and Affiliations
Corresponding author
Additional information
This article is part of a Special Issue on “Third International Workshop on Uncertainty in Greenhouse Gas Inventories” edited by Jean Ometto and Rostyslav Bun.
Electronic supplementary material
Below is the link to the electronic supplementary material.
ESM 1
(PDF 900 kb)
Rights and permissions
About this article
Cite this article
Boychuk, K., Bun, R. Regional spatial inventories (cadastres) of GHG emissions in the Energy sector: Accounting for uncertainty. Climatic Change 124, 561–574 (2014). https://doi.org/10.1007/s10584-013-1040-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10584-013-1040-9