====== 11.B - Forest Fires ======
===== Short Description =====
^ Method ^ AD ^ EF ^ Key Category ^
| CS, T2, T1 | CS | D | //not included in key category analysis// |
----
Legend
T = key source by Trend / L = key source by Level
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//Methods//
D: Default
RA: Reference Approach
T1: Tier 1 / Simple Methodology *
T2: Tier 2*
T3: Tier 3 / Detailed Methodology *
C: CORINAIR
CS: Country Specific
M: Model
as described in the EMEP/CORINAIR Emission Inventory Guidebook - 2019, in the group specific chapters.
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//AD:- Data Source for Activity Data //
NS: National Statistics
RS: Regional Statistics
IS: International Statistics
PS: Plant Specific data
AS: Associations, business organisations
Q: specific questionnaires, surveys
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//EF - Emission Factors//
D: Default (EMEP Guidebook)
C: Confidential
CS: Country Specific
PS: Plant Specific data
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====== Country specifics ======
===== Category 11.B – Forest fires =====
In Germany’s forests prescribed burning is not applied. Therefore, all forest fires are categorized as wildfires (include emissions from forest fires occurring naturally or caused by humans). - Note that emissions reported here are not accounted for the national totals.
==== Methodology ====
For calculating the emissions of wildfires a country specific Tier2 approach was used. The mass of carbon emitted M(C) was calculated using the adapted equation follows the methodology of Seiler and Crutzen (1980) ((Seiler, Wolfgang, and Paul J. Crutzen. "Estimates of gross and net fluxes of carbon between the biosphere and the atmosphere from biomass burning." Climatic change 2.3 (1980): 207-247.)).
{{ :sector:natural_sources:forest_fire.png?nolink&400}}
//M(C) = 0.45 * A * B * β//
where:
0.45 = average fraction of carbon in fuel wood;
A = forest area burnt in [m²];
B = mean above-ground biomass of fuel material per unit area in [kg/m²];
β = burning efficiency (fraction burnt) of the above-ground biomass.
The data on forest areas burnt for the period 1990 to 2020 have been taken from the German forest fire statistic (BLE, 2021)((BLE (Bundesanstalt für Landwirtschaft und Ernährung), (2021, 28. Juni), 2021: Waldbrandstatistik der Bundesrepublik Deutschland für das Jahr 2020, Bonn: 21 p. Retrieved July 2021, https://www.ble.de/DE/BZL/Daten-Berichte/Wald/wald_node.html)) managed by the Federal Agency for Agriculture and Food. The mean above-ground biomass was derived for each year by linear extrapolation and interpolation between the
* German National Forest Inventorys of 1987, 2002, 2012 (Bundeswaldinventuren 1987, 2002, 2012),
* [[https://www.thuenen.de/en/institutes/forest-ecosystems/projects/forest-monitoring/greenhouse-gas-inventory-for-forests/inventory-study-2008|the inventory study 2008]] and,
* [[https://www.thuenen.de/en/institutes/forest-ecosystems/projects/forest-monitoring/greenhouse-gas-inventory-for-forests/carbon-inventory-2017|the carbon inventory 2017]].
Pursuant to König (2007) ((König, H.-C., 2007. Waldbrandschutz - Kompendium für Forst und Feuerwehr. 1. Fachverlag Matthias Grimm, Berlin, 197 S.)), 80% of the forest fires in Germany are surface fires and 20% crown fires. In accordance to the IPCC Good Practice Guidance for LULUCF (2003) a burning efficiency of 0.15 was used for surface fires and an efficiency of 0.45 was used for crown fires.
The emissions for the pollutants were calculated by multiplying the mass of carbon with the respective emission factors from table 3-3 (EMEP/EEA, 2019)((EMEP/EEA, 2019: https://www.eea.europa.eu/publications/emep-eea-guidebook-2019/part-b-sectoral-guidance-chapters/11-natural-sources/11-b-forest-fires/view)).
For the calculation of particulate emissions (TSP, PM10 and PM2.5) the burnt biomass was multiplied with the respective emission factors from table 3-5 (EMEP/EEA, 2019). Those particulate emission factors have been estimated by averaging the emission factors from the US Environmental Protection Agency (USEPA, 1996) ((USEPA, 1996: Compilation of Air Pollutant Emission Factors Vol.1. Stationary, Point and Area Sources. Report AP-42, fifth edition)) methodology, since no better information is available. Those emission factors are assumed to be the same for all types of forest.
The Guidebook does not indicate whether EFs have considered the condensable component (with or without).
==== Activity data ====
The data on forest areas burnt for the period 1990 to 2020 are based on the German forest fire statistic (BLE, 2021) managed by the Federal Agency for Agriculture and Food.
__Table 1: Area of forest burnt from 1990 until the latest reporting year, in [ha]__
^ 1990 ^ 1991 ^ 1992 ^ 1993 ^ 1994 ^ 1995 ^ 1996 ^ 1997 ^ 1998 ^ 1999 ^
| 1,606 | 920 | 4,908 | 1,493 | 1,114 | 592 | 1,381 | 599 | 397 | 415 |
^ 2000 ^ 2001 ^ 2002 ^ 2003 ^ 2004 ^ 2005 ^ 2006 ^ 2007 ^ 2008 ^ 2009 ^
| 581 | 122 | 122 | 1,315 | 274 | 183 | 482 | 256 | 539 | 757 |
^ 2010 ^ 2011 ^ 2012 ^ 2013 ^ 2014 ^ 2015 ^ 2016 ^ 2017 ^ 2018 ^ 2019 ^
| 522 | 214 | 269 | 199 | 120 | 526 | 283 | 395 | 2,349 | 2,711 |
^ 2020 | | | | | | | | | |
| 368 | | | | | | | | | |
==== Emission factors ====
For the year 2020 the following estimated emission factors were applied:
__Table 2: Emission factors applied for 2020, in [kg/ha forest area burnt]__
^ ^ EF2020 ^
| NOx | 125.96 |
| CO | 4,492.47 |
| NMVOC | 396.8 |
| SOx | 30.23 |
| NH3 | 34.01 |
| TSP | 713.76 |
| PM10 | 461.84 |
| PM2.5 | 377.87 |
| BC | 34.01 |
In addition, a large-scale fire, which occurred in September 2018, is reported under 11.B. A detailed description can be found in the NIR
2020 in Chapter 6.8.2.5 ((NIR (2020): National Inventory Report 2020 for the German Greenhouse Gas Inventory 1990-2018. Available in April 2020)), because a large amount of CO2 emissions were released.
The burned area of the drained moor, which is used as a military facility, covered 1,221 ha. This fire was extensively investigated and documented by the Federal Office for Infrastructure, Environmental Protection and Services of the German Armed Forces. The emissions are calculated according to IPCC GL (2006), chapter 2, form 2.27 ((IPCC (Intergovernmental Panel on Climate Change) (2006): 2006 IPCC Guidelines for National Greenhouse Gas Inventories, Volume 4: Agriculture, Forestry and Other Land Use. Eds.: Eggleston S., Buendia L., Miwa K., Ngara T., Tanabe K. (Eds). IEA/OECD, IPCC National Greenhouse Gas Inventories Programme, Technical Support Unit, Hayama, Kanagawa, Japan. http://www.ipcc-nggip.iges.or.jp/public/2006gl/index.html)).
The product MB × Cf is set to 336 t d.m. ha-1 according to Table 2.6 and equation 2.7, 2013 IPCC Wetlands Supplement ((IPCC (Intergovernmental Panel on Climate Change) (2014b): 2013 Supplement to the IPCC Guidelines for National Greenhouse Gas Inventories: Wetlands. Hiraishi, T., Krug, T., Tanabe, K., Srivastava, N., Baasansuren, J., Fukuda, M. and Troxler, T.G.(eds). Published: IPCC, Switzerland http://www.ipcc-nggip.iges.or.jp/public/wetlands/index.html)), i.e. it is assumed that the moor was completely drained during the fire.
* MB = mass of fuel available for combustion, tonnes ha-1 (i.e. mass of dry organic soil fuel)
* Cf = combustion factor, dimensionless
For the calculation of CO emissions the EF according to Table 2.7, 2013 IPCC Wetlands Supplement 207 g (kg dm)-1, is taken into account resulting in 85 kt of CO.