The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005

S. Luyssaert; G. Abril; R. Andres; D. Bastviken; V. Bellassen; P. Bergamaschi; P. Bousquet; F. Chevallier; P. Ciais; M. Corazza; R. Dechow; K.-H. Erb; G. Etiope; A. Fortems-Cheiney; G. Grassi; J. Hartmann; M. Jung; J. Lathière; A. Lohila; E. Mayorga; N. Moosdorf; D. S. Njakou; J. Otto; D. Papale; W. Peters; P. Peylin; P. Raymond; C. Rödenbeck; S. Saarnio; E.-D. Schulze; S. Szopa; R. Thompson; P. J. Verkerk; N. Vuichard; R. Wang; M. Wattenbach; S. Zaehle

doi:10.5194/bg-9-3357-2012

The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005

S. Luyssaert, G. Abril, R. Andres, D. Bastviken, V. Bellassen, P. Bergamaschi, P. Bousquet, F. Chevallier, P. Ciais, M. Corazza, R. Dechow, K.-H. Erb, G. Etiope, A. Fortems-Cheiney, G. Grassi, J. Hartmann, M. Jung, J. Lathière, A. Lohila, E. MayorgaN. Moosdorf, D. S. Njakou, J. Otto, D. Papale, W. Peters, P. Peylin, P. Raymond, C. Rödenbeck, S. Saarnio, E.-D. Schulze, S. Szopa, R. Thompson, P. J. Verkerk, N. Vuichard, R. Wang, M. Wattenbach, S. Zaehle

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Abstract

Globally, terrestrial ecosystems have absorbed about 30% of anthropogenic greenhouse gas emissions over the period 2000-2007 and inter-hemispheric gradients indicate that a significant fraction of terrestrial carbon sequestration must be north of the Equator. We present a compilation of the CO2, CO, CH4 and N2O balances of Europe following a dual constraint approach in which (1) a land-based balance derived mainly from ecosystem carbon inventories and (2) a land-based balance derived from flux measurements are compared to (3) the atmospheric data-based balance derived from inversions constrained by measurements of atmospheric GHG (greenhouse gas) concentrations. Good agreement between the GHG balances based on fluxes (1294 ± 545 Tg C in CO2-eq yr-1), inventories (1299 ± 200 Tg C in CO2-eq yr-1) and inversions (1210 ± 405 Tg C in CO2-eq yr-1) increases our confidence that the processes underlying the European GHG budget are well understood and reasonably sampled. However, the uncertainty remains large and largely lacks formal estimates. Given that European net land to atmosphere exchanges are determined by a few dominant fluxes, the uncertainty of these key components needs to be formally estimated before efforts could be made to reduce the overall uncertainty. The net land-to-atmosphere flux is a net source for CO2, CO, CH4 and N2O, because the anthropogenic emissions by far exceed the biogenic sink strength. The dual-constraint approach confirmed that the European biogenic sink removes as much as 205 ± 72 Tg C yr-1 from fossil fuel burning from the atmosphere. However, This C is being sequestered in both terrestrial and inland aquatic ecosystems. If the C-cost for ecosystem management is taken into account, the net uptake of ecosystems is estimated to decrease by 45% but still indicates substantial C-sequestration. However, when the balance is extended from CO2 towards the main GHGs, C-uptake by terrestrial and aquatic ecosystems is offset by emissions of non-CO2 GHGs. As such, the European ecosystems are unlikely to contribute to mitigating the effects of climate change.

Original language	English
Pages (from-to)	3357-3380
Number of pages	24
Journal	Biogeosciences
Volume	9
Issue number	8
DOIs	https://doi.org/10.5194/bg-9-3357-2012
Publication status	Published - 24-Aug-2012
Externally published	Yes

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Luyssaert, S., Abril, G., Andres, R., Bastviken, D., Bellassen, V., Bergamaschi, P., Bousquet, P., Chevallier, F., Ciais, P., Corazza, M., Dechow, R., Erb, K.-H., Etiope, G., Fortems-Cheiney, A., Grassi, G., Hartmann, J., Jung, M., Lathière, J., Lohila, A., ... Zaehle, S. (2012). The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005. Biogeosciences, 9(8), 3357-3380. https://doi.org/10.5194/bg-9-3357-2012

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title = "The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005",

abstract = "Globally, terrestrial ecosystems have absorbed about 30% of anthropogenic greenhouse gas emissions over the period 2000-2007 and inter-hemispheric gradients indicate that a significant fraction of terrestrial carbon sequestration must be north of the Equator. We present a compilation of the CO2, CO, CH4 and N2O balances of Europe following a dual constraint approach in which (1) a land-based balance derived mainly from ecosystem carbon inventories and (2) a land-based balance derived from flux measurements are compared to (3) the atmospheric data-based balance derived from inversions constrained by measurements of atmospheric GHG (greenhouse gas) concentrations. Good agreement between the GHG balances based on fluxes (1294 ± 545 Tg C in CO2-eq yr-1), inventories (1299 ± 200 Tg C in CO2-eq yr-1) and inversions (1210 ± 405 Tg C in CO2-eq yr-1) increases our confidence that the processes underlying the European GHG budget are well understood and reasonably sampled. However, the uncertainty remains large and largely lacks formal estimates. Given that European net land to atmosphere exchanges are determined by a few dominant fluxes, the uncertainty of these key components needs to be formally estimated before efforts could be made to reduce the overall uncertainty. The net land-to-atmosphere flux is a net source for CO2, CO, CH4 and N2O, because the anthropogenic emissions by far exceed the biogenic sink strength. The dual-constraint approach confirmed that the European biogenic sink removes as much as 205 ± 72 Tg C yr-1 from fossil fuel burning from the atmosphere. However, This C is being sequestered in both terrestrial and inland aquatic ecosystems. If the C-cost for ecosystem management is taken into account, the net uptake of ecosystems is estimated to decrease by 45% but still indicates substantial C-sequestration. However, when the balance is extended from CO2 towards the main GHGs, C-uptake by terrestrial and aquatic ecosystems is offset by emissions of non-CO2 GHGs. As such, the European ecosystems are unlikely to contribute to mitigating the effects of climate change.",

author = "S. Luyssaert and G. Abril and R. Andres and D. Bastviken and V. Bellassen and P. Bergamaschi and P. Bousquet and F. Chevallier and P. Ciais and M. Corazza and R. Dechow and K.-H. Erb and G. Etiope and A. Fortems-Cheiney and G. Grassi and J. Hartmann and M. Jung and J. Lathi{\`e}re and A. Lohila and E. Mayorga and N. Moosdorf and Njakou, {D. S.} and J. Otto and D. Papale and W. Peters and P. Peylin and P. Raymond and C. R{\"o}denbeck and S. Saarnio and E.-D. Schulze and S. Szopa and R. Thompson and Verkerk, {P. J.} and N. Vuichard and R. Wang and M. Wattenbach and S. Zaehle",

year = "2012",

month = aug,

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doi = "10.5194/bg-9-3357-2012",

language = "English",

volume = "9",

pages = "3357--3380",

journal = "Biogeosciences",

issn = "1726-4170",

publisher = "COPERNICUS GESELLSCHAFT MBH",

number = "8",

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Luyssaert, S, Abril, G, Andres, R, Bastviken, D, Bellassen, V, Bergamaschi, P, Bousquet, P, Chevallier, F, Ciais, P, Corazza, M, Dechow, R, Erb, K-H, Etiope, G, Fortems-Cheiney, A, Grassi, G, Hartmann, J, Jung, M, Lathière, J, Lohila, A, Mayorga, E, Moosdorf, N, Njakou, DS, Otto, J, Papale, D, Peters, W, Peylin, P, Raymond, P, Rödenbeck, C, Saarnio, S, Schulze, E-D, Szopa, S, Thompson, R, Verkerk, PJ, Vuichard, N, Wang, R, Wattenbach, M & Zaehle, S 2012, 'The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005', Biogeosciences, vol. 9, no. 8, pp. 3357-3380. https://doi.org/10.5194/bg-9-3357-2012

TY - JOUR

T1 - The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005

AU - Luyssaert, S.

AU - Abril, G.

AU - Andres, R.

AU - Bastviken, D.

AU - Bellassen, V.

AU - Bergamaschi, P.

AU - Bousquet, P.

AU - Chevallier, F.

AU - Ciais, P.

AU - Corazza, M.

AU - Dechow, R.

AU - Erb, K.-H.

AU - Etiope, G.

AU - Fortems-Cheiney, A.

AU - Grassi, G.

AU - Hartmann, J.

AU - Jung, M.

AU - Lathière, J.

AU - Lohila, A.

AU - Mayorga, E.

AU - Moosdorf, N.

AU - Njakou, D. S.

AU - Otto, J.

AU - Papale, D.

AU - Peters, W.

AU - Peylin, P.

AU - Raymond, P.

AU - Rödenbeck, C.

AU - Saarnio, S.

AU - Schulze, E.-D.

AU - Szopa, S.

AU - Thompson, R.

AU - Verkerk, P. J.

AU - Vuichard, N.

AU - Wang, R.

AU - Wattenbach, M.

AU - Zaehle, S.

PY - 2012/8/24

Y1 - 2012/8/24

N2 - Globally, terrestrial ecosystems have absorbed about 30% of anthropogenic greenhouse gas emissions over the period 2000-2007 and inter-hemispheric gradients indicate that a significant fraction of terrestrial carbon sequestration must be north of the Equator. We present a compilation of the CO2, CO, CH4 and N2O balances of Europe following a dual constraint approach in which (1) a land-based balance derived mainly from ecosystem carbon inventories and (2) a land-based balance derived from flux measurements are compared to (3) the atmospheric data-based balance derived from inversions constrained by measurements of atmospheric GHG (greenhouse gas) concentrations. Good agreement between the GHG balances based on fluxes (1294 ± 545 Tg C in CO2-eq yr-1), inventories (1299 ± 200 Tg C in CO2-eq yr-1) and inversions (1210 ± 405 Tg C in CO2-eq yr-1) increases our confidence that the processes underlying the European GHG budget are well understood and reasonably sampled. However, the uncertainty remains large and largely lacks formal estimates. Given that European net land to atmosphere exchanges are determined by a few dominant fluxes, the uncertainty of these key components needs to be formally estimated before efforts could be made to reduce the overall uncertainty. The net land-to-atmosphere flux is a net source for CO2, CO, CH4 and N2O, because the anthropogenic emissions by far exceed the biogenic sink strength. The dual-constraint approach confirmed that the European biogenic sink removes as much as 205 ± 72 Tg C yr-1 from fossil fuel burning from the atmosphere. However, This C is being sequestered in both terrestrial and inland aquatic ecosystems. If the C-cost for ecosystem management is taken into account, the net uptake of ecosystems is estimated to decrease by 45% but still indicates substantial C-sequestration. However, when the balance is extended from CO2 towards the main GHGs, C-uptake by terrestrial and aquatic ecosystems is offset by emissions of non-CO2 GHGs. As such, the European ecosystems are unlikely to contribute to mitigating the effects of climate change.

AB - Globally, terrestrial ecosystems have absorbed about 30% of anthropogenic greenhouse gas emissions over the period 2000-2007 and inter-hemispheric gradients indicate that a significant fraction of terrestrial carbon sequestration must be north of the Equator. We present a compilation of the CO2, CO, CH4 and N2O balances of Europe following a dual constraint approach in which (1) a land-based balance derived mainly from ecosystem carbon inventories and (2) a land-based balance derived from flux measurements are compared to (3) the atmospheric data-based balance derived from inversions constrained by measurements of atmospheric GHG (greenhouse gas) concentrations. Good agreement between the GHG balances based on fluxes (1294 ± 545 Tg C in CO2-eq yr-1), inventories (1299 ± 200 Tg C in CO2-eq yr-1) and inversions (1210 ± 405 Tg C in CO2-eq yr-1) increases our confidence that the processes underlying the European GHG budget are well understood and reasonably sampled. However, the uncertainty remains large and largely lacks formal estimates. Given that European net land to atmosphere exchanges are determined by a few dominant fluxes, the uncertainty of these key components needs to be formally estimated before efforts could be made to reduce the overall uncertainty. The net land-to-atmosphere flux is a net source for CO2, CO, CH4 and N2O, because the anthropogenic emissions by far exceed the biogenic sink strength. The dual-constraint approach confirmed that the European biogenic sink removes as much as 205 ± 72 Tg C yr-1 from fossil fuel burning from the atmosphere. However, This C is being sequestered in both terrestrial and inland aquatic ecosystems. If the C-cost for ecosystem management is taken into account, the net uptake of ecosystems is estimated to decrease by 45% but still indicates substantial C-sequestration. However, when the balance is extended from CO2 towards the main GHGs, C-uptake by terrestrial and aquatic ecosystems is offset by emissions of non-CO2 GHGs. As such, the European ecosystems are unlikely to contribute to mitigating the effects of climate change.

U2 - 10.5194/bg-9-3357-2012

DO - 10.5194/bg-9-3357-2012

M3 - Article

SN - 1726-4170

VL - 9

SP - 3357

EP - 3380

JO - Biogeosciences

JF - Biogeosciences

IS - 8

ER -

The European land and inland water CO2, CO, CH4 and N2O balance between 2001 and 2005

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