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Africa and the global carbon cycle

Abstract

The African continent has a large and growing role in the global carbon cycle, with potentially important climate change implications. However, the sparse observation network in and around the African continent means that Africa is one of the weakest links in our understanding of the global carbon cycle. Here, we combine data from regional and global inventories as well as forward and inverse model analyses to appraise what is known about Africa's continental-scale carbon dynamics. With low fossil emissions and productivity that largely compensates respiration, land conversion is Africa's primary net carbon release, much of it through burning of forests. Savanna fire emissions, though large, represent a short-term source that is offset by ensuing regrowth. While current data suggest a near zero decadal-scale carbon balance, interannual climate fluctuations (especially drought) induce sizeable variability in net ecosystem productivity and savanna fire emissions such that Africa is a major source of interannual variability in global atmospheric CO2. Considering the continent's sizeable carbon stocks, their seemingly high vulnerability to anticipated climate and land use change, as well as growing populations and industrialization, Africa's carbon emissions and their interannual variability are likely to undergo substantial increases through the 21st century.

Background

Africa stands out among continents for widespread and deeply entrenched poverty, slow economic development, and agricultural systems prone to failure during frequent and persistent droughts [1]. Africa is also home to some rapidly developing economies, tremendous natural resources and remarkable social and ecological diversity. The unique history of Africa, the close dependencies of people on natural resources and a future that will certainly include substantial industrial, agricultural and social development, suggest that Africa will become a key player in the carbon cycle of the 21st century. However, our knowledge about Africa's current role in the global carbon cycle remains remarkably limited. We currently do not know whether Africa is a net sink or source of atmospheric carbon, and have only vague indications of the continent's temporal and spatial patterns of carbon exchange. Given the current development agenda that is intended to elevate Africa's importance in the global economy [2], it is time to focus as well on Africa's role in the global carbon cycle. Here we review what is known about Africa's carbon dynamics from regional and global inventories, and forward and inverse model analyses, and highlight some of the unique features of Africa's contribution to global carbon fluxes.

The diverse elements of the global carbon cycle have been the focus of much recent research [3–5]; research that is vital to our understanding of the missing carbon sink, future atmospheric carbon dioxide concentrations, and future climate [6–8]. Much of that research has concentrated on carbon dynamics of the large ocean basins [9, 10] and terrestrial exchange in North America [11, 12] and Eurasia [13, 14]. Despite representing 20% of the global land mass, Africa has thus far been largely neglected in these studies. Africa contributes a disproportionately small fraction of the global fossil fuel carbon emissions that are responsible for rising atmospheric carbon dioxide concentrations, with 14% of global population [15], but only 3% of fossil emissions [16]. In contrast, Africa plays a globally important role in fire and land use carbon emissions, though the magnitudes of these terms are highly uncertain.

To date, continental assessments of Africa's carbon dynamics are primarily model-based. Plausible estimates of Africa's regional sources and sinks can potentially be supplied by atmospheric inversion using global CO2 concentration measurements and atmospheric transport models. However such 'top-down' solutions have large uncertainties, particularly for Africa and other tropical regions, due to the paucity of appropriately located CO2 concentration measurements [17, 18]. Existing data are also insufficient to partition carbon sources and sinks within Africa, and inversion techniques provide little insight regarding mechanisms responsible for net uptake and release of carbon in space and time [17, 19, 20]. The alternative approach is to perform spatially, temporally and source-differentiated 'bottom-up' estimation using biogeochemical models. However, such regional carbon flux estimates are only weakly supported by the sparse network of place-based observations, and thus are largely founded on models that have been parameterized and evaluated with extra-African observations. The resultant uncertainty reduces our ability to resolve African and global carbon sources and sinks, and hinders wise resource management in Africa for greenhouse gas mitigation.

With the hope of identifying carbon cycle research priorities that may be met through focused research efforts, we synthesize current understanding of carbon stocks and fluxes within Africa, highlight uncertainties in those terms, and diagnose where uncertainty in our knowledge of the African carbon cycle impacts our ability to assess global carbon dynamics. We then outline where new measurements and further research are most likely to contribute understanding of African and global carbon cycling, and discuss implications for African involvement in international climate change agreements.

Africa in the Balance

Africa is second only to Eurasia in continental surface area. It has large areas of moist tropical forest, seasonal and semi-arid woodland, savanna, grassland and desert, as well as smaller regions of Mediterranean and montane vegetation in extra-tropical and high elevation areas (Figure 1).

Figure 1
figure 1

Latitudinal distribution of mean annual precipitation [72], soil [78] and plant [84] carbon density, annual net primary production (NPP) per unit ground area from CASA [23, 26] and the Potsdam 17-model intercomparison [89], total soil and live carbon, total annual NPP, shown with the spatial distribution of land cover [106] (colors). Means and totals were calculated from published data using all terrestrial locations in 5° latitude zones.

Initial estimates [21] of carbon stocks and the various flux pathways (Table 1, Figure 2) suggest that the continent plays a significant role in atmospheric CO2 dynamics at time scales ranging from sub-seasonal to decadal and longer. The balance of terms in Figure 2 should not be interpreted as identifying a large net biotic source for the continent but rather that independent studies which estimate the magnitude of fluxes associated with individual pathways can not be used in a budget calculation without careful consideration of the processes represented in each estimate and the associated uncertainties. For example, biomass burning emissions are not modeled explicitly in many biogeochemical or biophysical models and may thus be effectively lumped into heterotrophic respiration.

Figure 2
figure 2

The African carbon cycle. Annual fluxes and pools (shown in parentheses) all in units of 1015 g C, where NPP is net primary production, and Rh is heterotrophic respiration. Estimates as reported in Table 1

Table 1 Global terrestrial and African carbon stocks and fluxes representative of the 1990s.

Patterns of soil and vegetation carbon stocks and net primary production (NPP) are highly correlated with annual rainfall (Figure 1). Africa's fraction of global annual NPP is estimated to be similar to the fractional terrestrial area of the continent (Table 1 and Figure 1); the large unproductive arid regions are compensated by high productivity in forests and woodlands. Carbon stocks and NPP per unit land area center on the equator and decline to the north and south toward increasingly arid environments. However, greater land area in Africa's northern hemisphere cause latitudinally summed C stocks and NPP to peak north of the equator (Figure 1).

African fossil fuel emissions are a tiny fraction of global totals, even when normalized by land area or human population (Table 1), while renewable energy sources (wood, charcoal) are a substantial component of domestic emissions. With low fossil emissions, Africa's current continental scale carbon fluxes are dominated by biogenic uptake and release from terrestrial ecosystems as well as pyrogenic emissions in savanna and forest fires. As is generally true globally, the continent's large carbon uptake from photosynthesis is offset by an equivalently large respiration flux, leading to near-zero net biotic flux at multi-year or longer timescales. In spite of these broad patterns, estimates can differ widely between studies (Table 1) and temporal variability is large.

Bottom-up simulation models [22–24] indicate large interannual variation in Africa's net ecosystem carbon exchange (NEE), with an interannual variability (expressed as the standard deviation of annual NPP) that is approximately 50% of the variability estimated for the global land mass (Figure 3), primarily induced by climate fluctuations [24]. Particularly large between-year coefficients of variation in NPP are found for Africa's woodlands, savannas, and grasslands, according to one model incorporating satellite measurements of vegetation activity [25, 26].

Figure 3
figure 3

Standard deviation of net ecosystem carbon exchange (NEE) estimated with three ecosystem models, High Resolution Biosphere Model (HRBM), Terrestrial Ecosystem Model (TEM), and Lund-Potsdam-Jena model (LPJ) as reported by McGuire et al. [24].

Africa plays a global role in C emissions through land use and fire (Table 1), though lack of information from the limited number of studies on the continent [e.g. [27–31]] restricts confidence in their magnitudes. Deforestation is the largest term in current assessments of tropical land use emissions [32], with Africa contributing 25% to 35% of total tropical land clearing from deforestation, and as much as 0.37 Pg C y-1, in the last decades [32, 33]. Carbon losses through deforestation tend to be 'permanent' in Africa, as afforestation and reforestation rates are modest, at less than 5% of annual deforestation [32]. The associated net release of carbon from land use in sub-Saharan Africa is estimated to be 0.4 Pg C y-1, or 20% of the tropical total, nearly all attributed to deforestation [32]. Annual net C emissions from conversion to agriculture and cultivation practices alone are estimated [24] to be about 0.8 Pg C y-1 for tropical land masses, but only 0.1 Pg C y-1 from Africa [24, 31], where shifting cultivation is prevalent [31].

Lack of information prohibits even the best land use change C emissions assessments from including all of the terms anticipated to be important for Africa. Pastoralism, shifting cultivation, and domestic wood harvest are widespread across the continent, but are often assumed to be inconsequential or are not considered [e.g. [32]], such that land use and land use change emissions from Africa are likely to be underestimated. Recent work [31] explicitly simulates aspects of these practices, though still focuses exclusively on forest and cropland conversions, missing land use change C emissions in Africa's vast savannas and grasslands which are home to much of the continent's livestock and the center of Africa's cereal and grain production. Furthermore, net C fluxes associated with changes in land use practices but not involving land conversion, such as management of tillage, slash, crop residues, and crop rotation, are refinements currently missing from continental scale land use change assessments. Finally, much of Africa, particularly in the semi-arid regions, is vulnerable to degradation, that may be the result of periodic drought or caused by agricultural and pastoral activities, releasing presumably large but unknown amounts of CO2 from cleared and dead vegetation [34] as well as possibly triggering strong biophysical feedbacks to the climate system [35] that may accelerate warming and prolong droughts [36–38].

Fire and land use emissions of carbon are entwined, especially in the humid and subhumid forest areas where fire is a primary tool for land transformation. Fire emissions associated with deforestation, shifting cultivation, burning of agricultural residues, and fuelwood may be as large as 2 Pg C y-1 globally and 0.4 Pg C y-1 for Africa, each of similar magnitude to estimates of total land use-related C emissions from those regions (Table 1). Consequently, estimates of land use change and deforestation C emissions already include, at least in theory, the associated fire emissions. New methods to estimate fire emissions using satellite sensors and atmospheric carbon monoxide measurements [39, 40] will improve our ability to diagnose C emissions in fires.

Fire is also a common dry season occurrence in the seasonal savannas that encircle the humid forest zone. Carbon emissions in savanna fires represent a much shorter-term C loss than forest fires, since the main fuel is dead herbaceous vegetation, representing just one or two years of growth [27, 41]. Thus savanna fires may only lead to faster cycling of biomass carbon rather than a net emission. Even if carbon emissions from savanna fires are roughly balanced over the long-term by growth in subsequent years, fires provide intense and localized injections of carbon into the atmosphere potentially shifting the seasonal or interannual distribution of CO2 releases [27, 41]. Given the large magnitude of these fluxes in Africa, even fairly small (e.g. 20%) variation in year to year total fluxes could translate into annual variation in pyrogenic fluxes of 300 Tg of C or more. Correspondingly, recent results suggest that biomass burning is the largest source of interannual variability in land-atmosphere carbon fluxes [42].

Unlike respiration, fires return carbon to the atmosphere as a wide range of compounds, some of which are chemically or radiatively active (e.g. methane, carbon monoxide and aerosols), or are precursors to radiatively active gases (e.g. ozone precursors). Methane and other hydrocarbons, carbon monoxide, and black carbon releases in Africa are almost entirely of pyrogenic origin, and are thus included in the biomass burning term (Table 1) [27, 28, 41]. Methane consumption in upland soils is small, and available estimates of methane release from African wetlands suggest that they are globally insignificant [43]. However, given that there is no reliable map of wetland extent in Africa, and virtually no direct emission estimates, the true size of this flux is unknown. Recent work suggests the possibility of a large methane source of unknown magnitude from living plants [44, 45]. Emissions of volatile organic compounds (VOCs) such as isoprene and monoterpenes have been studied in some detail in southern and central Africa and are estimated to return as much as 0.08 Pg C y-1 to the atmosphere [46]. At the scale of the continent, industrial emissions of carbon dioxide, carbon monoxide and hydrocarbons from Africa are small, but can be locally very significant in the industrial areas of South Africa, the oilfields of the Gulf of Guinea, Angola, and Libya, and around major cities elsewhere in Africa.

The export of dissolved organic and inorganic carbon (DOC and DIC) in river water discharged to oceans is, by and large, offset by DOC and DIC delivered in precipitation (Table 1). Africa is also a minor net global source of biomass carbon through international exchange, mainly from export of wood products [47].

What the Atmosphere Sees

Atmospheric mixing ratios and isotopic compositions measured around the globe [48] can be used to estimate terrestrial and oceanic carbon sources and sinks by inversion with atmospheric transport models [18, 49–51]. Inverse solutions for Africa are poorly constrained due to the lack of tropical, especially African, observations (Figure 4) [17, 18]. This contributes to larger uncertainty ranges around net CO2 flux estimates for Africa than for global or tropical land areas, in general. Taken together, inversion results demonstrate that Africa's net role in global carbon cycling is highly uncertain. Furthermore, lack of data causes the inverse solution for southern Africa to trade off with solutions for South America and the southern oceans, such that results can vary widely between regions with no net change in overall source/sink strength [e.g. [17, 19]]. Solving this problem will require the addition of precise, long-term observations of carbon dioxide in the tropics, located such that they help resolve the longitudinal differences among the southern hemisphere regions [52–54]. Tropical atmospheric dynamics present an additional challenge [55], and a source of uncertainty that is not represented in Figure 4, because deep convection is both poorly represented in transport models and poorly sampled, introducing non-negligible biases in atmospheric inversions.

Figure 4
figure 4

Terrestrial carbon source and sink estimates for Africa, tropical and global lands. (a) Net carbon dioxide flux totals, and (b) net carbon dioxide flux per unit area. Positive values indicate a surface source. Boxes show the range of +/- 1 standard deviation from the IPCC report [6] for global and tropical land during the 1980s (dark) and 1990s (light), whereas symbols report results from inverse analyses cited in Appendix I. Triangles and error bars indicate mean flux estimates from individual inversion studies and associated posterior uncertainties. Squares indicate the average, and pluses indicate the standard deviation, of mean flux estimates from a group of inverse solutions. Circles indicate the average uncertainty estimates among the group of inverse solutions. Atmospheric inversion results for Africa are taken from Bousquet [18] (B99), Ciais [107] (C00), Rödenbeck [51] (R03), Gurney [17] (G02), and Gurney [19] (G04), with years spanned in each analysis shown below literature source abbreviations of (a).

Recognizing large uncertainties in the inverse solutions, inverse studies to date suggest that Africa as a whole is approximately carbon neutral on an annual to long-term basis. This is so despite significant carbon emissions related to land use change and burning, implying that net plant growth and corresponding sequestration of carbon in vegetation and soils is sufficiently large across the continent to offset the loss terms. If inverse solutions correctly estimate a carbon neutral Africa and assuming a neutral biosphere with a background balance between net primary production and heterotrophic respiration plus natural fires, the remaining biotic uptake or sequestration can be estimated as roughly offsetting Africa's land use (0.4 Pg C y-1) plus fossil fuel (0.2 Pg C yr-1) sources, still noting the large uncertainties.

Despite a near-zero balance, recent time-dependent inverse solutions attribute much of the interannual variability (IAV) in global carbon sources/sinks to the African continent [20, 42, 51, 56]. Estimates of regional IAV are less sensitive to transport and station-selection than seasonal and long-term mean fluxes [20]. Global solutions for the IAV of carbon sources/sinks [20] robustly indicate the strong influence of global lands, particularly those in the tropics, with approximately equal contributions by lands of tropical Asia, Africa, and southern and tropical America (each about 0.5 Pg C y-1) (Figure 5). However, temporal source/sink dynamics are still poorly constrained among tropical regions, especially those of Africa and America [20].

Figure 5
figure 5

Root mean square of annual net carbon flux obtained from time-dependent inverse solutions [20] for the period 1990 – 2001 and for regions based on TransCom [20, 108]. NH (Northern Hemisphere land) includes temperate and boreal Asia, temperate and boreal North America, and Europe, SH (Southern Hemisphere land) includes temperate South America, Australia and New Zealand, Tropical includes tropical America, Africa and tropical Asia, and Amer. abbreviates America.

Taken together, large temporal variability of carbon sources and sinks may be Africa's most significant contribution to the global carbon cycle. This is consistent with results from ecosystem models [22–24], which indicate that high interannual variability in rainfall throughout the Sudano-Sahelian and southern African regions [57, 58], partly associated with the North Atlantic Oscillation, El Niño Southern Oscillation, and South Pacific circulation [59, 60], introduce pronounced multi-year fluctuations in surface-atmosphere C exchanges, which, in turn, appear in atmospheric CO2 concentrations [51]. Inter-annual variability in NPP then translate to variability in fire emissions with a lag of several months to a year. Such departures from long-term average biosphere exchange [51] and fire emissions [42, 51] may both be as large as the net exchanges themselves.

The Future of Carbon Cycle Research in Africa

Given the need to better understand the spatial and temporal dimensions of the global carbon cycle for prediction and management of future atmospheric CO2 concentrations, a number of research priorities for Africa emerge from this review. Of primary importance is the need for continent-wide observations that support both bottom-up and top-down methods of estimating carbon sources and sinks. Continued and new investment in collection and synthesis of carbon cycle information (measurements of carbon stocks and fluxes within and between the major pools) is needed to advance process-level characterization of seasonal and interannual variations in source/sink strengths. Such data will help to improve the way biophysical and biogeochemical models represent African ecosystems so that they capture the full suite of uniquely African features such as the continent's seasonal fire cycles, pastoralism, fuelwood harvest, cereal/grain production, dryland degradation, and the productivity and isotopic signatures of its extensive C4 vegetation. In particular, carbon flux observations wherever existing need to be used in model development and testing to appropriately represent the sensitivity of production and respiration processes to climate fluctuations. New collaborative research programs and networks are emerging in Africa to address some of the gaps through expanded site-based and regional field measurements and model-based analyses (including, amongst many national and regional activities, the growing network of eddy covariance sites (the "Afriflux" network), the African Monsoon Multidisciplinary Analysis (AMMA), the South African Ecological Observation Network (SAEON), and the Environmental Long-Term Observatories of southern Africa (ELTOSA)).

Support for inventory and monitoring of soil and vegetation carbon stocks by forest and agricultural research stations, long-established in most African countries [61], is critical. The associated national resource inventories [62] provide information invaluable for assessing regionally-specific ecosystem responses to natural and human disturbances and for anchoring regional-scale estimates of land use related carbon sources and sinks. Synthesis of country-level data is of great importance to provide local and regional scale data to underpin regional- and global-scale carbon cycle assessments. These will complement developments in satellite remote sensing of vegetation biomass using, for example, passive and active optical and radar approaches [63, 64].

A well-located atmospheric sampling network in Africa is also needed to better constrain inversion estimates of regional carbon sources and sinks and their temporal variability both in Africa and globally. However, improved constraint relies not only on new observations but also improvement of modeled transport and inverse estimation techniques. New transport schemes are needed to represent deep tropical convection, while new data assimilation and computational techniques promise to better resolve the African signal in global atmospheric carbon dynamics by incorporating diurnal variation in surface fluxes, multiple atmospheric tracers, and prior estimates of fire emissions. With regard to additional carbon cycle tracers, Africa is unique in having vast coverage of C4 vegetation [65], associated with a prevalence of semi-arid and hot environments. Seasonal production, respiration, and burning of C4 vegetation alter the carbon stable isotope (13C:12C) composition of the atmosphere because C4 plants discriminate against the heavier isotope less than C3 plants. This imprint provides a tracer for diagnosing Africa's role in global carbon stocks and fluxes [40], presenting a potential opportunity for separation of moist tropical forest exchange from that of the savanna regions. Furthermore, since oceanic and C4 plant discrimination are similar, information on the C4 terrestrial exchange is critical for separation of terrestrial from oceanic fluxes.

An orbiting space-based total column carbon observatory covering the entire globe is anticipated within the next decade [66], but it will still require near-surface and vertical profile measurements of CO2 for calibrating, validating, interpolating and interpreting satellite-derived observations. Satellite-based assessments of local to regional vegetation change from land use practices [e.g. [67]] should be further explored for continental-scale assessment. These and other data could be used to develop land use/land cover transition models that represent Africa's unique human-vegetation-climate settings. Such comprehensive investigations into regionally-specific ecosystem responses to land use in Africa offer needed detail for representing the complex dynamics associated with human-induced disturbances and land use management.

Africa and the Climate Change Context

Recent International Panel on Climate Change (IPCC) assessments show that industrialized nations are imposing a heavy burden of climate change on the global environment through emissions of carbon dioxide (CO2) and other greenhouse gases, largely from the burning of fossil fuels [6]. Non-industrialized countries currently contribute little to these emissions, but are vulnerable to climate change and will therefore be forced to take potentially costly measures to adapt.

Nearly all African countries are signatories to the UN Framework Convention on Climate Change (UNFCCC) and, being non-Annex 1 countries, there is no cap on their greenhouse gas emissions in the first Kyoto Protocol commitment period. Still, parties in Africa can participate in the Clean Development Mechanism (CDM) of the Kyoto Protocol, under which developed countries that have accepted emission caps are authorized to implement projects that reduce emissions or sequester carbon in developing countries. The resulting certified emissions reductions can then be used to meet a fraction of Annex 1 emission targets. This mechanism provides opportunities for less developed countries to leap-frog to clean industries using foreign investment and technology.

The predominantly agricultural nations of Africa are poorly-positioned to benefit financially and technologically from emission mitigation trading schemes, insofar as these mechanisms focus mainly on industrial emissions reductions, which are more easily verified. However, the scope for carbon sequestration through management of land in developing countries is large, and CDM provisions for land use based carbon emission reductions might provide rapid, medium-term sequestration at relatively low cost. Uncertainties surrounding the quantification and verification of carbon sequestration through changes in land management have thus far prevented large-scale investment in this strategy. This situation could change with improved understanding of carbon cycle dynamics in terrestrial ecosystems and suitable verification schemes, enabling many African nations to more easily participate in global efforts to slow the rate of increase of atmospheric CO2, as well as benefit from the financial and technological transfers.

Carbon sequestration through reforestation of lands deforested prior to 1990 appears to be one of the most readily available opportunities for a number of African countries. Fire management presents another prospective opportunity for mitigation, but reducing fire occurrence has proven difficult in the past [e.g. [68]], and such programs would need to be wary of unintentional loss of biodiversity from fire-adapted biota. Climate change mitigation through land management could also impart unintended environmental and social costs that affect the most vulnerable sectors of society, for example from converting lands in subsistence farming to large scale carbon plantations, or by restriction of fuel wood harvest for domestic uses. Such programs therefore require careful evaluation of the potential costs and benefits, particularly for already marginalized populations.

A Global Outlook

With as much as 40% of the world's fire emissions, about 20% of global net primary production and heterotrophic respiration, at least 20% of global land use emissions, and a major source of interannual variability in global net carbon exchange, African carbon dynamics are of global significance. The continent's vast carbon stocks seem to be highly vulnerable to climate change, evidenced by strong sensitivity of net ecosystem productivity and fire emissions to climate fluctuations. Being highly variable and insufficiently studied, there is a need for continued and enhanced observations of Africa's carbon stocks, fluxes, and atmospheric concentrations to enable more precise assessments of Africa's carbon cycle, and its sensitivity to natural and anthropogenic pressures and future climate.

In years ahead, Africa's land use pressures will undoubtedly increase and climate changes are anticipated to intensify drought cycles and make much of Africa warmer and dryer [69]. Furthermore, increasing exploitation of forest resource in the moist tropics is anticipated with economic development and investment in logging infrastructure. Such changes will likely release CO2 to the atmosphere as well as increase the magnitude of interannual variation in Africa's C fluxes by increasing Africa's biomass burning emissions and reducing the continent's net ecosystem productivity. If realized, these trends would have enormously important implications for global carbon dynamics and biospheric feedbacks to the climate system.

Appendix 1. Methods

Table 1 contains statistics of a sample of independent mean estimates for each term, presenting arithmetic means of reported values, their maxima and minima, and standard deviations. When a standard deviation around a mean estimate was reported in one of the many sources, we attempted to incorporate some of this uncertainty in the tabular values of Table 1 by including the mean, mean plus standard deviation, and mean minus standard deviation all as independent estimates contributing to the sample.

Annual precipitation C flux to Africa was estimated from the sum of estimates for dissolved organic and inorganic (DOC and DIC) carbon fluxes from precipitation following the approach in Kempe [70]. For DOC, the flux was calculated as the product of annual precipitation water flux with the maximum or minimum observed continental rainwater DOC reported in Willey et al. [71], where precipitation delivered to Africa was estimated from an FAO rainfall product [72]. Similarly, the DIC flux was calculated as the product of annual African precipitation with a) continental rainwater DIC at a pH of 7.4 and 10°C as in Willey et al. [71], and b) its product with the mean CO2 content of precipitation reported in Miotke [73].

Africa's annual riverine C discharge to oceans was calculated from the sum of riverine DOC and DIC flux estimates also as in Kempe [70]. For DIC the flux was calculated as the product of Africa's riverine discharge [74, 75] with DIC content of Africa's river water [74]. For DOC, we used the global ratio of DOC to DIC in river water [74] to estimate DOC content of Africa's river water, which was then multiplied by river water discharge.

When not directly reported, carbon emissions from human-managed fires were estimated by converting biomass burned into carbon emissions based on a common [e.g. [27, 28, 76]] assumption of biomass to carbon emissions ratio of ~0.45.

References

  1. The Least Developed Countries Report 2002: Escaping the Poverty Trap United Nations Conference on Trade and Development; 2002.

  2. UN Millenium Project: Investing in Development: A Practical Plan to Achieve the Millennium Development Goals: Overview. Earthscan, London and Sterling, VA; 2005.

    Google Scholar 

  3. House JI, Prentice IC, Ramankutty N, Houghton RA, Heimann M: Reconciling apparent inconsistencies in estimates of terrestrial CO2 sources and sinks. Tellus Ser B-Chem Phys Meteorol 2003, 55: 345–363. 10.1034/j.1600-0889.2003.00037.x

    Google Scholar 

  4. Schimel DS, House JI, Hibbard KA, Bousquet P, Ciais P, Peylin P, Braswell BH, Apps MJ, Baker D, Bondeau A, Canadell J, Churkina G, Cramer W, Denning AS, Field CB, Friedlingstein P, Goodale C, Heimann M, Houghton RA, Melillo JM, Moore B, Murdiyarso D, Noble I, Pacala SW, Prentice IC, Raupach MR, Rayner PJ, Scholes RJ, Steffen WL, Wirth C: Recent patterns and mechanisms of carbon exchange by terrestrial ecosystems. Nature 2001, 414: 169–172. 10.1038/35102500

    CAS  Google Scholar 

  5. Field CB and M.R. Raupach (eds): The global carbon cycle: Integrating humans, climate, and the natural world. Washington, D.C., Scientific Committee on Problems of the Envrionment (SCOPE) 62; 2004:526.

    Google Scholar 

  6. IPCC: Climate Change 2001: Synthesis Report, Third Assessment Report of the Intergovernmental Panel on Climate Change. New York, Cambridge Univ. Press; 2001.

    Google Scholar 

  7. Fung I: Climate change - Variable carbon sinks. Science 2000, 290: 1313–1313. 10.1126/science.290.5495.1313

    CAS  Google Scholar 

  8. Raupach MR, Rayner PJ, Barrett DJ, DeFries RS, Heimann M, Ojima DS, Quegan S, Schmullius CC: Model-data synthesis in terrestrial carbon observation: methods, data requirements and data uncertainty specifications. Glob Change Biol 2005, 11: 378–397. 10.1111/j.1365-2486.2005.00917.x

    Google Scholar 

  9. Gruber N, Keeling CD, Bates NR: Interannual variability in the North Atlantic Ocean carbon sink. Science 2002, 298: 2374–2378. 10.1126/science.1077077

    CAS  Google Scholar 

  10. Sabine CL, Feely RA, Gruber N, Key RM, Lee K, Bullister JL, Wanninkhof R, Wong CS, Wallace DWR, Tilbrook B, Millero FJ, Peng TH, Kozyr A, Ono T, Rios AF: The oceanic sink for anthropogenic CO2. Science 2004, 305: 367–371. 10.1126/science.1097403

    CAS  Google Scholar 

  11. Ciais P, Tans PP, Trolier M, White JWC, Francey RJ: A Large Northern-Hemisphere Terrestrial Co2 Sink Indicated by the C-13/C-12 Ratio of Atmospheric Co2. Science 1995, 269: 1098–1102. 10.1126/science.269.5227.1098

    CAS  Google Scholar 

  12. Fan SM, Blaine TL, Sarmiento JL: Terrestrial carbon sink in the Northern Hemisphere estimated from the atmospheric CO2 difference between Manna Loa and the South Pole since 1959. Tellus Ser B-Chem Phys Meteorol 1999, 51: 863–870. 10.1034/j.1600-0889.1999.t01-4-00001.x

    Google Scholar 

  13. Janssens IA, Freibauer A, Ciais P, Smith P, Nabuurs GJ, Folberth G, Schlamadinger B, Hutjes RWA, Ceulemans R, Schulze ED, Valentini R, Dolman AJ: Europe's terrestrial biosphere absorbs 7 to 12% of European anthropogenic CO2 emissions. Science 2003, 300: 1538–1542. 10.1126/science.1083592

    CAS  Google Scholar 

  14. Maksyutov S, Machida T, Mukai H, Patra PK, Nakazawa T, Inoue G: Effect of recent observations on Asian CO2 flux estimates by transport model inversions. Tellus Ser B-Chem Phys Meteorol 2003, 55: 522–529. 10.1034/j.1600-0889.2003.00052.x

    Google Scholar 

  15. UNFPA: State of World Population 2004. The Cairo Consensus at 10: Population, Reproductive Health and the Global Effort to End Poverty. New York; 2004.

    Google Scholar 

  16. Marland G, Boden TA, Andres RJ: Global, regional, and national annual CO2 emissions from fossil-fuel burning, cement production, and gas flaring: 1751–2000.Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, U.S. Department of Energy, Oak Ridge, Tenn., USA; 2003. [http://cdiac.esd.ornl.gov/ndps/ndp030.html] data made available at the website

    Google Scholar 

  17. Gurney KR, Law RM, Denning AS, Rayner PJ, Baker D, Bousquet P, Bruhwiler L, Chen YH, Ciais P, Fan S, Fung IY, Gloor M, Heimann M, Higuchi K, John J, Maki T, Maksyutov S, Masarie K, Peylin P, Prather M, Pak BC, Randerson J, Sarmiento J, Taguchi S, Takahashi T, Yuen CW: Towards robust regional estimates of CO2 sources and sinks using atmospheric transport models. Nature 2002, 415: 626–630. 10.1038/415626a

    Google Scholar 

  18. Bousquet P, Ciais P, Peylin P, Ramonet M, Monfray P: Inverse modeling of annual atmospheric CO2 sources and sinks 1. Method and control inversion. J Geophys Res-Atmos 1999, 104: 26161–26178. 10.1029/1999JD900342

    CAS  Google Scholar 

  19. Gurney KR, Law RM, Denning AS, Rayner PJ, Pak BC, Baker D, Bousquet P, Bruhwiler L, Chen YH, Ciais P, Fung IY, Heimann M, John J, Maki T, Maksyutov S, Peylin P, Prather M, Taguchi S: Transcom 3 inversion intercomparison: Model mean results for the estimation of seasonal carbon sources and sinks. Glob Biogeochem Cycle 2004., 18:

    Google Scholar 

  20. Baker DF, Law RM, Gurney KR, Rayner P, Peylin P, Denning AS, Bousquet P, Bruhwiler L, Chen YH, Ciais P, Fung IY, Heimann M, John J, Maki T, Maksyutov S, Masarie K, Prather M, Pak B, Taguchi S, Zhu Z: TransCom 3 inversion intercomparison: Impact of transport model errors on the interannual variability of regional CO2 fluxes, 1988–2003. Global Biogeochemical Cycles 2006, 20: GB1002, doi:10.1029/2004GB002439. 10.1029/2004GB002439

    Google Scholar 

  21. *: . Methods are available in Appendix 1..

  22. Cao MK, Zhang QF, Shugart HH: Dynamic responses of African ecosystem carbon cycling to climate change. Clim Res 2001, 17: 183–193.

    Google Scholar 

  23. Potter CS, Klooster S, Brooks V: Interannual variability in terrestrial net primary production: Exploration of trends and controls on regional to global scales. Ecosystems 1999, 2: 36–48. 10.1007/s100219900056

    Google Scholar 

  24. McGuire AD, Sitch S, Clein JS, Dargaville R, Esser G, Foley J, Heimann M, Joos F, Kaplan J, Kicklighter DW, Meier RA, Melillo JM, Moore B, Prentice IC, Ramankutty N, Reichenau T, Schloss A, Tian H, Williams LJ, Wittenberg U: Carbon balance of the terrestrial biosphere in the twentieth century: Analyses of CO2, climate and land use effects with four process-based ecosystem models. Glob Biogeochem Cycle 2001, 15: 183–206. 10.1029/2000GB001298

    CAS  Google Scholar 

  25. Potter CS: Terrestrial biomass and the effects of deforestation on the global carbon cycle - Results from a model of primary production using satellite observations. Bioscience 1999, 49: 769–778. 10.2307/1313568

    Google Scholar 

  26. Potter C, Klooster S, Myneni R, Genovese V, Tan PN, Kumar V: Continental-scale comparisons of terrestrial carbon sinks estimated from satellite data and ecosystem modeling 1982–1998. Glob Planet Change 2003, 39: 201–213. 10.1016/j.gloplacha.2003.07.001

    Google Scholar 

  27. Crutzen PJ, Andreae MO: Biomass Burning in the Tropics - Impact on Atmospheric Chemistry and Biogeochemical Cycles. Science 1990, 250: 1669–1678. 10.1126/science.250.4988.1669

    CAS  Google Scholar 

  28. Andreae MO, Merlet P: Emission of trace gases and aerosols from biomass burning. Glob Biogeochem Cycle 2001, 15: 955–966. 10.1029/2000GB001382

    CAS  Google Scholar 

  29. Houghton RA: Aboveground forest biomass and the global carbon balance. Glob Change Biol 2005, 11: 945–958. 10.1111/j.1365-2486.2005.00955.x

    Google Scholar 

  30. Houghton RA: Why are estimates of the terrestrial carbon balance so different? Glob Change Biol 2003, 9: 500–509. 10.1046/j.1365-2486.2003.00620.x

    Google Scholar 

  31. Houghton RA, Hackler JL: Emissions of carbon from land use change in sub-Saharan Africa. Journal of Geophysical Research 2006, 111: G02003, doi:10.1029/2005JG000076. 10.1029/2005JG000076

    Google Scholar 

  32. Houghton RA: Revised estimates of the annual net flux of carbon to the atmosphere from changes in land use and land management 1850–2000. Tellus Ser B-Chem Phys Meteorol 2003, 55: 378–390. 10.1034/j.1600-0889.2003.01450.x

    Google Scholar 

  33. DeFries RS, Houghton RA, Hansen MC, Field CB, Skole D, Townshend J: Carbon emissions from tropical deforestation and regrowth based on satellite observations for the 1980s and 1990s. Proc Natl Acad Sci U S A 2002, 99: 14256–14261. 10.1073/pnas.182560099

    CAS  Google Scholar 

  34. IPCC: Climate Change 2001: Working Group 2: Impacts, Adaptation, and Vulnerability, Third Assessment Report for the Intergovernmental Panel on Climate Change, Ch 10: Africa. New York, Cambridge Univ. Press; 2001.

    Google Scholar 

  35. Schlesinger WH: Biological feedbacks in global desertification. Science 1990, 247: 1043–1048. 10.1126/science.247.4946.1043

    CAS  Google Scholar 

  36. Wang GL, Eltahir EAB: Ecosystem dynamics and the Sahel drought. Geophys Res Lett 2000, 27: 795–798. 10.1029/1999GL011089

    Google Scholar 

  37. Zeng N, Neelin JD: The role of vegetation-climate interaction and interannual variability in shaping the African savanna. J Clim 2000, 13: 2665–2670. 10.1175/1520-0442(2000)013<2665:TROVCI>2.0.CO;2

    Google Scholar 

  38. Nicholson S: Land surface processes and Sahel climate. Rev Geophys 2000, 38: 117–139. 10.1029/1999RG900014

    Google Scholar 

  39. Arellano AF, Kasibhatla PS, Giglio L, van der Werf GR, Randerson JT: Top-down estimates of global CO sources using MOPITT measurements (vol 31, art no. L01104, 2004). Geophysical Research Letters 2004., 31:

    Google Scholar 

  40. Randerson JT, van der Werf GR, Collatz GJ, Giglio L, Still CJ, Kasibhatla P, Miller JB, White JWC, DeFries RS, Kasischke ES: Fire emissions from C-3 and C-4 vegetation and their influence on interannual variability of atmospheric CO2 and delta(CO2)-C-13. Glob Biogeochem Cycle 2005., 19:

    Google Scholar 

  41. Scholes M, Andreae MO: Biogenic and pyrogenic emissions from Africa and their impact on the global atmosphere. Ambio 2000, 29: 23–29. 10.1639/0044-7447(2000)029[0023:BAPEFA]2.0.CO;2

    Google Scholar 

  42. Patra PK, Ishizawa M, Maksyutov S, Nakazawa T, Inoue G: Role of biomass burning and climate anomalies for land-atmosphere carbon fluxes based on inverse modeling of atmospheric CO2. Glob Biogeochem Cycle 2005., 19:

    Google Scholar 

  43. Otter LB, Scholes MC: Methane sources and sinks in a periodically flooded South African savanna. Glob Biogeochem Cycle 2000, 14: 97–111. 10.1029/1999GB900068

    CAS  Google Scholar 

  44. Keppler F, Hamilton JTG, Brass M, Rockmann T: Methane emissions from terrestrial plants under aerobic conditions. Nature 2006, 439: 187–191. 10.1038/nature04420

    CAS  Google Scholar 

  45. do Carmo JB, Keller M, Dias JD, de Camargo PB, Crill P: A source of methane from upland forests in the Brazilian Amazon. Geophys Res Lett 2006., 33:

    Google Scholar 

  46. Otter L, Guenther A, Wiedinmyer C, Fleming G, Harley P, Greenberg J: Spatial and temporal variations in biogenic volatile organic compound emissions for Africa south of the equator. J Geophys Res-Atmos 2003., 108:

    Google Scholar 

  47. Tschirley J and G. Servin: Carbon transport through international commerce. In The global carbon cycle: Integrating humans, climate, and the natural world. Volume 62. Edited by: Field CBRMR. Washington, D.C., Scientific Committee on Problems of the Environment (SCOPE); 2004:383–401.

    Google Scholar 

  48. GLOBALVIEW-CO2: Cooperative Atmospheric Data Integration Project - Carbon Dioxide. CD-ROM, NOAA CMDL, Boulder, Colorado . 2005. [Also available on Internet via anonymous FTP to ftp.cmdl.noaa.gov, Path: ccg/co2/GLOBALVIEW]

    Google Scholar 

  49. Enting IG, Trudinger CM, Francey RJ: A Synthesis Inversion of the Concentration and Delta-C-13 of Atmospheric Co2. Tellus Ser B-Chem Phys Meteorol 1995, 47: 35–52. 10.1034/j.1600-0889.47.issue1.5.x

    Google Scholar 

  50. Rayner PJ, Enting IG, Francey RJ, Langenfelds R: Reconstructing the recent carbon cycle from atmospheric CO2, delta C-13 and O-2/N-2 observations. Tellus Ser B-Chem Phys Meteorol 1999, 51: 213–232. 10.1034/j.1600-0889.1999.t01-1-00008.x

    Google Scholar 

  51. Rödenbeck C, Houweling S, Gloor M, Heimann M: CO2 flux history 1982–2001 inferred from atmospheric data using a global inversion of atmospheric transport. Atmos Chem Phys 2003, 3: 1919–1964.

    Google Scholar 

  52. Gloor M, Fan SM, Pacala S, Sarmiento J: Optimal sampling of the atmosphere for purpose of inverse modeling: A model study. Glob Biogeochem Cycle 2000, 14: 407–428. 10.1029/1999GB900052

    CAS  Google Scholar 

  53. Patra PK, Maksyutov S: Incremental approach to the optimal network design for CO2 surface source inversion. Geophys Res Lett 2002., 29:

    Google Scholar 

  54. Rayner PJ, Enting IG, Trudinger CM: Optimizing the CO2 observing network for constraining sources and sinks. Tellus Ser B-Chem Phys Meteorol 1996, 48: 433–444. 10.1034/j.1600-0889.1996.t01-3-00003.x

    Google Scholar 

  55. Bousquet P, Peylin P, Ciais P, Ramonet M, Monfray P: Inverse modeling of annual atmospheric CO2 sources and sinks 2. Sensitivity study. J Geophys Res-Atmos 1999, 104: 26179–26193. 10.1029/1999JD900341

    CAS  Google Scholar 

  56. Rödenbeck C, Houweling S, Gloor M, Heimann M: Time-dependent atmospheric CO2 inversions based on interannually varying tracer transport. Tellus Ser B-Chem Phys Meteorol 2003, 55: 488–497. 10.1034/j.1600-0889.2003.00033.x

    Google Scholar 

  57. Nicholson SE, Kim J, Ba MB, Lare AR: The mean surface water balance over Africa and its interannual variability. J Clim 1997, 10: 2981–3002. 10.1175/1520-0442(1997)010<2981:TMSWBO>2.0.CO;2

    Google Scholar 

  58. Nicholson SE, Grist JP: A conceptual model for understanding rainfall variability in the West African Sahel on interannual and interdecadal timescales. International Journal of Climatology 2001, 21: 1733–1757. 10.1002/joc.648

    Google Scholar 

  59. Stige LC, Stave J, Chan KS, Ciannelli L, Pettorelli N, Glantz M, Herren HR, Stenseth NC: The effect of climate variation on agro-pastoral production in Africa. Proc Natl Acad Sci U S A 2006, 103: 3049–3053. 10.1073/pnas.0600057103

    CAS  Google Scholar 

  60. McHugh MJ: Impact of South Pacific circulation variability on east African rainfall. Int J Climatol 2006, 26: 505–521. 10.1002/joc.1257

    Google Scholar 

  61. Justice CO, Wilkie D, Zhang Q, Brunner J, Donoghue C: Central African forests, carbon and climate change. Clim Res 2001, 17: 229–246.

    Google Scholar 

  62. Desanker PV, Justice CO: Africa and global climate change: critical issues and suggestions for further research and integrated assessment modeling. Clim Res 2001, 17: 93–103.

    Google Scholar 

  63. Saatchi SS Houghton, R. A., Dos Santos Alvala, R. C., Soares, J. V. and Yu, Y.: Distribution of aboveground live biomass in the Amazon basin. Global Change Biology 2007., (in press):

    Google Scholar 

  64. Woodhouse IH: Predicting backscatter-biomass and height-biomass trends using a macroecology model. Ieee Transactions on Geoscience and Remote Sensing 2006, 44: 871–877. 10.1109/TGRS.2006.872356

    Google Scholar 

  65. Still CJ, Berry JA, Collatz GJ, DeFries RS: Global distribution of C-3 and C-4 vegetation: Carbon cycle implications. Glob Biogeochem Cycle 2003., 17:

    Google Scholar 

  66. Crisp D, Atlas RM, Breon FM, Brown LR, Burrows JP, Ciais P, Connor BJ, Doney SC, Fung IY, Jacob DJ, Miller CE, O'Brien D, Pawson S, Randerson JT, Rayner P, Salawitch RJ, Sander SP, Sen B, Stephens GL, Tans PP, Toon GC, Wennberg PO, Wofsy SC, Yung YL, Kuang Z, Chudasama B, Sprague G, Weiss B, Pollock R, Kenyon D, Schroll S: The orbiting carbon observatory (OCO) mission. Advances in Space Research. Trace Constituents in the Troposphere and Lower Stratosphere 2004, 34: 700–709.

    CAS  Google Scholar 

  67. Dube OP, Pickup G: Effects of rainfall variability and communal and semi-commercial grazing on land cover in southern African rangelands. Clim Res 2001, 17: 195–208.

    Google Scholar 

  68. Van Wilgen BW, Govender N, Biggs HC, Ntsala D, Funda XN: Response of Savanna fire regimes to changing fire-management policies in a large African National Park. Conserv Biol 2004, 18: 1533–1540. 10.1111/j.1523-1739.2004.00362.x

    Google Scholar 

  69. IPCC: Climate Change 2001: Working Group 1: The Scientific Basis, Third Assessment Report of the Intergovernmental Panel on Climate Change. New York, Cambridge Univ. Press; 2001.

    Google Scholar 

  70. Kempe S: Chapter 12, Carbon in the Freshwater Cycle. In The Global Carbon Cycle, SCOPE, Vol 13. Edited by: Bolin B, Degens ET, Kempe S and Ketner P. Chichester, John Wiley & Sons; 1979.

    Google Scholar 

  71. Willey JD, Kieber RJ, Eyman MS, Avery GB: Rainwater dissolved organic carbon: Concentrations and global flux. Glob Biogeochem Cycle 2000, 14: 139–148. 10.1029/1999GB900036

    CAS  Google Scholar 

  72. Leemans R, Cramer WP: The IIASA Database for Mean Monthly Values of Temperature, Precipitation and Cloudiness of a Global Terrestrial Grid. IIASA, Laxenburg, Austria; 1991:RR-91–18, 62.

    Google Scholar 

  73. Miotke FD: Karstmorphologische Studien in der glazial überformten Höhenstufe der `Picos de Europa' Nord-Spanien. In Jb Geogr Ges Hannover, Arb Geograph Inst Techn Univ Hannover, Sonderheft. Volume 4. Hannover, Selbstverlag Geograph. Ges. Hannover; 1968:1–161.

    Google Scholar 

  74. Livingstone DA: Chemical composition of rivers and lakes. U.S. Geol. Surv. Prof. Pap. 440G; 1963:1–64.

    Google Scholar 

  75. Baumgartner A, Reichel E: The World Water Balance. München, Wien, R. Oldenbourg-Verlag; 1975:179.

    Google Scholar 

  76. Hao WM, Liu MH: Spatial and Temporal Distribution of Tropical Biomass Burning. Glob Biogeochem Cycle 1994, 8: 495–503. 10.1029/94GB02086

    CAS  Google Scholar 

  77. Schlesinger WH: Biogeochemistry: An analysis of global change. 2nd edition. San Diego, Academic Press; 1997:142.

    Google Scholar 

  78. Post WM, Emanuel WR, Zinke PJ, Stangenberger AG: Soil Carbon Pools and World Life Zones. Nature 1982, 298: 156–159. 10.1038/298156a0

    CAS  Google Scholar 

  79. Batjes NH: Total carbon and nitrogen in the soils of the world. European Journal of Soil Science 1996, 47: 151–163. 10.1111/j.1365-2389.1996.tb01386.x

    CAS  Google Scholar 

  80. Atjay GL, Ketner P, Duvigneaud P: Terrestrial primary production and phytomass. In The Global Carbon Cycle, SCOPE, Vol 13. Edited by: Bolin B, Degens ET, Kempe S and Ketner P. Chichester, John Wiley & Sons; 1979:129–181.

    Google Scholar 

  81. Carter AJ, Scholes RJ: Spatial Global Database of Soil Properties. IGBP Global Soil Data Task. CD-ROM. Toulouse, France, International Geosphere-Biosphere Programme (IGBP) Data Information Systems; 2000.

    Google Scholar 

  82. Sabine CL, Heimann M, Artaxo P, Bakker DCE, Chen CTA, Field CB, Gruber N, Le Quere C, Prinn RG, Richey J, Lankao PR, Sathaye JA, Valentini R: Current Status and Past Trends of the Global Carbon Cycle. In Scope 62, The Global Carbon Cycle: Integrating Humans, Climate, and the Natural World. Edited by: C.B. Field MRR. Washington, D.C., Island Press; 2004:17–44.

    Google Scholar 

  83. Roy J, Mooney H, Saugier B: Terrestrial Global Productivity: Past, Present, and Future. San Diego, Academic Press; 2001:573.

    Google Scholar 

  84. Olson JS, Watts JA, Allison LJ: Major world ecosystem complexes ranked by carbon in live vegetation: A Database. NDP-017. , Carbon Dioxide Information Center, Oak Ridge National Laboratory, Oak Ridge, Tennessee. (Revised 2001); 1985.

    Google Scholar 

  85. Gaston G, Brown S, Lorenzini M, Singh KD: State and change in carbon pools in the forests of tropical Africa. Global Change Biology 1998, 4: 97–114. 10.1046/j.1365-2486.1998.00114.x

    Google Scholar 

  86. Saugier B, Roy J, Mooney HA: Estimations of global terrestrial productivity: Converging toward a single number? In Terrestrial global productivity. Edited by: J. Roy BSHAM. San Diego, Academic Press; 2001:543–557.

    Google Scholar 

  87. Schimel DS: Terrestrial ecosystems and the carbon cycle. Global Change Biol 1995, 1: 1–16. 10.1111/j.1365-2486.1995.tb00008.x

    Google Scholar 

  88. Houghton RA, Skole DI: Carbon. In The Earth as Transformed by Human Action. Edited by: B.L. Turner WCCRWKJFRJTMWBM. Cambridge, Cambridge University Press; 1990.

    Google Scholar 

  89. Cramer W, Kicklighter DW, Bondeau A, Moore B, Churkina C, Nemry B, Ruimy A, Schloss AL: Comparing global models of terrestrial net primary productivity (NPP): overview and key results. Global Change Biol 1999, 5: 1–15. 10.1046/j.1365-2486.1999.00009.x

    Google Scholar 

  90. Raich JW, Schlesinger WH: The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate. Tellus 1992, 44B: 81–90.

    CAS  Google Scholar 

  91. Raich JW, Potter CS, Bhagawati D: Interannual variability in global soil respiration, 1980–94. Glob Change Biol 2002, 8: 800–812. 10.1046/j.1365-2486.2002.00511.x

    Google Scholar 

  92. Prentice IC, Farquhar GD, Fasham MJR, Goulden ML, Heimann M, Jaramillo VJ, Kheshgi HS, Le Quere C, Scholes RJ, Wallace DWR: IPCC TAR, Chapter 3: The carbon cycle and atmospheric carbon dioxide. 2001.

    Google Scholar 

  93. Houghton RA: A new estimate of global sources and sinks of C from land-use change. EOS 2000, 81: s281.

    Google Scholar 

  94. Houghton RA: Emissions of carbon from land-use change. In The Carbon Cycle. Edited by: Wigley TML and Schimel DS. New York, Cambridge Univ. Press; 2000:63–76.

    Google Scholar 

  95. Achard F, Eva HD, Mayaux P, Stibig HJ, Belward A: Improved estimates of net carbon emissions from land cover change in the tropics for the 1990s. Global Biogeochemical Cycles 2004, 18: doi: 10.1029/2003GB02142. 10.1029/2003GB002142

    Google Scholar 

  96. FAO: Global Forest Resources Assessment 2000, Main Report. FAO Forestry Paper 140. Rome, FAO; 2001.

    Google Scholar 

  97. Seiler W, Crutzen PJ: Estimates of Gross and Net Fluxes of Carbon between the Biosphere and the Atmosphere from Biomass Burning. Clim Change 1980, 2: 207–247. 10.1007/BF00137988

    CAS  Google Scholar 

  98. Hao WM, Liu MH, Crutzen PJ: Estimates of annual and regional releases of CO2 and other trace gases to the atmosphere from fires in the tropics, based on the FAO statistics for the period 1975–1980. In Fire in the Tropical Biota: Ecosystem Processes and Global Challenges. Edited by: Goldammer JG. New York, Springer-Verlag; 1990:440–462.

    Google Scholar 

  99. Andreae MO: Biomass burning: Its theory, use, and distribution and its impact on environmental quality and global climate. In Global Biomass Burning, Atmospheric, Climatic, and Biospheric Implications. Edited by: Levine JS. Cambridge, Mass., MIT Press; 1991:3–21.

    Google Scholar 

  100. van der Werf GR, Randerson JT, Collatz GJ, Giglio L: Carbon emissions from fires in tropical and subtropical ecosystems. Global Change Biology 2003, 9: 547–562. 10.1046/j.1365-2486.2003.00604.x

    Google Scholar 

  101. Barbosa PM, Stroppiana D, Gregoire JM: An assessment of vegetation fire in Africa (1981–1991): Burned areas, burned biomass, and atmospheric emissions. Global Biogeochemical Cycles 1999, 13: 933–950. 10.1029/1999GB900042

    CAS  Google Scholar 

  102. Andreae MO, Anderson BE, Blake DR, Bradshaw JD, Collins JE, Gregory GL, Sachse GW, Shipham MC: Influence of plumes from biomass burning on atmospheric chemistry over the equatorial Atlantic during CITE-3. Journal of Geophysical Research 1994, 99: 12793–12808. 10.1029/94JD00263

    CAS  Google Scholar 

  103. Prinn RG: Non-CO2 Greenhouse Gases. In The global carbon cycle: Integrating humans, climate, and the natural world. Volume 62. Edited by: Field CB and Raupach MR. Washington, D.C., Scientific Committee on Problems of the Environment (SCOPE); 2004:205–216.

    Google Scholar 

  104. Anderson IC, Poth MA: Controls on fluxes of trace gases from Brazilian cerrado soils. J Environ Qual 1998, 27: 1117–1124.

    CAS  Google Scholar 

  105. RIVM, TNO: National Institute for Public Health (RIVM) and Netherlands Organization for Applied Scientific Research (TNO), The Emission Database for Global Atmospheric Research (EDGAR) 3.2. Precursors: NMVOC (Non-Methane Volatile Organic Compounds): Aggregated Emissions 1990/1995.The Netherlands, RIVM; 2001. [http://arch.rivm.nl/env/int/coredata/edgar/]

    Google Scholar 

  106. DeFries R Hansen, M., Townshend, J. R. G. and Sohlberg, R.: Global land cover classifications at 8 km spatial resolution: The use of training data derived from Landsat imagery in decision tree classifiers. International Journal of Remote Sensing 1998, 19: 3141–3168. 10.1080/014311698214235

    Google Scholar 

  107. Ciais P, Peylin P, Bousquet P: Regional biospheric carbon fluxes as inferred from atmospheric CO2 measurements. Ecol Appl 2000, 10: 1574–1589. 10.2307/2641225

    Google Scholar 

  108. Gurney KR, Law RM, Denning AS, Rayner PJ, Baker D, Bousquet P, Bruhwiler L, Chen YH, Ciais P, Fan SM, Fung IY, Gloor M, Heimann M, Higuchi K, John J, Kowalczyk E, Maki T, Maksyutov S, Peylin P, Prather M, Pak BC, Sarmiento J, Taguchi S, Takahashi T, Yuen CW: TransCom 3 CO2 inversion intercomparison: 1. Annual mean control results and sensitivity to transport and prior flux information. Tellus Ser B-Chem Phys Meteorol 2003, 55: 555–579. 10.1034/j.1600-0889.2003.00049.x

    Google Scholar 

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Acknowledgements

Funding for this study was provided by the United States National Aeronautics and Space Administration (NASA) Terrestrial Ecology Program (Dr. Diane Wickland), and the National Oceanic and Atmospheric Administration (NOAA) Global Carbon Cycle Program (Dr. Kathy Tedesco). We would like to thank A.J. Dolman of Vrije University, Amsterdam, and Robert B. Jackson of Duke University for providing initial reviews of the draft manuscript.

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All authors participated in detailed discussions that led to this review paper. CAW compiled and analyzed the data and drafted the manuscript. NPH originally conceived the paper and contributed to data analyses, interpretation, drafting and editing the manuscript. JCN, RJS, JAB and ASD provided intellectual input on available data and previous analyses, and on the synthesis, presentation and interpretation needed for this review. DFB made data available from a global time-dependent inverse analysis of CO2 concentrations contributing to Figure 5. All of the authors read, edited, and approved the final manuscript.

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Williams, C.A., Hanan, N.P., Neff, J.C. et al. Africa and the global carbon cycle. Carbon Balance Manage 2, 3 (2007). https://doi.org/10.1186/1750-0680-2-3

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