Teodoru, C.R., Nyoni, F.C., Borges, A.V., Darchambeau, F., Nyambe, I., Bouillon, S., 2015. Dynamics of greenhouse gases (CO2, CH4, N2O) along the Zambezi River and major tributaries, and their importance in the riverine carbon budget. Biogeosciences 12, 2431-2453.
Abstract
Spanning over 3000 km in length and with a catchment of
approximately 1.4 million km2, the Zambezi River is the fourth largest
river in Africa and the largest flowing into the Indian Ocean from the
African continent. We present data on greenhouse gas (GHG: carbon dioxide
(CO2), methane (CH4), and nitrous oxide (N2O)) concentrations
and fluxes, as well as data that allow for characterization of sources and dynamics
of carbon pools collected along the Zambezi River, reservoirs and several of
its tributaries during 2012 and 2013 and over two climatic seasons (dry and
wet) to constrain the interannual variability, seasonality and spatial
heterogeneity along the aquatic continuum. All GHG concentrations showed
high spatial variability (coefficient of variation: 1.01 for CO2, 2.65
for CH4 and 0.21 for N2O). Overall, there was no unidirectional
pattern along the river stretch (i.e., decrease or increase towards the
ocean), as the spatial heterogeneity of GHGs appeared to be determined
mainly by the connectivity with floodplains and wetlands as well as the presence
of man-made structures (reservoirs) and natural barriers (waterfalls,
rapids). Highest CO2 and CH4 concentrations in the main channel
were found downstream of extensive floodplains/wetlands. Undersaturated
CO2 conditions, in contrast, were characteristic of the surface waters
of the two large reservoirs along the Zambezi mainstem. N2O
concentrations showed the opposite pattern, being lowest downstream of the
floodplains and highest in reservoirs. Among tributaries, highest
concentrations of both CO2 and CH4 were measured in the Shire
River, whereas low values were characteristic of more turbid systems such as
the Luangwa and Mazoe rivers. The interannual variability in the Zambezi
River was relatively large for both CO2 and CH4, and
significantly higher concentrations (up to 2-fold) were measured during
wet seasons compared to the dry season. Interannual variability of N2O
was less pronounced, but higher values were generally found during the dry
season. Overall, both concentrations and fluxes of CO2 and CH4
were well below the median/average values for tropical rivers, streams and
reservoirs reported previously in the literature and used for global
extrapolations. A first-order mass balance suggests that carbon (C)
transport to the ocean represents the major component (59%) of the budget
(largely in the form of dissolved inorganic carbon, DIC), while 38% of
the total C yield is annually emitted into the atmosphere, mostly as
CO2 (98%), and 3% is removed by sedimentation in reservoirs.
Tyler et al. 1998. Measurements and interpretation of d13C of methane from termites, rice paddies, and wetlands in Kenya
Tyler SC, Zimmerman PR, Cumberbatch C, Greenberg JP, Westberg
C, Darlington JP: Measurements and interpretation of d13C of methane from
termites, rice paddies, and wetlands in Kenya. Glob Biogeochem Cy 1988,
2:341-355.
Abstract
Ratios of 13C/12C have been measured in methane from a variety of sources in tropical Kenya. Ranges of δ13C in CH4
for termites (most values range from −56 to −64‰, one is at −44‰ one is
at ∼−73‰), rice paddies (range −57 to −63‰), and wetlands (range −45 to
− 50‰ for Lake Baringo, ∼−55‰ in the Moloi River, ∼−62‰ and ∼−31‰ in
two swamp areas) are presented. The data are interpreted with the help
of additional measurements of δ13C of CO2 gas, and
organic carbon in plant material, termite bodies, and termite fungus
combs. The implications of these findings are related to the problem of
studying the atmospheric methane budget.
Macdonald et al. 1998. Methane emission by termites and oxidation by soils, across a forest disturbance gradient in the Mbalmayo Forest Reserve, Cameroon
Macdonald JA,
Eggleton P, Bignell DE, Forzi F, Fowler D: Methane emission by termites and
oxidation by soils, across a forest disturbance gradient in the Mbalmayo Forest
Reserve, Cameroon. Glob Change Biol 1998, 4:409-418.
Abstract
Methane fluxes
were measured, using static chambers, across a disturbance gradient in a
West African semi-deciduous humid forest. Soil-feeding termite biomass
was simultaneously determined, in an attempt to examine its influence on
the net soil-atmosphere exchange of CH4. CH4
emission rates from individual termite species were determined under
laboratory conditions, permitting the gross production of CH4 to be compared with net fluxes to the atmosphere. Both net CH4 oxidation(-) and emission were observed, and CH4 fluxes ranged from – 24.6 to 40.7 ng m–2 s–1. A statistically significant relationship between termite biomass and CH4 flux was observed across the forested sites such that: CH4 flux (ng m–2 s–1) = 4.95 × termite biomass (gm–2)–10.9 (P < 0.001). Rates of CH4
oxidation were on average 60% smaller at the clearfelled and Terminalia
plantation sites than at the near-primary forest site. Two of the
disturbed sites were net CH4 sources during one of the sampling periods. Disturbance of tropical forests, resulting in a decrease in the CH4 sink capacity of the soil, may therefore increase the contribution of termite-derived CH4 to the atmosphere. Measurements from the mounds of the soil-feeding termites Thoracotermes macrothorax and Cubitermes fungifaber from the old plantation site gave a CH4 emission of 636 and 53.4 ng s–1 mound–1, respectively. The forest floor surrounding the mounds was sampled in three concentric bands. Around the mound of T. macrothorax the soil was a net source of CH4 estimated to contribute a further 148 ng s–1. Soil surrounding the mound of C. fungifaber was mostly a net sink. The mounds of soil-feeding termites are point sources of CH4,
which at the landscape scale may exceed the general sink capacity of
the soil, to an extent dependent on seasonal variations in soil moisture
and level of disturbance.
Baggs et al. 2006. A short-term investigation of trace gas emissions following tillage and no-tillage of agroforestry residues in western Kenya.
Baggs EM, Chebii J, Ndufa JK (2006)
A short-term investigation of trace gas emissions following tillage and
no-tillage of agroforestry residues in western Kenya. Soil and Tillage Research
90: 69-76.
Abstract
Improved-fallow
agroforestry systems are increasingly being adopted in the humid
tropics for soil fertility management. However, there is little
information on trace gas emissions after residue application in these
systems, or on the effect of tillage practice on emissions from tropical
agricultural systems. Here, we report a short-term experiment in which
the effects of tillage practice (no-tillage versus tillage to 15 cm
depth) and residue quality on emissions of N2O, CO2 and CH4 were determined in an improved-fallow agroforestry system in western Kenya. Emissions were increased following tillage of Tephrosia candida (2.1 g N2O-N ha−1 kg N applied−1; 759 kg CO2-C ha−1 t C applied−1; 30 g CH4-C ha−1 t C applied−1) and Crotalaria paulina residues (2.8 g N2O-N ha−1 kg N applied−1; 967 kg CO2-C ha−1 t C applied−1; 146 g CH4-C ha−1 t C applied−1) and were higher than from tillage of natural-fallow residues (1.0 g N2O-N ha−1 kg N applied−1; 432 kg CO2-C ha−1 t C applied−1; 14.7 g CH4-C ha−1 t C applied−1)
or from continuous maize cropping systems. Emissions from these fallow
treatments were positively correlated with residue N content (r = 0.62–0.97; P < 0.05) and negatively correlated with residue lignin content (r = −0.56, N2O; r = −0.92, CH4; P < 0.05). No-tillage of surface applied Tephrosia residues lowered the total N2O and CO2 emitted over 99 days by 0.33 g N2O-N ha−1 kg N applied−1 and 124 kg CO2-C ha−1 t C applied−1, respectively; estimated to provide a reduction in global warming potential of 41 g CO2
equivalents. However, emissions were increased from this treatment over
the first 2 weeks. The responses to tillage practice and residue
quality reported here need to be verified in longer term experiments
before they can be used to suggest mitigation strategies appropriate for
all three greenhouse gases.
Michelsen et al. 2004. Carbon stocks, soil respiration and microbial biomass in fire-prone tropical grassland, woodland and forest ecosystems
Michelsen, A., Andersson, M., Jensen, M., Kjøller, A., Gashew, M., 2004. Carbon stocks, soil respiration and microbial biomass in fire-prone tropical grassland, woodland and forest ecosystems. Soil Biol. Biochem. 36, 1707-1717.
Abstract
A
thorough understanding of the role of microbes in C cycling in relation
to fire is important for estimation of C emissions and for development
of guidelines for sustainable management of dry ecosystems. We
investigated the seasonal changes and spatial distribution of soil
total, dissolved organic C (DOC) and microbial biomass C during 18
months, quantified the soil CO2 emission in the beginning of
the rainy season, and related these variables to the fire frequency in
important dry vegetation types grassland, woodland and dry forest in
Ethiopia. The soil C isotope ratios (δ13C) reflected
the 15-fold decrease in the grass biomass along the vegetation gradient
and the 12-fold increase in woody biomass in the opposite direction.
Changes in δ13C down the soil profiles also
suggested that in two of the grass-dominated sites woody plants were
more frequent in the past. The soil C stock ranged from being 2.5 (dry
forest) to 48 times (grassland) higher than the C stock in the
aboveground plant biomass. The influence of fire in frequently burnt
wooded grassland was evident as an unchanged or increasing total C
content down the soil profile. DOC and microbial biomass measured with
the fumigation–extraction method (Cmic) reflected the
vertical distribution of soil organic matter (SOM). However, although
SOM was stable throughout the year, seasonal fluctuations in Cmic and substrate-induced respiration (SIR) were large. In woodland and woodland–wooded grassland Cmic
and SIR increased in the dry season, and gradually decreased during the
following rainy season, confirming previous suggestions that microbes
may play an important role in nutrient retention in the dry season.
However, in dry forest and two wooded grasslands Cmic and SIR
was stable throughout the rainy season, or even increased in this
period, which could lead to enhanced competition with plants for
nutrients. Both the range and the seasonal changes in soil microbial
biomass C in dry tropical ecosystems may be wider than previously
assumed. Neither SIR nor Cmic were good predictors of in situ
soil respiration. The soil respiration was relatively high in
infrequently burnt forest and woodland, while frequently burnt
grasslands had lower rates, presumably because most C is released
through dry season burning and not through decomposition in fire-prone
systems. Shifts in the relative importance of the two pathways for C
release from organic matter may have strong implications for C and
nutrient cycling in seasonally dry tropical ecosystems.
Andersson et al. 2004. Tropical savannah woodland: effects of experimental fire on soil microorganisms and soil emissions of carbon dioxide
Andersson, M., Michelsen, A., Jensen, M., Kjøller, A., 2004. Tropical savannah woodland: effects of experimental fire on soil microorganisms and soil emissions of carbon dioxide. Soil Biol. Biochem. 36, 849-858.
Abstract
Burning
of the vegetation in the African savannahs in the dry season is
widespread and may have significant effects on soil chemical and
biological properties. A field experiment in a full factorial randomised
block design with fire, ash and extra grass biomass as main factors was
carried out in savannah woodland of the Gambella region in Ethiopia.
The microbial biomass C (Cmic) was 52%
(fumigation–extraction) and 20% (substrate-induced respiration) higher
in burned than unburned plots 12 d after burning. Both basal respiration
and potential denitrification enzyme activity (PDA) immediately
responded to burning and increased after treatment. However, in burned
plots addition of extra biomass (fuel load) led to a reduction of Cmic
and PDA due to enhanced fire temperature. Five days after burning,
there was a short-lived burst in the in situ soil respiration following
rainfall, with twice as high soil respiration in burned than unburned
plots. In contrast, 12 d after burning soil respiration was 21% lower in
the burned plots, coinciding with lower soil water content in the same
plots. The fire treatment resulted in higher concentrations of dissolved
organic C (24–85%) and nitrate (47–76%) in the soil until 90 d after
burning, while soil NH4+–N was not affected to the same extent. The increase in soil NO3−–N but not NH4+–N
in the burned plots together with the well-aerated soil conditions
indicated that nitrifying bacteria were stimulated by fire and
immediately oxidised NH4+–N to NO3−–N. In the subsequent rainy season, NO3−–N and, consequently, PDA were reduced by ash deposition. Further, Cmic
was lower in burned plots at that time. However, the fire-induced
changes in microbial biomass and activity were relatively small compared
to the substantial seasonal variation, suggesting transient effects of
the low severity experimental fire on soil microbial functioning.
Gerschlauer et al. 2014. Greenhouse gas exchange in tropical mountain ecosystems in Tanzania
Gerschlauer et al. 2014. Greenhouse gas exchange in tropical mountain ecosystems in Tanzania. EGU General Assembly 2014, held 27 April - 2 May, 2014 in Vienna, Austria
Abstract
Tropical mountain ecosystems with their mostly immense biodiversity are important regions for natural resources but also for agricultural production. Their supportive ecosystem processes are particularly vulnerable to the combined impacts of global warming and the conversion of natural to human-modified landscapes. Data of impacts of climate and land use change on soil-atmosphere interactions due to GHG (CO2, CH4, and N2O) exchange from these ecosystems are still scarce, in particular for Africa. Tropical forest soils are underestimated as sinks for atmospheric CH4 with regard to worldwide GHG budgets (Werner et al. 2007, J GEOPHYS RES Vol. 112). Even though these soils are an important source for the atmospheric N2O budget, N2O emissions from tropical forest ecosystems are still poorly characterized (Castaldi et al. 2013, Biogeosciences 10). To obtain an insight of GHG balances of selected ecosystems soil-atmosphere exchange of N2O, CH4 and CO2 was investigated along the southern slope of Mt. Kilimanjaro, Tanzania. We will present results for tropical forests in three different altitudes (lower montane, Ocotea, and Podocarpus forest), home garden (extensive agro-forestry), and coffee plantation (intensive agro-forestry). Therefore we used a combined approach consisting of a laboratory parameterization experiment (3 temperature and 2 moisture levels) and in situ static chamber measurements for GHG exchange. Field measurements were conducted during different hygric seasons throughout two years. Seasonal variation of temperature and especially of soil moisture across the different ecosystems resulted in distinct differences in GHG exchange. In addition environmental parameters like soil bulk density and substrate availability varying in space strongly influenced the GHG fluxes within sites. The results from parameterization experiments and in situ measurements show that natural forest ecosystems and extensive land use had higher uptakes of CH4. For the investigated forest ecosystems we found considerable differences in soil sink strength for CH4. N2O emissions were highest in natural forest ecosystems even though N input in the intensively managed system was considerably higher. Highest N2O efflux rates were identified in the region of highest mean annual precipitation. CO2 emissions reduced from managed to natural ecosystems. In general an increase in temperature as well as in soil moisture caused higher GHG fluxes throughout all investigated natural and managed ecosystems. With increasing altitude of the investigated forests GHG emissions reduced overall.
http://meetingorganizer.copernicus.org/EGU2014/EGU2014-10821.pdf
Abstract
Tropical mountain ecosystems with their mostly immense biodiversity are important regions for natural resources but also for agricultural production. Their supportive ecosystem processes are particularly vulnerable to the combined impacts of global warming and the conversion of natural to human-modified landscapes. Data of impacts of climate and land use change on soil-atmosphere interactions due to GHG (CO2, CH4, and N2O) exchange from these ecosystems are still scarce, in particular for Africa. Tropical forest soils are underestimated as sinks for atmospheric CH4 with regard to worldwide GHG budgets (Werner et al. 2007, J GEOPHYS RES Vol. 112). Even though these soils are an important source for the atmospheric N2O budget, N2O emissions from tropical forest ecosystems are still poorly characterized (Castaldi et al. 2013, Biogeosciences 10). To obtain an insight of GHG balances of selected ecosystems soil-atmosphere exchange of N2O, CH4 and CO2 was investigated along the southern slope of Mt. Kilimanjaro, Tanzania. We will present results for tropical forests in three different altitudes (lower montane, Ocotea, and Podocarpus forest), home garden (extensive agro-forestry), and coffee plantation (intensive agro-forestry). Therefore we used a combined approach consisting of a laboratory parameterization experiment (3 temperature and 2 moisture levels) and in situ static chamber measurements for GHG exchange. Field measurements were conducted during different hygric seasons throughout two years. Seasonal variation of temperature and especially of soil moisture across the different ecosystems resulted in distinct differences in GHG exchange. In addition environmental parameters like soil bulk density and substrate availability varying in space strongly influenced the GHG fluxes within sites. The results from parameterization experiments and in situ measurements show that natural forest ecosystems and extensive land use had higher uptakes of CH4. For the investigated forest ecosystems we found considerable differences in soil sink strength for CH4. N2O emissions were highest in natural forest ecosystems even though N input in the intensively managed system was considerably higher. Highest N2O efflux rates were identified in the region of highest mean annual precipitation. CO2 emissions reduced from managed to natural ecosystems. In general an increase in temperature as well as in soil moisture caused higher GHG fluxes throughout all investigated natural and managed ecosystems. With increasing altitude of the investigated forests GHG emissions reduced overall.
http://meetingorganizer.copernicus.org/EGU2014/EGU2014-10821.pdf
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