Land Use, Not Stream Order, Controls N<sub>2</sub>O Concentration and Flux in the Upper Mara River Basin, Kenya

Mwanake, Ricky; Gettel, Gretchen M.; Aho, Kelly S.; Namwaya, D.W.; Masese, Frank O.; Butterbach‐Bahl, Klaus; Raymond, Peter A.

doi:10.1029/2019jg005063

Cited by 44 publications

(30 citation statements)

References 48 publications

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“…On the other hand, this study reports higher N 2 O concentration than a river in New Zealand (114% saturation, Clough et al 2011) and African rivers in general (0.26 μ g‐N L −1 , Borges et al 2015), and higher N 2 O fluxes than a coastal watershed in North Carolina (0.31 mg‐N m −2 d −1 , Stow et al 2005), rivers on the Tibetan Plateau (0.18 mg‐N m −2 d −1 , Qu et al 2017), and boreal rivers (0.05 mg‐N m −2 d −1 , Soued et al 2016). However, our average N 2 O concentration is lower than nearby first‐order streams in Connecticut (0.63 μ atm, Aho and Raymond 2019), forested (1.6 ± 2.1 μ g‐N L −1 ) and agriculture (1.3 ± 1.8 μ g‐N L −1 ) streams in Sweden (Audet et al 2020), and agriculture‐influenced rivers in Kenya (0.51 μ g‐N L −1 , Mwanake et al 2019), Belgium (1406%, Borges et al 2018), and the Upper Mississippi River (250%, Turner et al 2016). In summary, the forested watershed in this study had moderate N 2 O concentration and fluxes compared to global rivers and streams of various land uses and land covers, with values higher than boreal and alpine watersheds but lower than many headwater streams and agriculture‐influenced systems.…”

Section: Discussionmentioning

confidence: 99%

“…Spatiotemporal controls on lotic N 2 O dynamics are poorly understood, which limits modeling efforts. Spatially, urban (McMahon and Dennehy 1999; Beaulieu et al 2010; Beaulieu et al 2011) and agriculture (Beaulieu et al 2011; Audet et al 2017; Mwanake et al 2019) landcover types have been associated with high terrestrial nitrogen loading and subsequent high lotic N 2 O emissions. However, a recent study showed that forested rivers have similar N 2 O concentration as agriculture rivers (Audet et al 2020).…”

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confidence: 99%

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An intense precipitation event causes a temperate forested drainage network to shift from N₂O source to sink

Aho

Fair

Hosen

et al. 2022

Limnology & Oceanography

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Nitrous oxide (N2O) evasion from streams and rivers is a significant, yet highly uncertain, flux in nitrogen cycle models. Most global estimates of lotic N2O emission assume that evasion rates are proportional to inorganic nitrogen inputs to a stream or river. However, many field studies do not detect relationships between lotic N2O evasion and dissolved nitrogen concentration, highlighting the need for better understanding of process‐based controls on this flux. This study reports 4‐yr time series of pN2O and N2O evasion from eight nested streams and rivers and detects an abrupt change in N2O dynamics associated with an intense rainstorm. This rainstorm, and the associated hydrologic flood event, pushed forested reaches across the watershed from consistent N2O sources to prolonged N2O sinks. We attribute this shift to disturbance of incomplete denitrification in the stream network and surrounding watershed, although alternate hypotheses are also discussed. There was continued availability of nitrate (NO3−) for in‐stream processing, eliminating the possibility that NO3−‐availability limited N2O production, and post‐storm N2O‐to‐nitrate ratios were lower than pre‐storm ratios suggesting that the large storm affected in‐situ nitrogen processing rates. The sustained period of post‐storm N2O undersaturation resulted in net negative evasion for five of the eight study sites in 2018, which mitigated emissions over the 4‐yr study. This nonlinear response in N2O dynamics illustrates the potential importance of storm events to control lotic N2O production and emissions.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

An intense precipitation event causes a temperate forested drainage network to shift from N₂O source to sink

Aho

Fair

Hosen

et al. 2022

Limnology & Oceanography

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“…However, areas under current agricultural production when converted to agroforestry lead to a decrease in runoff while increasing groundwater uptakethis is often because of the choice of tree species sich as Eucalyptus that has a massive water demand (Hubbard et al, 2020). Land use, predominantly deforestation and transition to agriculture, was found to influence nitrous oxide levels in the lower elevations of the Mara River network (Mwanake et al, 2019). The effect of forest cover loss leading to reduced capacity to act as a catchment during heavy rainfall and mediate streamflow was identified as a major disruptor to economic activities to the south-west of Mau (Otuoma et al, 2012).…”

Section: The Early and Middle Holocene: 240-100 CMmentioning

confidence: 99%

“…Recent politicking has led to increased illegal settlement, logging and charcoal burning in the forest as a source of income (Nkako et al, 2005;Were et al, 2013). These increased human population pressures on the forests have further fragmented wildlife populations, with subsequent erosion and water distribution issues having consequences for downstream ecosystems and populations (Gichana et al, 2015;Mwangi et al, 2017;Dutton et al, 2018;Mwanake et al, 2019). Neighbouring Mau forest blocks have undergone varying degrees of anthropogenic modifications impacting vegetation biodiversity, soil geochemistry and topsoil seed bank; however, ecological restoration potential remains (Kinjanjui et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Late Pleistocene and Holocene Afromontane vegetation and headwater wetland dynamics within the Eastern Mau Forest, Kenya

Githumbi

Mustaphi

Marchant

2021

J Quaternary Science

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The Mau Forest Complex is Kenya's largest fragment of Afromontane forest, providing critical ecosystem services, and has been subject to intense land use changes since colonial times. It forms the upper catchment of rivers that drain into major drainage networks, thus supporting the livelihoods of millions of Kenyans and providing important wildlife areas. We present the results of a sedimentological and palynological analysis of a Late Pleistocene-Holocene sediment record of Afromontane forest change from Nyabuiyabui wetland in the Eastern Mau Forest, a highland region that has received limited geological characterization and palaeoecological study. Sedimentology, pollen, charcoal, X-ray fluorescence and radiocarbon data record environmental and ecosystem change over the last~16 000 cal a BP. The pollen record suggests Afromontane forests characterized the end of the Late Pleistocene to the Holocene with dominant taxa changing from Apodytes, Celtis, Dracaena, Hagenia and Podocarpus to Cordia, Croton, Ficus, Juniperus and Olea. The Late Holocene is characterized by a more open Afromontane forest with increased grass and herbaceous cover. Continuous Poaceae, Cyperaceae and Juncaceae vegetation currently cover the wetland and the water level has been decreasing over the recent past. Intensive agroforestry since the 1920s has reduced Afromontane forest cover as introduced taxa have increased (Pinus, Cupressus and Eucalyptus).

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“…It is also anticipated that the GHG emissions will increase soon due to modern land-use changes that the sub-Saharan Africa region has adopted (Popp et al 2010). Although the fluxes are anticipated to be high, there are various uncertainties in the estimates provided due to large insufficient temporal and spatial representation of emissions from agricultural soils (Mwanake et al 2019). In SSA, these changes have significantly impacted the climatic patterns leading to more extended droughts and excessive rainfall that does not support agricultural productivity at the field level.…”

Section: Introductionmentioning

confidence: 99%

Greenhouse Gases Emissions in Agricultural Systems and Climate Change Effects in Sub- Saharan Africa

Ntinyari

Gweyi-Onyango

2021

African Handbook of Climate Change Adaptation

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Climate change has been viewed to result from anthropogenic human activities that have significantly altered the Nitrogen (N) cycle and carbon cycles, increasing the risks of global warming and pollution. A key cause of global warming is the increase in greenhouse gas emissions including methane, nitrous oxide, and carbon among others. The context of this chapter is based on a comprehensive desktop review on published scientific papers on climate change, greenhouse emissions, agricultural fertilizer use, modeling and projections of greenhouse gases emissions. Interestingly, sub-Saharan Africa (SSA) has the least emissions of the greenhouses gases accounting for only 7% of the total world’s emissions, implying that there is overall very little contribution yet it has the highest regional burden concerning climate change impacts. However, the values could be extremely higher than this due to lack of proper estimation and measurement tools in the region and therefore, caution needs to be taken early enough to avoid taking the trend currently experienced in developed nations. In SSA, agricultural production is the leading sector in emissions of N compound to the atmosphere followed by energy and transportation. The greatest challenge lies in the management of the two systems to ensure sufficiency in food production using more bioenergy hence less pollution. Integrating livestock and cropping systems is one strategy that can reduce methane emissions. Additionally, developing fertilizer use policy to improve management of fertilizer and organic manure have been potentially considered as effective in reducing the effects of agriculture activities on climate change and hence the main focus of the current chapter.

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Land Use, Not Stream Order, Controls N₂O Concentration and Flux in the Upper Mara River Basin, Kenya

Cited by 44 publications

References 48 publications

An intense precipitation event causes a temperate forested drainage network to shift from N₂O source to sink

An intense precipitation event causes a temperate forested drainage network to shift from N₂O source to sink

Late Pleistocene and Holocene Afromontane vegetation and headwater wetland dynamics within the Eastern Mau Forest, Kenya

Greenhouse Gases Emissions in Agricultural Systems and Climate Change Effects in Sub- Saharan Africa

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Land Use, Not Stream Order, Controls N2O Concentration and Flux in the Upper Mara River Basin, Kenya

Cited by 44 publications

References 48 publications

An intense precipitation event causes a temperate forested drainage network to shift from N2O source to sink

An intense precipitation event causes a temperate forested drainage network to shift from N2O source to sink

Late Pleistocene and Holocene Afromontane vegetation and headwater wetland dynamics within the Eastern Mau Forest, Kenya

Greenhouse Gases Emissions in Agricultural Systems and Climate Change Effects in Sub- Saharan Africa

Contact Info

Product

Resources

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Land Use, Not Stream Order, Controls N₂O Concentration and Flux in the Upper Mara River Basin, Kenya

An intense precipitation event causes a temperate forested drainage network to shift from N₂O source to sink

An intense precipitation event causes a temperate forested drainage network to shift from N₂O source to sink