TY  - JOUR
A1  - Germer, Sonja
A1  - Zimmermann, Alexander
A1  - Neill, Christopher
A1  - Krusche, Alex V.
A1  - Elsenbeer, Helmut
T1  - Disproportionate single-species contribution to canopy-soil nutrient flux in an Amazonian rainforest
JF  - Forest ecology and management
N2  - Rainfall, throughfall and stemflow were monitored on an event basis in an undisturbed open tropical rainforest with a large number of palm trees located in the southwestern Amazon basin of Brazil. Stemflow samples were collected from 24 trees with a diameter at breast height (DBH) > 5 cm, as well as eight young and four full-grown babassu palms (Attalea speciosa Mart.) for 5 weeks during the peak of the wet season. We calculated rainfall, throughfall and stemflow concentrations and fluxes of Na+, K+, Ca2+, Mg2+,, Cl-, SO42-, NO3- and H+ and stemflow volume-weighted mean concentrations and fluxes for three size classes of broadleaf trees and three size classes of palms. The concentrations of most solutes were higher in stemflow than in rainfall and increased with increasing tree and palm size. Concentration enrichments from rainfall to stemflow and throughfall were particularly high (81-fold) for NO3-. Stemflow fluxes of NO3- and H+ exceeded throughfall fluxes but stemflow fluxes of other solutes were less than throughfall fluxes. Stemflow solute fluxes to the forest soil were dominated by fluxes on babassu palms, which represented only 4% of total stem number and 10% of total basal area. For NO3-, stemflow contributed 51% of the total mass of nitrogen delivered to the forest floor (stemflow + throughfall) and represented more than a 2000-fold increase in NO3- flux compared what would have been delivered by rainfall alone on the equivalent area. Because these highly localized fluxes of both water and NO3- persist in time and space, they have the potential to affect patterns of soil moisture, microbial populations and other features of soil biogeochemistry conducive to the creation of hotspots for nitrogen leaching and denitrification, which could amount to an important fraction of total ecosystem fluxes. Because these hotspots occur over very small areas, they have likely gone undetected in previous studies and need to be considered as an important feature of the biogeochemistry of palm-rich tropical forest.
KW  - Stemflow
KW  - Throughfall
KW  - DBH
KW  - Open tropical rain forest
KW  - Babassu palm (Attalea speciosa Mart. synonym: Orbignya phalerata Mart.)
KW  - Amazonia
Y1  - 2012
U6  - https://doi.org/10.1016/j.foreco.2011.11.041
SN  - 0378-1127
VL  - 267
IS  - 2
SP  - 40
EP  - 49
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - JOUR
A1  - Bäse, Frank
A1  - Elsenbeer, Helmut
A1  - Neill, Christopher
A1  - Krusche, Alex V.
T1  - Differences in throughfall and net precipitation between soybean and transitional tropical forest in the southern Amazon, Brazil
JF  - Agriculture, ecosystems & environment : an international journal for scientific research on the relationship of agriculture and food production to the biosphere
N2  - The expansion of soybean cultivation into the Amazon in Brazil has potential hydrological effects at local to regional scales. To determine the impacts of soybean agriculture on hydrology, a comparison of net precipitation (throughfall, stemflow) in undisturbed tropical forest and soybean fields on the southern edge of the Amazon Basin in the state of Mato Grosso is needed. This study measured throughfall with troughs and stemflow with collar collectors during two rainy seasons. The results showed that in forest 91.6% of rainfall was collected as throughfall and 0.3% as stemflow, while in soybean fields with two-month old plants, 46.2% of rainfall was collected as throughfall and 9.0% as stemflow. Hence, interception of precipitation in soybean fields was far greater than in intact forests. Differences in throughfall, stemflow and net precipitation were found to be mainly associated with differences in plant structure and stem density in transitional forest and soybean cropland. Because rainfall interception in soybean fields is higher than previously believed and because both the area of cropland and the frequency of crop cycles (double cropping) are increasing rapidly, interception needs to be reconsidered in regional water balance models when consequences of land cover changes are analyzed in the Amazon soybean frontier region. Based on the continued expansion of soybean fields across the landscape and the finding that net precipitation is lower in soy agriculture, a reduction in water availability in the long term can be assumed.
KW  - Throughfall
KW  - Net precipitation
KW  - Stemflow
KW  - Soybean
KW  - Tropical forest
Y1  - 2012
U6  - https://doi.org/10.1016/j.agee.2012.06.013
SN  - 0167-8809
VL  - 159
SP  - 19
EP  - 28
PB  - Elsevier
CY  - Amsterdam
ER  - 
TY  - JOUR
A1  - Neill, Christopher
A1  - Coe, Michael T.
A1  - Riskin, Shelby H.
A1  - Krusche, Alex V.
A1  - Elsenbeer, Helmut
A1  - Macedo, Marcia N.
A1  - McHorney, Richard
A1  - Lefebvre, Paul
A1  - Davidson, Eric A.
A1  - Scheffler, Raphael
A1  - Figueira, Adelaine Michela e Silva
A1  - Porder, Stephen
A1  - Deegan, Linda A.
T1  - Watershed responses to Amazon soya bean cropland expansion and intensification
JF  - Philosophical transactions of the Royal Society of London : B, Biological sciences
N2  - The expansion and intensification of soya bean agriculture in southeastern Amazonia can alter watershed hydrology and biogeochemistry by changing the land cover, water balance and nutrient inputs. Several new insights on the responses of watershed hydrology and biogeochemistry to deforestation in Mato Grosso have emerged from recent intensive field campaigns in this region. Because of reduced evapotranspiration, total water export increases threefold to fourfold in soya bean watersheds compared with forest. However, the deep and highly permeable soils on the broad plateaus on which much of the soya bean cultivation has expanded buffer small soya bean watersheds against increased stormflows. Concentrations of nitrate and phosphate do not differ between forest or soya bean watersheds because fixation of phosphorus fertilizer by iron and aluminium oxides and anion exchange of nitrate in deep soils restrict nutrient movement. Despite resistance to biogeochemical change, streams in soya bean watersheds have higher temperatures caused by impoundments and reduction of bordering riparian forest. In larger rivers, increased water flow, current velocities and sediment flux following deforestation can reshape stream morphology, suggesting that cumulative impacts of deforestation in small watersheds will occur at larger scales.
KW  - soya beans
KW  - watersheds
KW  - nitrogen
KW  - phosphorus
KW  - soil
Y1  - 2013
U6  - https://doi.org/10.1098/rstb.2012.0425
SN  - 0962-8436
SN  - 1471-2970
VL  - 368
IS  - 1619
PB  - Royal Society
CY  - London
ER  - 
TY  - JOUR
A1  - Neill, Christopher
A1  - Jankowski, KathiJo
A1  - Brando, Paulo M.
A1  - Coe, Michael T.
A1  - Deegan, Linda A.
A1  - Macedo, Marcia N.
A1  - Riskin, Shelby H.
A1  - Porder, Stephen
A1  - Elsenbeer, Helmut
A1  - Krusche, Alex V.
T1  - Surprisingly Modest Water Quality Impacts From Expansion and Intensification of Large-Sscale Commercial Agriculture in the Brazilian Amazon-Cerrado Region
JF  - Tropical conservation science
N2  - Large-scale commercial cropping of soybeans expanded in the tropical Amazon and Cerrado biomes of Brazil after 1990. More recently, cropping intensified from single-cropping of soybeans to double-cropping of soybeans with corn or cotton. Cropland expansion and intensification, and the accompanying use of mineral fertilizers, raise concerns about whether nutrient runoff and impacts to surface waters will be similar to those experienced in commercial cropland regions at temperate latitudes. We quantified water infiltration through soils, water yield, and streamwater chemistry in watersheds draining native tropical forest and single-and double-cropped areas on the level, deep, highly weathered soils where cropland expansion and intensification typically occurs. Although water yield increased four-fold from croplands, streamwater chemistry remained largely unchanged. Soil characteristics exerted important control over the movement of nitrogen (N) and phosphorus (P) into streams. High soil infiltration rates prevented surface erosion and movement of particulate P, while P fixation in surface soils restricted P movement to deeper soil layers. Nitrogen retention in deep soils, likely by anion exchange, also appeared to limit N leaching and export in streamwater from both single-and double-cropped watersheds that received nitrogen fertilizer. These mechanisms led to lower streamwater P and N concentrations and lower watershed N and P export than would be expected, based on studies from temperate croplands with similar cropping and fertilizer application practices.
KW  - water
KW  - quality
KW  - agriculture
KW  - intensification
KW  - impact
Y1  - 2017
U6  - https://doi.org/10.1177/1940082917720669
SN  - 1940-0829
VL  - 10
PB  - Sage Publ.
CY  - Thousand Oaks
ER  -