Publications
Found 33 publication(s)
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Landshuter, N.; Mölg, T.; Grießinger, J.; Bräuning, A.; Peters, T. & Institute of Geography, F.E.E.G. (2020): Characteristics of moisture source regions and their potential effect on seasonal isotopic signatures of d18O in tropical trees of southern Ecuador. Frontiers in Earth Science 8(604804), 1-22.
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DOI: 10.3389/feart.2020.604804
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Abstract:
Abstract:
Ratios of stable oxygen isotopes in tree rings (δ18O) are a valuable proxy for reconstructing past climates. Such reconstructions allow us to gain better knowledge of climate dynamics under different (eg warmer) environmental conditions, which also forms the basis for effective risk management. The latter aspect is particularly relevant for our study site on the
western flanks of the Andes in Southern Ecuador, since the region is frequently affected by droughts and heavy precipitation events during the rainy season (January to April), leading to enormous social and economic losses. In particular, we focus on precipitation amounts and moisture source regions as they are known to influence the δ18O signature of tree rings. Moisture source regions are based on 240 h backward trajectories that were
calculated with the trajectory model LAGRANTO for the rainy seasons 2008 to 2017. A moisture source diagnostic was applied to the air parcel pathways. The resulting moisture source regions were analyzed by calculating composites based on precipitation amounts, season, and calendar year. The precipitation amounts were derived from data of a local Automatic Weather Station (AWS). The analysis confirms that our study site receives its moisture both, from the Atlantic and the Pacific Oceans.
Heavy precipitation events are linked to higher moisture contributions from the Pacific, and local SST anomalies along the coast of Ecuador are of higher importance than those off the coast toward the central Pacific. Moreover, we identified increasing moisture contributions from the Pacific over the course of the rainy season. This change and also rain amount
effects are detectable in preliminary data of δ18O variations in tree rings of Bursera graveolens. These signatures can be a starting point for investigating atmospheric and hydroclimatic processes, which trigger δ18O variations in tree rings, more extensively in future studies.
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Keywords: |
precipitation |
South Ecuador |
South America |
tropical trees |
Tree Rings |
modelling |
stable isotopes |
Knoke, T.; Paul, C.; Rammig, A.; Gosling, E.; Hildebrandt, P.; Härtl, F.; Peters, T.; Richter, M.; Diertl, K.; Castro, L.M.; Calvas, B.; Ochoa Moreno, S.; Valle-Carrión, L.A.; Hamer, U.; Tischer, A.; Potthast, K.; Windhorst, D.; Homeier, J.; Wilcke, W.; Velescu, A.; Gerique, A.; Pohle, P.; Adams, J.; Breuer, L.; Mosandl, R.; Beck, E.; Weber, M.; Stimm, B.; Silva, B.; Verburg, P.H. & Bendix, J. (2020): Accounting for multiple ecosystem services in a simulation of land-use decisions: Does it reduce tropical deforestation?. Global Change Biology 26( ), 1-22.
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DOI: 10.1111/gcb.15003
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Abstract:
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Abstract Conversion of tropical forests is among the primary causes of global environmental change. The loss of their important environmental services has prompted calls to integrate ecosystem services (ES) in addition to socio-economic objectives in decision-making. To test the effect of accounting for both ES and socio-economic objectives in land-use decisions, we develop a new dynamic approach to model deforestation scenarios for tropical mountain forests. We integrate multi-objective optimization of land allocation with an innovative approach to consider uncertainty spaces for each objective. These uncertainty spaces account for potential variability among decision-makers, who may have different expectations about the future. When optimizing only socio-economic objectives, the model continues the past trend in deforestation (1975–2015) in the projected land-use allocation (2015–2070). Based on indicators for biomass production, carbon storage, climate and water regulation, and soil quality, we show that considering multiple ES in addition to the socio-economic objectives has heterogeneous effects on land-use allocation. It saves some natural forest if the natural forest share is below 38%, and can stop deforestation once the natural forest share drops below 10%. For landscapes with high shares of forest (38%–80% in our study), accounting for multiple ES under high uncertainty of their indicators may, however, accelerate deforestation. For such multifunctional landscapes, two main effects prevail: (a) accelerated expansion of diversified non-natural areas to elevate the levels of the indicators and (b) increased landscape diversification to maintain multiple ES, reducing the proportion of natural forest. Only when accounting for vascular plant species richness as an explicit objective in the optimization, deforestation was consistently reduced. Aiming for multifunctional landscapes may therefore conflict with the aim of reducing deforestation, which we can quantify here for the first time. Our findings are relevant for identifying types of landscapes where this conflict may arise and to better align respective policies.
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Keywords: |
Ecuador |
biodiversity |
ecosystem services |
landscape restoration |
land allocation |
robust optimization |
Butz, P.; Raffelsbauer, V.; Graefe, S.; Peters, T.; Cueva, E.; Hölscher, D. & Bräuning, A. (2016): Tree responses to moisture fluctuations in a neotropical dry forest as potential climate change indicators. Ecological Indicators 1(1), 1-13.
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DOI: 10.1016/j.ecolind.2016.11.021
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Trees in tropical dry forests (TDFs) have manifold drought coping strategies including succulence of different plant organs, wood anatomical traits and leaf phenology. As water availability to plants is the limiting factor for physiological activity, changes in precipitation patterns are assumed to have strong influences on tree phenology, growth and water turnover. Our objectives were to assess patterns in leaf phenology, radial stem circumference changes and sap flux responses to fluctuating moisture regimes of selected species. Based on these findings we evaluated the potential suitability as indicator species for climate change effects. The study was implemented at different elevational positions in a submontane dry forest of southern Ecuador. Annual rainfall is 600 mm with an eight months dry period; moisture availability slightly increases with altitude because of moist air coming from the Pacific. At three altitudes,we studied the tree species Ceiba trichistandra (leaf deciduous, stem succulent), Eriotheca ruizii (leaf deciduous, root succulent) and Erythrina velutina (leaf deciduous). Reversible stem swelling and shrinking was observed for all three species during the whole study period and at all positions at the altitudinal gradient. However, it was most pronounced and sensitive in the stem succulent C. trichistandra and at the lowest (driest) position. C. trichistandra flushed leaves at dry season intermittent rain events, and from dry to wet season leaf out was earlier, and in this period sap flux was high while stem circumference decreased. Length of the leaved periods of all species increased with altitude. Thus, clear differences among species, topographic positions, radial growth and tree water use patterns are revealed; especially C. trichistandra responded very sensitive to fluctuating moisture regimes with leaf phenology, sap flux and stem diameter variations, and can be regarded as a sensitive indicator for assessing climatic variations.
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Keywords: |
Ecuador |
Phenology |
Elevation gradient |
Sap flux |
Seasonality |
Tree indicator |
Spannl, S.; Volland, F.; Pucha Cofrep, D.A.; Peters, T.; Cueva, E. & Bräuning, A. (2016): Climate variability, tree increment patterns and ENSO-related carbon sequestration reduction of the tropical dry forest species Loxopterygium huasango of Southern Ecuador. Trees Structure and Function e(e), e.
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DOI: DOI 10.1007/s00468-016-1362-0
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Abstract:
Abstract:
We present the first multi-year long time series
of local climate data in the seasonally dry tropical forest in
Southern Ecuador and related growth dynamics of Loxopterygium
huasango, a deciduous tree species. Local climate
was investigated by installing an automatically
weather station in 2007 and the daily tree growth variability
was measured with high-resolution point dendrometers.
The climatic impact on growth behaviour was
evaluated. Hydro-climatic variables, like precipitation and
relative humidity, were the most important factors for
controlling tree growth. Changes in rainwater input affected
radial increment rates and daily amplitudes of stem
diameter variations within the study period from 2009 to
2013. El Nin˜o Southern Oscillation (ENSO) related
variations of tropical Pacific Ocean sea surface temperatures
influenced the trees’ increment rates. Average radial
increments showed high inter-annual (up to 7.89 mm) and
inter-individual (up to 3.88 mm) variations. Daily amplitudes
of stem diameter variations differed strongly between
the two extreme years 2009 (wet) and 2011 (dry). Contrary
to 2009, the La Nin˜a drought in 2011 caused a rapid
reduction of the daily amplitudes, indicating a total cessation
(‘growth collapse’) of stem increment under ENSOrelated
drought conditions and demonstrating the high
impact of climatic extreme events on carbon sequestration
of the dry tropical forest ecosystem.
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Keywords: |
Ecuador |
dendrometer |
dendroecology |
Climate variability |
La Nina drought |
Seasonally dry tropical forest |
Pucha Cofrep, D.A.; Peters, T. & Bräuning, A. (2015): Wet season precipitation during the past 120 years reconstructed from tree rings of a tropical dry forest in Southern Ecuador. Global and Planetary Change 133, 65–78.
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DOI: 10.1016/j.gloplacha.2015.08.003
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Abstract:
Abstract:
From 10 selected tree species, Bursera graveolens and Maclura tinctoria exhibited distinct annual and crossdatable tree-rings. It was possible to synchronize individual tree-ring series and to establish two tree-ring chronologies of 203 and 87 years length, respectively. The characteristic ENSO frequency band is reflected in wavelet
power spectra of both chronologies. Both species showa strong correlation between ringwidth and precipitation of thewet season (January–May). Strong El Niño events (1972, 1983 and 1998) lead to strong growth responses in the tree-ring chronologies, whereas ‘normal’ ENSO events do not trigger long-lasting growth responses. The first ring-width based wet-season precipitation reconstruction for the past 103 years was developed. Statistical and spatial correlation analysis verified the skills of the reconstructed precipitation which captures a great part of the Rainfall Index over the land area of Ecuador and the equatorial Pacific. Furthermore, teleconnections with central Pacific precipitation and SST patterns were found.
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Keywords: |
Ecuador |
precipitation |
tree growth |
wood anatomy |
dendroecology |
el nino |
ENSO |
tree rings |
dendrochronology |
dry forest |
Spannl, S.; Günter, S.; Peters, T.; Volland, F. & Bräuning, A. (2012): Which factors control tree growth in a tropical mountain forest? The case of Cedrela montana in Southern Ecuador. TRACE - Tree Rings in Archaeology, Climatology and Ecology 10, 99-105.
Peters, T.; Drobnik, T.; Meyer, H.; Rankl, M.; Richter, M.; Rollenbeck, R.; Thies, B. & Bendix, J. (2014): Environmental Changes Affecting the Andes of Ecuador. In: Bendix, J., Beck, E., Bräuning, A., Makeschin, F., Mosandl, R., Scheu, S., Wilcke, W. (eds.): Ecosystem Services, Biodiversity and Environmental Change in a Tropical Mountain Ecosystem of South ( ), Springer.
Spannl, S.; Ganzhi, O.; Peters, T. & Bräuning, A. (2013): Tree growth under climatic and trophic forcing - A nutrient manipulation experiment in Southern Ecuador. TRACE - Tree Rings in Archaeology, Climatology and Ecology 11, 10-14.
Peters, T. (2014): Water Balance in Tropical Regions. In: Michael Koehl, Laszlo Pancel (eds.): Tropical Forestry Handbook ( ), Springer, Heidelberg.
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DOI: 10.1007/SpringerReference_384452
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Abstract:
Abstract:
Within this chapter relative air humidity, evaporation, transpiration, evapotranspiration, hydrologic cycle and water balance are discussed for the Tropics. In general, atmospheric water is of high climatological importance due to its capacity to control precipitation as well as to its influence on absorption and reflection of solar and terrestrial radiation. When water changes its state of aggregation, energy is either produced or consumed. This is crucial for the tropical atmosphere where the condensation of large amounts of water vapor leads to the release of latent heat energy. The global hydrosphere consists of a couple of different water reservoirs which are connected by water fluxes in various phases. From these
reservoirs, water moves in a great series of continuous interchanges of both physical state and geographical position, known as the hydrologic cycle. Evapotranspiration is one of the most important factors for the water budget and physical processes in the tropics. It specifies the total flow of water into the atmosphere which is composed of two processes: evaporation and transpiration.
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Keywords: |
Climate - Evaporation - Evapotranspiration - Hydrologic cycle - Relative air humidity - Transpiratio |
Peters, T. & Richter, M. (2014): The Atmospheric Circulation. In: Michael Koehl, Laszlo Pancel (eds.): Tropical Forestry Handbook ( ), Springer, Heidelberg.
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DOI: 10.1007/SpringerReference_384448
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Abstract:
Abstract:
Within this chapter the Hadley Circulation, the Monsoon System, Easterly Waves, Tropical Cyclones and the Walker Circulation are discussed. While the Hadley Circulation and the Monsoon System explain different air flow systems in a mainly meridional sense, a secondary system of latitudinal wind flow is governed by the Walker circulation which is decisive for the formation of La Niña and El Niño events. Apart from the long-term seasonal and nonseasonal variations of the tropical atmosphere, the climate of the Tropics is also affected by more frequent tropical weather disturbances. One of them are large-scale planetary waves which produce greater amounts of rainfall in many maritime tropical regions. These disturbance lines sprawl in a meridional direction from east to west and are called easterly waves.
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Keywords: |
Easterly waves - Hadley circulation - Monsoon system - Tradewind system - Tropical cyclones - Walker |
Peters, T. (2014): Radiation and Heat in the Tropics. In: Michael Koehl, Laszlo Pancel (eds.): Tropical Forestry Handbook ( ), Springer, Heidelberg.
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DOI: 10.1007/SpringerReference_384449
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Abstract:
Within this chapter different aspects of radiation and heat are discussed for the tropics. On a global scale the amount of annual solar radiation reaching the Earth's surface is determined by atmospheric and astronomical factors and the average energy budget of the Earth could be explained by the global radiation budget. Within the tropics the net radiation varies clearly across the different climatic regions. In the humid tropics the amount of net radiation shows an almost uniform annual pattern with two maxima per annum. In contrast to this, the horizontal course of the isopleths in a radiation isopleths diagram for the marginal tropics still indicates a marked diurnal cycle. At the Earth's surface, the total incoming
radiation is transformed into different heat fluxes which are either directed towards the ground or to the atmosphere. In the tropical rainforests, only 10 % of the incoming radiation reaches the ground, and only a weak flow of sensible and latent heat exists from the forest canopy towards the forest ground and vice versa.
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Keywords: |
Tropics - Radiation and Heat - Global Radiation Budget - Heat Budget - Sensible and Latent Heat |
Peters, T. (2014): Design of Data Collection Related to the Climate in the Tropics. In: Michael Koehl, Laszlo Pancel (eds.): Tropical Forestry Handbook ( ), Springer, Heidelberg.
Peters, T. (2014): Climatic Types of Water Balances in the Tropics. In: Michael Koehl, Laszlo Pancel (eds.): Tropical Forestry Handbook ( ), Springer, Heidelberg.
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DOI: 10.1007/SpringerReference_384414
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Abstract:
Abstract:
One of the most important climate criteria of the tropics is the absence of thermic seasons. Thus, hygric seasons become more relevant for ecosystem functioning and are of special importance for plant growth. Within this chapter different climate types of the tropics are discussed on the basis of their annual water budget. The humid climate type appears across the rain equator within or close to the ITCZ. It is distinguished by a clear water surplus and all months show a positive water balance in the long-term mean. The semi-humid climate type prevails at a certain distance from the Equator and the ITCZ. It is characterized by a distinct rainfall seasonality and the occurrence of more than 3 -4 arid months. In terms of the arid climate type the arid period is in general longer than the humid period and precipitation amounts decrease almost towards zero within the desert areas.
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Keywords: |
Tropics - Climatic Types - Hygric seasons - Humid Climate Type - Semi-Humid Climate Type - Arid Clim |
Peters, T. (2014): Climate Change in the Tropics. In: Michael Koehl, Laszlo Pancel (eds.): Tropical Forestry Handbook ( ), Springer, Heidelberg.
Wagemann, J.; Thies, B.; Rollenbeck, R.; Peters, T. & Bendix, J. (2015): Regionalization of wind-speed data to analyse tree-line wind conditions in the eastern Andes of southern Ecuador. Erdkunde 69, 3-19.
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DOI: 10.3112/erdkunde.2015.01.01
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This paper presents a method to extrapolate wind-speed data and to calculate wind-speed and dynamic pressure maps for the complex topography of a mountain rainforest area in the tropical Andes of southeastern Ecuador. The spatial differentiation of dynamic wind pressure in this area is claimed to be a major determinant of the altitude of the tree-line ecotone and to affect the tree line’s physiognomy. The paper presents a hybrid method encompassing statistical data analysis using the Weibull distribution and a digital terrain analysis, taking topographical shelter effects into account. The method is used to derive mean and maximum wind-speed and dynamic pressure maps to reveal whether the tree-line ecotone is influenced by direct wind effects. On average, the tree-line ecotone on the eastern slopes shows a clear average depression of ~50 m. These slopes are affected by higher dynamic wind stress, so have a more disturbed canopy. These altered vegetation structures may be caused mainly by direct wind effects and to a smaller extent by indirect effects, such as high humidity.
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Keywords: |
wind speed |
regionalization |
Werner, F.A.; Jantz, N.; Krashevska, V.; Peters, T.; Behling, H.; Maraun, M.; Scheu, S. & Brehm, G. (2014): Climate Change Effects on Biodiversity and Ecosystem Functioning. In: Bendix, J., Beck, E., Bräuning, A., Makeschin, F., Mosandl, R., Scheu, S., Wilcke, W. (eds.): Ecosystem Services, Biodiversity and Environmental Change in a Tropical Mountain Ecosystem of South ( ), Springer.
Fries, A.; Rollenbeck, R.; Bayer, F.; Gonzalez, V.; Oñate-Valivieso, F.; Peters, T. & Bendix, J. (2014): Catchment precipitation processes in the San Francisco valley in southern Ecuador: combined approach using high-resolution radar images and in situ observations. Meteorology and Atmospheric Physics 703, x.
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DOI: 10.1007/s00703-014-0335-3
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Abstract:
The precise estimation of precipitation quantities in tropical mountain regions is in great demand by ecological and hydrological studies, due to the heterogeneity of the rainfall distribution and the lack of meteorological station data. This study uses radar images and ground station data to provide the required high-resolution precipitation maps. Also wind data are taken into account, due to its influence on the precipitation formation and to demonstrate the relation between synoptic wind, topography and the precipitation distribution inside small mountain valleys. The study analyses the rainfall distribution and amounts of 4 days inside the San Francisco Valley, a small catchment in the tropical Andes of southern Ecuador, representing different seasons and the typical atmospheric flows, which are correlated to the annual precipitation map. The results show that the rainfall distribution and amounts are generally defined by the wind direction and velocity, besides the topographic location in relation to the main barriers and pathways. The dominant wind direction causes a division of the catchment in a wetter eastern and a dryer western part. Moreover, the annual seasons are reversed; the main rainy season for the eastern part occurs between June and August, while the western part reaches the precipitation maximum between January and March. This may have influence on the species composition at the different slopes and the annual hydrological cycle inside the catchment.
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Keywords: |
Atmospheric Sciences |
Meteorology |
Terrestrial Pollution |
Waste Water Technology |
Water Pollution Control |
Water Management |
Aquatic Pollution |
Peters, T.; Bräuning, A.; Münchow, J. & Richter, M. (2014): An ecological paradox: high species diversity and low position of the upper forest line in the Andean Depression. Ecology and Evolution ece.3.1078, 1-12.
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DOI: DOI:10.1002/ece3.1078
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Abstract:
Systematic investigations of the upper forest line (UFL) primarily concentrate on mid and high latitudes of the Northern Hemisphere, whereas studies of Neotropical UFLs are still fragmentary. This article outlines the extraordinary high tree diversity at the UFL within the Andean Depression and unravels the links between the comparatively low position of the local UFL, high tree-species diversity, and climate. On the basis of Gentry?s rapid inventory methodology for the tropics, vegetation sampling was conducted at 12 UFL sites, and local climate (temperature, wind, precipitation, and soil moisture) was investigated at six sites. Monotypic forests dominated by Polylepis were only found at the higher located margins of the Andean Depression while the lower situated core areas were characterized by a species-rich forest, which lacked the elsewhere dominant tree-species Polylepis. In total, a remarkably high tree-species number of 255 tree species of 40 different plant families was found. Beta-diversity was also high with more than two complete species turnovers. A non-linear relationship between the floristic similarity of the investigated study sites and elevation was detected. Temperatures at the investigated study sites clearly exceeded 5.5°C, the postulated threshold value for the upper tree growth limit in the tropics. Instead, quasi-permanent trade winds, high precipitation amounts, and high soil water contents affect the local position of the UFL in a negative way. Interestingly, most of the above-mentioned factors are also contributing to the high species richness. The result is a combination of a clearly marked upper forest line depression combined with an extraordinary forest line complexity, which was an almost unknown paradox.
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Keywords: |
climate |
air temperature |
Andes |
Biodiversity |
upper forest line |
andean depression |
Wilcke, W.; Leimer, S.; Peters, T.; Emck, P.; Rollenbeck, R.; Trachte, K.; Valarezo, C. & Bendix, J. (2013): The nitrogen cycle of tropical montane forest in Ecuador turns inorganic under environmental change. Global Biogeochemical Cycles 27(4), 1194-1204.
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DOI: 10.1002/2012GB004471
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Abstract:
Abstract:
Water-bound nitrogen (N) cycling in temperate terrestrial ecosystems of the Northern
Hemisphere is today mainly inorganic because of anthropogenic release of reactive N to
the environment. In little-industrialized and remote areas, in contrast, a larger part of
N cycling occurs as dissolved organic N (DON). In a north Andean tropical montane forest
in Ecuador, the N cycle changed markedly during 1998–2010 along with increasing
N deposition and reduced soil moisture. The DON concentrations and the fractional
contribution of DON to total N significantly decreased in rainfall, throughfall, and soil
solutions. This inorganic turn of the N cycle was most pronounced in rainfall and became
weaker along the flow path of water through the system until it disappeared in stream water.
Decreasing organic contributions to N cycling were caused not only by increasing inorganic
N input but also by reduced DON production and/or enhanced DON decomposition.
Accelerated DON decomposition might be attributable to less waterlogging and higher
nutrient availability. Significantly increasing NO3-N concentrations and NO3-N/NH4-N
concentration ratios in throughfall and litter leachate below the thick organic layers indicated
increasing nitrification. In mineral soil solutions, in contrast, NH4-N concentrations increased and NO3-N/NH4-N concentration ratios decreased significantly, suggesting increasing net ammonification. Our results demonstrate that the remote tropical montane forests on the rim of the Amazon basin experienced a pronounced change of the N cycle in only one decade. This change likely parallels a similar change which followed industrialization in the temperate zone of the Northern Hemisphere more than a century ago.
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Keywords: |
climate change |
nitrification |
N deposition |
terrestrial N cycling |
dissolved organic N |
Fries, A.; Rollenbeck, R.; Nauss, T.; Peters, T. & Bendix, J. (2012): Near surface air humidity in a megadiverse Andean mountain ecosystem of southern Ecuador and its regionalization.. Agricultural and Forest Meteorology 152, 17-30.
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DOI: 10.1016/j.agrformet.2011.08.004
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Abstract:
Abstract:
The near surface humidity in a megadiverse mountain ecosystem in southern Ecuador is examined on the basis of Relative Humidity (RH) measurements inside the natural mountain forest and at open sites along an altitudinal gradient from 1700 to 3200 m. The main methodological aim of the current study is to generate a humidity regionalization tool to provide spatial datasets on average monthly mean, minimum and maximum RH, Specific Humidity (q) and Specific Saturation Deficit (DS) by using observation data of RH. The maps based on data of the period 1999–2009 are needed by ecological projects working on various plots where no climate station data are available. The humidity maps are generated by combining a straightforward detrending technique with a Digital Elevation Model and a satellite-based land cover classification which also provides the relative forest cover per pixel. The topical aim of the study is to investigate the humidity distribution and structure of both manifestations of our ecosystem (pastures and natural vegetation) with special considerations to the ecosystem regulation service by converting natural forest into pasture. The results reveal a clear differentiation over the year, partly triggered by the change of synoptic weather situation but also by land cover effects. Humidity amplitudes are particularly low during the main rainy season when cloudiness and rainfall are high, but markedly pronounced in the relative dry season when daily irradiance and outgoing nocturnal radiation causes distinct differences between the land cover units. Particularly the upper pasture areas gained by slash and burn of the natural forest exhibit the lowest humidity values while the humidity inside the mountain forest is significantly higher due to the regulating effects of the dense vegetation. Thus, clearing the forest clearly reduces the regulation function (regulating ecosystem services) of the ecosystem which might become problematic for reforestation under future global warming.
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Keywords: |
South Ecuador |
regionalization |
forest and open land |
distribution |
structure |
near surface humidity |
Volland, F.; Bräuning, A.; Ganzhi, O.; Peters, T. & Maza, H. (2011): Radial stem variations of Tabebuia chrysantha (Bignoniaceae) in different tropical forest ecosystems of southern Ecuador. Trees 25, 39-48.
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Abstract:
Abstract:
Stem diameter increments of the broadleaved deciduous tree species Tabebuia chrysantha were measured with high-resolution dendrometers in a tropical lower montane forest and in a dry forest in southern Ecuador, the latter showing a distinct dry season. Those analyses were complemented by wood anatomical studies on regularly collected microcores to determine the season of active cambial growth and the time of formation of annual growth boundaries. The length of the cambial active period varied between 3 and 7 months at the tropical lower montane forest and 2 and 4 months in the dry forest, respectively. During dry days, amplitudes of daily stem diameter variations correlated with vapour pressure deficit. During October and November, inter-annual climate variations may lead to dry and sunny conditions in the tropical lower montane forest, causing water deficit and stem diameter shrinkage in T. chrysantha. The results of the climate– growth analysis show a positive relationship between tree growth and rainfall as well as vapour pressure deficit in certain periods of the year, indicating that rainfall plays a major role for tree growth.
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Keywords: |
Ecuador |
dendrometer |
Tabebuia chrysantha |
tropical montane forest |
wood anatomy |
dendroecology |
Richter, M. & Peters, T. (2011): Klimavielfalt, Klimawandel und Klimafolgen in den tropischen Anden. Passauer Kontaktstudium Geographie 11, 159-175.
Roos, K.; Rollenbeck, R.; Peters, T.; Bendix, J. & Beck, E. (2010): Growth of Tropical Bracken (Pteridium arachnoideum): Response to Weather Variations and Burning. Invasive Plant Science and Management 3, 402-411.
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DOI: 10.1614/IPSM-D-09-00031.1
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Abstract:
Abstract:
The ecology of tropical bracken, which occurs in tropical regions, is not well known. We studied its response to weather variations and burning in the south Ecuadorian Andes, where this weed had already overgrown 40% of the pastureland. In field observations, a constant 1:1 ratio of emerging and dying leaves suggested limitation of frond density by nutrient shortage. Short-term deviations from that ratio could be related to weather variations. Spells of dry weather temporarily increased mortality but stimulated emergence of new fronds. Lifespan of the fronds produced immediately after a fire was longer than of those produced during unaffected bracken growth. A burst of frond development during the initial 2 to 3 mo was observed after a fire followed by self-thinning to a stable level. To analyze the effect of fire on bracken, rhizomes were treated with heat pulses. Rhizomes were heat tolerant up to 70 C, and frond production from short shoots was enhanced by elevated temperature. Burning apparently releases apical dominance of developed fronds, as does cutting, and stimulates bud break. The local practice of pasture maintenance in Ecuador of repeated burning favors growth of the fern.
Peters, T.; Diertl, K.; Adams, J.; Rankl, M. & Richter, M. (2010): Vascular Plant Diversity in Natural and Anthropogenic Ecosystems in the Andes of Southern Ecuador - Studies from the Rio San Francisco Valley. Mountain Research and Development 30, 344-352.
Bräuning, A.; Volland, F.; Peters, T.; Ganzhi, O. & Nauss, T. (2009): Climatic control of radial growth of Cedrela montana in a humid mountain rain forest in southern Ecuador.. Erdkunde 59, 337-345.
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Abstract:
Abstract:
Cedrela montana is a deciduous broad-leaved tree species growing in the humid mountain rainforests of southern Ecuador. High-resolution dendrometer data indicate a regular seasonal growth rhythm with cambial activity during January to April. Amplitudes of daily radial stem diameter variations are correlated with the amount of the maximum daily vapour pressure deficit. During humid periods, daily stem diameter variations are considerably smaller than during drier periods. This indicates that cambial activity is limited by available moisture even in such a very humid mountain climate. Wood anatomical studies on microcores show the formation of a marginal parenchyma band at the beginning of the growth period. This parenchyma band can be used to delineate annual growth rings. We were able to establish the first ring-width chronology from Cedrela montana which covers the time until 1840. However, the chronology is presently statistically robust back to 1910 only. Correlation functions calculated with NCEP/NCAR data indicate a significantly positive relationship of tree growth with temperatures during the growth period during January to April. However, only 8% of the growth variance is explained by this climatic factor. In the future, this relationship may be useful to reconstruct past temperature conditions of the study area.
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Keywords: |
Ecuador |
dendrometer |
Cedrela montana |
tropical montane forest |
wood anatomy |
tree rings |
dendrochronology |
Fries, A.; Rollenbeck, R.; Göttlicher, D.; Nauss, T.; Homeier, J.; Peters, T. & Bendix, J. (2009): Thermal structure of a megadiverse Andean mountain ecosystem in southern Ecuador and its regionalization. Erdkunde 63, 321-335.
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DOI: 10.3112/erdkunde.2009.04.03
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Abstract:
Abstract:
The thermal structure of a megadiverse mountain ecosystem in southern Ecuador is examined on the basis of temperature measurements inside the natural mountain forest and at open-sites along an altitudinal gradient from 1600 to 3200 m. The main methodological aim of the current study is to develop an air temperature regionalization tool to provide spatial datasets on average monthly mean, minimum and maximum temperature by using observation data. The maps, based on data of the period 1999?2007, are needed by ecological projects working on various plots where no climate station data are available. The temperature maps are generated by combining a straightforward detrending technique with a Digital Elevation Model and a satellite-based land cover classification which also provides the relative forest cover per pixel. The topical aim of the study is to investigate the thermal structure of both manifestations of our ecosystem (pastures and natural vegetation) with special considerations to the ecosystem temperature regulation service by converting natural forest into pasture. The results reveal a clear thermal differentiation over the year, partly triggered by the change of synoptic weather situation but also by land cover effects. Thermal amplitudes are particularly low during the main rainy season when cloudiness and air humidity are high, but markedly pronounced in the relative dry season when daily irradiance and outgoing nocturnal radiation cause distinct differences between the land cover units. Particularly the lower pasture areas gained by slash and burn of the natural forest exhibit the most extreme thermal conditions while the atmosphere inside the mountain forest is slightly cooler due to the regulating effects of the dense vegetation. Thus, clearing the forest clearly reduces the thermal regulation function (regulating ecosystem services) of the ecosystem which might become problematic under future global warming.
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Keywords: |
air temperature |
South Ecuador |
thermal structure |
regionalization |
forest and open land |
Peters, T. (2009): Struktur und ökologische Merkmale der oberen Waldgrenze in der Andinen Depression Institut für Geographie, FAU Erlangen-Nürnberg, phd thesis
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Abstract:
Abstract:
Since 1998, members of the DFG investigation group 402 (Since 2003 DFG investigation
group 816) devoted themselves to the analysis of a local mountainous rainforest system in
the Cordillera Real in southern Ecuador. The ?upper treeline? was subject to a closer study
because of the atypical lowering of the local treeline ecotone at 2600 to 3350 m a.s.l. and
the missing scientific findings on this topic. Within this thesis, methods of vegetation
research as well as climatologic and pedologic analysis were used. Vegetation was taken
up at ten different treeline sites ranging from the northern boundary of the Andes
Depression near Cuenca in southern Ecuador to Huancabamba in the north of Peru. At
each investigation area, eight vegetation transects (100 m2 each) were analysed and trees
with a trunk diameter of >5 cm were recorded to species lists.
The coverage of climatic parameters was carried out following the North-South-gradient at
six sites. Three of them were analysed in detail by means of comparative micro-climatic
measurements between forest and Páramo.
The pedologic research was carried out at three lower-located sites of the upper treeline
ecotone in the centre of the investigation area.
The chapter of results is ordered into three sections, namely, structures of vegetation and
its characteristics, climate and soil. In the chapter of botanical geography, syntaxonomic
similarity of each transect and site was calculated by means of statistical classification
methods and forest species with their particular populations were presented in detail.
Results show that the upper treeline of the Andes Depression is completely different from
the outer areas of the Depression in floristic terms. In the centre of the Andean Depression,
which is rich in endemic species, up to 66 tree species form part of the forest border line
(concerning an area of only 800 m2!). This number falls drastically at the northern edge of
the area of examination, where the upper treeline rises to barely more than 4000 m a.s.l.
Apart from the reduction of species with rising sea level, this fact can be postulated by
distribution of Polylepis and different treeline structures. Monotypic Polylepis forests
containing less species only exist at the northern edge of the Andes Depression and at the
most southern study site in the West of Huancabamba. At all other sites, polytypic forests
containing many different species are characteristic of the local treeline ecotone.
The sites? taxonomic differences can be confirmed by ordination methods, which allow a
clear floristic separation between Polylepis-free areas with populations of lowland taxa and
Polylepis-forests.
The different combinations of species are mainly due to variations in altitude, temperature,
the number of humid months, and latitude. Nevertheless, the existence of an enormous
range of species itself builds the precondition for a huge potential and a variable mixture of
available taxa.
The analysis of climate data shows that soil as well as air temperatures in the centre of the
study area are clearly above 5.5° C, the postulated threshold value for tree growth.
Therefore, temperature cannot be considered to cause the lowering of the local treeline
ecotone of the Andean Depression compared to the Northern and Central Andes. Instead,
quasi-permanent East winds, high amounts of precipitation throughout the year and maybe
even extreme incidents of radiation lead to the depression of the local treeline ecotone
system. While high global radiation leads to radiation stress especially for tree seedlings
situated outside closed forest stands, strong East winds additionally constrain the
establishment of forests in the higher-located ridge areas of Páramo formations.
High precipitation leads to a shortage of nutrients in the more gently inclined ridges where
the interflow is lower compared to steeper slopes.
The results of chemical soil analysis show clearly that the three examined sites are
characterized by low pH-values as well as a lack of nutrients. Furthermore, the upper soil
layers of the Páramo areas show higher aluminium toxicity due to the type of litter
decomposed by Páramo plants, a fact hindering the settling of young trees.
Among the natural factors which prevent the growth of forests in higher areas are high
rates of radiation, an extreme wind speed, as well as enormous rainfalls. Other sites
restricted in forest growth are caused by human influence.
The high diversity of species is remarkable in the upper treeline ecotone in the centre of the
Andes Depression, a fact that can be ascribed to the lack of nutrients (strongly competitive
species are locked out, cf. soil nutrient hypothesis) on the one hand. On the other hand,
high precipitation amounts are also responsible for the lowering of the treeline. The result
is the combination of a clearly marked forest treeline depression combined with an
astonishing treeline complexity which is still an almost unknown paradox.
Richter, M.; Diertl, K.; Emck, P.; Peters, T. & Beck, E. (2009): Reasons for an outstanding plant diversity in the tropical Andes of Southern Ecuador. Landscape Online 12, 1-35.
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DOI: 10.3097
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Abstract:
Abstract:
Long-term field studies in the scope of a multidisciplinary project in southern Ecuador revealed extraordinary high species
numbers of many organismic groups. This article discusses reasons for the outstanding vascular plant diversity using a
hierarchical scale-oriented top-down approach (Grüninger 2005), from the global scale to the local microscale. The global
scale explains general (paleo-) ecological factors valid for most parts of the humid tropics, addressing various hypotheses
and theories, such as the ?greater effective evolutionary time?, constant input of ?accidentals?, the ?seasonal variability hypothesis?, the ?intermediate disturbance hypothesis?, and the impact of soil fertility. The macroscale focuses on the Andes
in northwestern South America. The tropical Andes are characterised by many taxa of restricted range which is particularly
true for the Amotape-Huancabamba region, i.e. the so called Andean Depression, which is effective as discrete phytogeographic transition as well as barrier zone. Interdigitation of northern and southern flora elements, habitat fragmentation, geological and landscape history, and a high speciation rate due to rapid genetic radiation of some taxa contribute to a high degree of diversification. The mesoscale deals with the special environmental features of the eastern mountain range, the Cordillera Real and surrounding areas in southern Ecuador. Various climatic characteristics, the orographic heterogeneity, the geologic and edaphic conditions as well as human impact are the most prominent factors augmenting plant species diversity. On microscale, prevailing regimes of disturbance and environmental stresses, the orographic basement, as well as the general role on the various mountain chains are considered. Here, micro-habitats e.g. niches for epiphytes, effects of micro-relief patterns, and successions after small-sized disturbance events are screened. Direct effects of human impact are addressed and a perspective of possible effects of climate change on plant diversity is presented.
Bendix, J.; Behling, H.; Peters, T.; Richter, M. & Beck, E. (2009): Functional biodiversity and climate change along an altitudinal gradient in a tropical mountain rainforest. In: Tscharnke, T. et al. (eds.): Tropical rainforests and agroforests under global change (Environmental Science Series ), Springer.
Bräuning, A.; von Schnakenburg, P.; Volland, F. & Peters, T. (2008): Seasonal growth dynamics and its climate forcing in a tropical mountain rain forest in southern Ecuador. TRACE - Tree Rings in Archaeology, Climatology and Ecology 6, 27-30.