Carlos Valarezo scite author profile

Summary In tropical montane forests nutrients released from the organic layers of the soil can supply a large part of the vegetation's requirements. We have examined concentrations, storage, and turnover times of nutrients in the organic layer and the fluxes of nutrients by the fall of small litter (leaves, seeds, flowers, small twigs, and plant debris that passed an opening of 0.3 m × 0.3 m) in such a forest in Ecuador. The times taken for litter to turn over were estimated by relating nutrient storage in the organic layer to rate of litterfall and by incubating samples in the laboratory. The organic layer had a thickness of 2–43 cm, a mass of 30–713 t ha−1, and a nutrient storage of 0.87–21 t N, 0.03–0.70 t P, 0.12–2.5 t K, 0.09–3.2 t Ca, and 0.07–1.0 t Mg ha−1. The pH (in H2O) ranged between 3.1 and 7.4 and was correlated with the concentrations of Ca and Mg (r= 0.83 and 0.84, respectively). The quantity of small litter (8.5–9.7 t year−1) and mean concentrations of nutrients in litter (19–22 g N, 0.9–1.6 g P, 6.1–9.1 g K, 12–18 g Ca, and 3.5–5.8 g Mg kg−1) were larger than in many other tropical montane forests. The mean turnover times of elements in the organic layer increased in the order, Mg (7.0 years) < Ca (7.9) < K (8.5) < P (11) < N (14) < S (15) when calculated as the quotient of storage in the organic layer to flux by litterfall; they were < 12 years for N, P, and S in the incubation experiment. Under optimum conditions in the laboratory, the mineralization of S was just as large as the S deposition by litterfall. In weakly acid soils Mn and Zn and in strongly acid soils Ca added in a nutrient solution were immobilized during incubation. Thus, lack of S, Mn, Zn, and Ca might limit plant growth on some soils.

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Tracing water paths through small catchments under a tropical montane rain forest in south Ecuador by an oxygen isotope approach

Goller

Wilcke²,

Leng

et al. 2005

Journal of Hydrology

107

105

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Rainfall interception in a lower montane forest in Ecuador: effects of canopy properties

et al. 2005

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Abstract:Rainfall interception in forests is influenced by properties of the canopy that tend to vary over small distances. Our objectives were: (i) to determine the variables needed to model the interception loss of the canopy of a lower montane forest in south Ecuador, i.e. the storage capacity of the leaves S and of the trunks and branches S t , and the fractions of direct throughfall p and stemflow p t ; (ii) to assess the influence of canopy density and epiphyte coverage of trees on the interception of rainfall and subsequent evaporation losses.The study site was located on the eastern slope of the eastern cordillera in the south Ecuadorian Andes at 1900-2000 m above sea level. We monitored incident rainfall, throughfall, and stemflow between April 1998 and April 2001. In 2001, the leaf area index (LAI), inferred from light transmission, and epiphyte coverage was determined.The mean annual incident rainfall at three gauging stations ranged between 2319 and 2561 mm. The mean annual interception loss at five study transects in the forest varied between 591 and 1321 mm, i.e. between 25 and 52% of the incident rainfall. Mean S was estimated at 1Ð91 mm for relatively dry weeks with a regression model and at 2Ð46 mm for all weeks with the analytical Gash model; the respective estimates of mean S t were 0Ð04 mm and 0Ð09 mm, of mean p were 0Ð42 and 0Ð63, and of mean p t were 0Ð003 and 0Ð012. The LAI ranged from 5Ð19 to 9Ð32. Epiphytes, mostly bryophytes, covered up to 80% of the trunk and branch surfaces. The fraction of direct throughfall p and the LAI correlated significantly with interception loss (Pearson's correlation coefficient r D 0Ð77 and 0Ð35 respectively, n D 40). Bryophyte and lichen coverage tended to decrease S t and vascular epiphytes tended to increase it, although there was no significant correlation between epiphyte coverage and interception loss. Our results demonstrate that canopy density influences interception loss but only explains part of the total variation in interception loss.

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Water flow paths in soil control element exports in an Andean tropical montane forest

Boy

Valarezo

Wilcke

2008

European J Soil Science

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We tested the hypothesis that concentrations of chemical constituents in stream water can be explained by the depth of water flow through soil. Therefore, we measured the concentrations of total organic carbon (TOC), NO 3 -N, NH 4 -N, dissolved organic nitrogen (DON), P, S, K, Ca, Mg, Na, Al and Mn in rainfall, throughfall, stemflow, litter leachate, mineral soil solution and stream water of three 8-13 ha catchments on steep slopes (1900-2200 m above sea level) of the south Ecuadorian Andes, from April 1998 to April 2003. Peak C (14-22 mg litre À1 ), N (0.6-0.9 mg litre À1 ), K (0.5-0.7 mg litre À1 ), Ca (0.6-1.0 mg litre À1 ), Mg (0.3-0.5 mg litre À1 ), Al (110-390 mg litre À1 ) and Mn (3.9-8.4 mg litre À1 ) concentrations in stream water were associated with lateral flow (fast near-surface flow in saturated topsoil) while the greatest P (0.1-0.3 mg litre À1 ), S (0.3-0.7 mg litre À1 ) and Na (3.0-6.0 mg litre À1 ) concentrations occurred during low baseflow conditions. All elements had greater concentrations in the organic layer than in the mineral soil, but only C, N, K, Ca, Mg, Al and Mn were flushed out during lateral-flow conditions. Phosphorus, S and Na, in contrast, were mainly released by weathering and (re-)oxidation of sulphides in the subsoil. Baseflow accounted for 32% to 61% of P export, while > 50% of S was exported during intermediate flow conditions (i.e. lateral flow at the depth of several tens of cm in the mineral soil). Near-surface water flow through C-and nutrient-rich topsoil during rainstorms was the major export pathway for C, N, Al and Mn (contributing > 50% to the total export of these elements). Near-surface flow also accounted for one-third of total base metal export. Our results demonstrate that near-surface flow related to storm events markedly affects the cycling of many nutrients in steep tropical montane forests.

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Water budgets of three small catchments under montane forest in Ecuador: experimental and modelling approach

Fleischbein

Wilcke

Valarezo

et al. 2006

Hydrological Processes

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Abstract:The water budget of forested catchments controls the local water supply and influences the regional climate. To assess the anthropogenic impact on the water cycle, we constructed a water budget for three ¾10 ha catchments under lower montane forest on the east-facing slope of the Andes in south Ecuador at 1900-2150 m elevation. We used field hydrological measurements and modelled surface flows with TOPMODEL, a semi-distributed catchment model. We measured incident precipitation, throughfall, stemflow, and surface flow between May 1998 and April 2002 in hourly to weekly resolution, and determined all variables needed to parameterise TOPMODEL. On average, of the four monitored years and three catchments, incident precipitation was 2504 š SD 123 mm, throughfall 1473 š 197 mm, and stemflow 25 š 2 mm yr 1 . Fog water input was negligible. Mean annual interception loss in the forest was 1006 š 270 mm, and mean annual surface flow, calculated with TOPMODEL in an hourly resolution was 1039 š 48 mm. The resulting mean annual evapotranspiration was 1466 š 161 mm of which 32% (D471 š 162 mm) was transpiration if evaporation from the soil was neglected. Our study catchments show a high evapotranspiration attributable to the strong solar insolation near the equator, the small impact of fog, the generally low intensity of incident precipitation and additional wind-driven advective energy input.

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Carlos Valarezo

Nutrient storage and turnover in organic layers under tropical montane rain forest in Ecuador

Tracing water paths through small catchments under a tropical montane rain forest in south Ecuador by an oxygen isotope approach

Rainfall interception in a lower montane forest in Ecuador: effects of canopy properties

Water flow paths in soil control element exports in an Andean tropical montane forest

Water budgets of three small catchments under montane forest in Ecuador: experimental and modelling approach

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