Modelling rainfall interception by a lowland tropical rain forest in northeastern Puerto Rico

Schellekens, Jaap; Scatena, F. N.; Bruijnzeel, L. A.; Wickel, A. J.

doi:10.1016/s0022-1694(99)00157-2

Cited by 157 publications

(186 citation statements)

References 39 publications

(86 reference statements)

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“…energy limited; Calder, 1998), and therefore the expected increases in ET a due to forest regrowth are not evident in the Q record. However, the interception evaporation component of ET a can be well in excess of PET, particularly on mountainous maritime islands (Schellekens et al, 1999;Roberts et al, 2005;Holwerda et al, 2006Holwerda et al, , 2012McJannet et al, 2007;Giambelluca et al, 2009). Moreover, an insignificant correlation was obtained between forest cover change and mean Q during the dry season (January-March; Q dry ), when PET is not expected to be a limiting factor (Fig.…”

Section: Potential Explanations For the Lack Of Relationshipsmentioning

confidence: 97%

The impact of forest regeneration on streamflow in 12 mesoscale humid tropical catchments

Beck

Bruijnzeel

Dijk

et al. 2013

Hydrol. Earth Syst. Sci.

105

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Abstract. Although regenerating forests make up an increasingly large portion of humid tropical landscapes, little is known of their water use and effects on streamflow (Q). Since the 1950s the island of Puerto Rico has experienced widespread abandonment of pastures and agricultural lands, followed by forest regeneration. This paper examines the possible impacts of these secondary forests on several Q characteristics for 12 mesoscale catchments (23-346 km 2 ; mean precipitation 1720-3422 mm yr −1 ) with long (33-51 yr) and simultaneous records for Q, precipitation (P ), potential evaporation (PET), and land cover. A simple spatially-lumped, conceptual rainfall-runoff model that uses daily P and PET time series as inputs (HBV-light) was used to simulate Q for each catchment. Annual time series of observed and simulated values of four Q characteristics were calculated. A least-squares trend was fitted through annual time series of the residual difference between observed and simulated time series of each Q characteristic. From this the total cumulative change (Â) was calculated, representing the change in each Q characteristic after controlling for climate variability and water storage carry-over effects between years. Negative values ofÂ were found for most catchments and Q characteristics, suggesting enhanced actual evaporation overall following forest regeneration. However, correlations between changes in urban or forest area and values ofÂ were insignificant (p ≥ 0.389) for all Q characteristics. This suggests there is no convincing evidence that changes in the chosen Q characteristics in these Puerto Rican catchments can be ascribed to changes in urban or forest area. The present results are in line with previous studies of mesoand macro-scale (sub-)tropical catchments, which generally found no significant change in Q that can be attributed to changes in forest cover. Possible explanations for the lack of a clear signal may include errors in the land cover, climate, Q, and/or catchment boundary data; changes in forest area occurring mainly in the less rainy lowlands; and heterogeneity in catchment response. Different results were obtained for different catchments, and using a smaller subset of catchments could have led to very different conclusions. This highlights the importance of including multiple catchments in land-cover impact analysis at the mesoscale.

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Section: Potential Explanations For the Lack Of Relationshipsmentioning

confidence: 97%

The impact of forest regeneration on streamflow in 12 mesoscale humid tropical catchments

Beck

Bruijnzeel

Dijk

et al. 2013

Hydrol. Earth Syst. Sci.

105

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“…d and z 0 were estimated as 0.75 and 0.1, respectively, of the average stand height (Rutter et al, 1971(Rutter et al, , 1975. Evaporation rate (E) for the saturated canopy of a sparse forest can be estimated as E p when C≥S, or as E=E p ·C/S, when C<S (C is the actual canopy storage and S is canopy storage capacity) (Teklehaimonot and Jarvis, 1991;Domingo et al, 1998;Schellekens, et al, 1999). Rainfall intensity, R, is calculated for all hours when the rainfall exceeds the threshold, 0.5 mm (Gash et al, 1995).…”

Section: Evaporation Ratementioning

confidence: 99%

Modelling and measurement of two-layer-canopy interception losses in a subtropical evergreen forest of central-south China

Zhang

Zeng

Jiang

et al. 2006

Hydrol. Earth Syst. Sci.

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Abstract.The original Gash analytical model and the sparse Gash's model were combined to simulate rainfall interception losses from the top-and sub-canopy layers in Shaoshan evergreen forest located in central-south China in 2003. The total estimated interception loss from the two canopy layers was 334.1 mm with an overestimation of 39.8 mm or 13.5% of the total measured interception (294.3 mm). The simulated interception losses of the top-and sub-canopy suggested that the simulated interception losses in the stages of "during storms" and "after storms" were in good agreement with the published ones. Both the original Gash model and the sparse model overestimated the interception losses, but the sparse model gave more accurate estimates than the original Gash model.

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“…Based on the few reports available, the characteristics of tropical rain-events are thought to regulate the rate of wet-canopy evaporation (Lloyd, 1990;Asdak et al, 1998;Schellekens et al, 1999;Chappell et al, 2001), transpiration supression (Szarzynski and Anuf, 2001), shallow water-table fluctuations (Bidin et al, 1993), and runoff behaviour (Robinson and Sivapalan, 1997;Bonell et al, 2004). Many studies have also attributed the temporal variation in tropical geomorphic activity to rain-event characteristics, particularly those of large events Morgan, 2004).…”

Section: Introductionmentioning

confidence: 99%

Characteristics of rain events at an inland locality in northeastern Borneo, Malaysia

Bidin

Chappell

2006

Hydrol. Process.

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Abstract:Understanding the intensity and duration of tropical rain events is critical to modelling the rate and timing of wetcanopy evaporation, the suppression of transpiration, the generation of infiltration-excess overland flow and hence to erosion, and to river responsiveness. Despite this central role, few studies have addressed the characteristics of equatorial rainstorms. This study analyses rainfall data for a 5 km 2 region largely comprising of the 4 km 2 Sapat Kalisun Experimental Catchment in the interior of northeastern Borneo at sampling frequencies from 1 min 1 to 1 day1 . The work clearly shows that most rainfall within this inland, forested area is received during regular short-duration events (<15 min) that have a relatively low intensity (i.e. less than two 0Ð2 mm rain-gauge tips in almost all 5 min periods). The rainfall appears localized, with significant losses in intergauge correlations being observable in minutes in the case of the typical mid-afternoon, convective events. This suggests that a dense rain-gauge network, sampled at a high temporal frequency, is required for accurate distributed rainfall-runoff modelling of such small catchments. Observed rain-event intensity is much less than the measured infiltration capacities, and thus supports the tenet of the dominance of quick subsurface responses in controlling river behaviour in this small equatorial catchment.

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Modelling rainfall interception by a lowland tropical rain forest in northeastern Puerto Rico

Cited by 157 publications

References 39 publications

The impact of forest regeneration on streamflow in 12 mesoscale humid tropical catchments

The impact of forest regeneration on streamflow in 12 mesoscale humid tropical catchments

Modelling and measurement of two-layer-canopy interception losses in a subtropical evergreen forest of central-south China

Characteristics of rain events at an inland locality in northeastern Borneo, Malaysia

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