Plant water resource partitioning and isotopic fractionation during transpiration in a seasonally dry tropical climate

Wispelaere, Lien De; Bodé, Samuel; Hervé‐Fernández, Pedro; Hemp, Andreas; Verschuren, Dirk; Boeckx, Pascal

doi:10.5194/bg-14-73-2017

Cited by 16 publications

(11 citation statements)

References 83 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, in recent years parts of the dry crater forest have been destroyed by fires set by alcohol distillers occupying shallow caves surrounding the lake. The crater rim and the more gently sloping outer slopes are covered by open savanna woodland ('Obstgartensteppe'; Volkens, 1897), a highly diverse plant community of Acacia (but note that African acacias are now assigned to Vachellia and Senegalia; Boatwright et al, 2014), Acalypha, Combretum, Grewia, Rhus, Lannea, Terminalia, Vepris and Ximenia trees and shrubs interspersed by grassland with dominant grasses Themeda triandra and Enteropogon macrostylus (De Wispelaere et al, 2017) complemented by Bothriochloa insculpta, Eragrostis superba, Cyperus niveus and Indigofera volkensii (A. Hemp, personal Hemp, 2006b). (b) Aerial view of Lake Chala within its steep-sided crater basin, and of the surrounding vegetation in a partly cultural landscape, viewed from the south (photo credit: Wikimedia Commons).…”

Section: Modern-day Vegetationmentioning

confidence: 99%

“…Here, Acalypha is one of the more responsive taxa in the pollen diagram: it occupies a special position in the PCA species plot (Figure 3a) and its temporal trends contribute significantly to the pollen zonation ( Figure 2). Its occurrence both in the colline forest and woodland on the outer crater slopes (De Wispelaere et al, 2017) as in the dry forest inside the crater (A. Hemp, personal observation) renders interpretation of its temporal dynamics in the pollen record anything but straightforward. The fact that the temporal trends in Acalypha broadly follow those of Euphorbia would seem to indicate that a substantial part of Acalypha pollen in our record originated from inner crater forest, and yet in the PCA Acalypha does not group together with Euphorbia or other crater forest taxa (Figure 3a).…”

Section: Long-term Vegetation Dynamics: Extra-local and Regional Vegementioning

confidence: 99%

See 1 more Smart Citation

Climate-human-landscape interaction in the eastern foothills of Mt. Kilimanjaro (equatorial East Africa) during the last two millennia

et al. 2020

Self Cite

View full text Add to dashboard Cite

The Mt. Kilimanjaro region is known for its long history of intensive agriculture, but the temporal extent of human activity and its impact on the regional ecosystem are not well known. In this study, climate-human-landscape interactions during the past ~2200 years were examined using climate and vegetation proxies extracted from the continuous and high-resolution sediment record of Lake Chala. Ancient-to-modern regional human activity is documented against a backdrop of long-term vegetation dynamics in the low-elevation savanna woodland southeast of Mt. Kilimanjaro and riparian forest within Chala crater. During prolonged dry periods (~1170–1300 CE), succulent dry crater forest expanded relative to the moist lakeshore forest. The savanna landscape surrounding Chala crater was relatively stable through time, except that savanna grasses were stimulated by higher precipitation, consistent with the fuel-limited fire regime evidenced in the charcoal record. Expansion of subalpine ericaceous vegetation and a general decline in Afromontane forest taxa on Mt. Kilimanjaro after 550 CE may reflect a lowering of its upper forest line. The earliest robust signature of human influence on regional vegetation involves an increase in ruderal (weedy) plant taxa around 1100 CE, possibly associated with the development of Chagga homegardens and associated agroforestry in the submontane forest zone. A first hint of cereal agriculture (likely sorghum) is observed around 1550 CE, followed by a more robust signature from 1780 CE onwards which likely reflects the start of lowland irrigation agriculture. From 1780 CE we also find the first undisputed appearance of maize, introduced to East Africa about a century earlier.

show abstract

Section: Modern-day Vegetationmentioning

confidence: 99%

Section: Long-term Vegetation Dynamics: Extra-local and Regional Vegementioning

confidence: 99%

Climate-human-landscape interaction in the eastern foothills of Mt. Kilimanjaro (equatorial East Africa) during the last two millennia

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…Studies on isotope ecohydrology across the tropics are emerging, and so far they have addressed: plant water uptake and partitioning (Meinzer et al, 1999;Evaristo et al, 2016;De Wispelaere et al, 2017;De Deurwaerder et al, 2018;Bodé et al, 2020;Jiménez-Rodríguez et al, 2019), soil water dynamics and mixing (Mosquera et al, 2020), and soil evaporative losses (Hasselquist et al, 2018). Most of these studies come from the dry tropics; however, research coming from mountain and wet rainforest environments, as well as highland Páramos, are particularly scarce.…”

Section: Data Gaps: Water Vapor Fog Soil and Plantsmentioning

confidence: 99%

“…Isotope ratios ( 18 O/ 16 O, 17 O/ 16 O, 2 H/ 1 H) and derived second order variables (d-excess, lc-excess, and 17 O-excess) (Dansgaard, 1964;Angert et al, 2004;Landwehr and Coplen, 2006) have been widely used to infer water origin, apparent age, and related fluxes across the soil-plant-atmosphere continuum (SPAC) (Sprenger et al, 2016;Nehemy et al, 2019;Sprenger et al, 2019). These applications are primarily concentrated in temperate environments (Hervé-Fernández et al, 2016;Volkmann et al, 2016;Brinkmann et al, 2018;Goldsmith et al, 2019); however, in the tropics, isotope ecohydrological studies are incipient (Goldsmith et al, 2012;Evaristo et al, 2016;De Wispelaere et al, 2017;De Deurwaerder et al, 2018;Hasselquist et al, 2018;Bodé et al, 2020;Mosquera et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Tracing Water Sources and Fluxes in a Dynamic Tropical Environment: From Observations to Modeling

et al. 2020

View full text Add to dashboard Cite

Tropical regions cover approximately 36% of the Earth's landmass. These regions are home to 40% of the world's population, which is projected to increase to over 50% by 2030 under a remarkable climate variability scenario often exacerbated by El Niño Southern Oscillation (ENSO) and other climate teleconnections. In the tropics, ecohydrological conditions are typically under the influence of complex land-oceanatmosphere interactions that produce a dynamic cycling of mass and energy reflected in a clear partition of water fluxes. Here, we present a review of 7 years of a concerted and continuous water stable isotope monitoring across Costa Rica, including key insights learned, main methodological advances and limitations (both in experimental designs and data analysis), potential data gaps, and future research opportunities with a humid tropical perspective. The uniqueness of the geographic location of Costa Rica within the mountainous Central America Isthmus, receiving moisture inputs from the Caribbean Sea (windward) and the Pacific Ocean (complex leeward topography), and experiencing strong ENSO events, poses a clear advantage for the use of isotopic variations to underpin key drivers in ecohydrological responses. In a sequential approach, isotopic variations are analyzed from moisture transport, rainfall generation, and groundwater/surface connectivity to Bayesian and rainfall-runoff modeling. The overarching goal of this review is to provide a robust humid tropical example with a progressive escalation from common water isotope observations to more complex modeling outputs and applications to enhance water resource management in the tropics.

show abstract

“…This will be useful to understand why certain species outperform other species under specific conditions, and which species will be particularly vulnerable to change in the climate regime. Such knowledge is specifically missing for data scarce regions like the African tropics (de Wispelaere et al, 2017; Wright et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Variability in tree water uptake determined with stable water isotopes in an African tropical montane forest

et al. 2021

View full text Add to dashboard Cite

Ecohydrological processes in tropical rainforests are insufficiently understood, and existing studies yield contradictory results. We investigated relative contributions of different soil depths to tree water uptake of 83 trees and possible species‐specific differences in a 50 × 50 m forest plot at four dates in a tropical montane forest in Kenya using stable water isotopes and the Bayesian mixing model framework MixSIAR. We found distinct individual tree differences (e.g. Drypetes gerrardii taking 75% of its water from <0.5 m, or a rather large shift in uptake patterns based on the climatic conditions, that is the fourth sampling date), but no consistent species‐specific or small‐scale spatiotemporal patterns in water uptake and depth contributions. Soil water δ18O showed a lateral variation of up to 6‰, which was accounted for by a spatial interpolation of soil water isotopes and enabled us to improve allocations of water uptake sources to individual trees. Our results show that ignoring the lateral variability of water isotope signatures in soils complicates the applicability of a mixing model in this context and might be a widespread constraint reducing the validity and comparability of mixing model results. Further research on underlying processes of water fluxes in forest ecosystems is urgently needed and we point out the need for considering large individual differences in water uptake patterns and small‐scale variability of soil water isotopic composition despite homogeneous soil characteristics.

show abstract

Plant water resource partitioning and isotopic fractionation during transpiration in a seasonally dry tropical climate

Cited by 16 publications

References 83 publications

Climate-human-landscape interaction in the eastern foothills of Mt. Kilimanjaro (equatorial East Africa) during the last two millennia

Climate-human-landscape interaction in the eastern foothills of Mt. Kilimanjaro (equatorial East Africa) during the last two millennia

Tracing Water Sources and Fluxes in a Dynamic Tropical Environment: From Observations to Modeling

Variability in tree water uptake determined with stable water isotopes in an African tropical montane forest

Contact Info

Product

Resources

About