End member and Bayesian mixing models consistently indicate near‐surface flowpath dominance in a pristine humid tropical rainforest

Christian Birkel; Alicia Correa Barahona; Clément Duvert; Sebastián Granados Bolaños; Andres Chavarría Palma; Ana Maria Durán Quesada; Ricardo Sánchez Murillo; Harald Biester

doi:10.1002/hyp.14153

End member and Bayesian mixing models consistently indicate near‐surface flowpath dominance in a pristine humid tropical rainforest

Christian Birkel^* (Corresponding Author), Alicia Correa Barahona, Clément Duvert, Sebastián Granados Bolaños, Andres Chavarría Palma, Ana Maria Durán Quesada, Ricardo Sánchez Murillo, Harald Biester

^*Corresponding author for this work

Geography & Environment

Research output: Contribution to journal › Article › peer-review

15 Citations (Scopus)

Abstract

The impacts of forest conversion on runoff generation in the tropics have received much interest, but scientific progress is still hampered by challenging fieldwork conditions and limited knowledge about runoff mechanisms. Here, we assessed the runoff generation, flow paths and water source dynamics of a pristine rainforest catchment in Costa Rica using end member mixing analysis (EMMA) and a Bayesian mixing model (MixSIAR). Geochemical tracer data collected over a 4-week field campaign were combined with tritium data used to assess potential deeper groundwater flow pathways to the perennial stream. The streamflow composition was best captured using three end-members, namely throughfall, shallow (5–15 cm) and deeper (15–50 cm) soil water. We estimated the end-member contributions to the main stream and two tributaries using the two mixing approaches and found good agreement between results obtained from EMMA and MixSIAR. The system was overwhelmingly dominated by near-surface sources, with little evidence for deeper and older groundwater as tritium-derived baseflow mean transit time was between 2.0 and 4.4 years. The shallow soil flow pathway dominated streamflow contributions in the main stream (median 39% and 49% based on EMMA and MixSIAR, respectively), followed by the deeper soil (32% and 31%) and throughfall (25% and 19%). The two tributaries had even greater shallow soil water contributions relative to the main stream (83% and 74% for tributary A and 42% and 63% for tributary B). Tributary B had no detectable deep soil water contribution, reflecting the morphology of the hillslope (steeper slopes, shallower soils and lower vegetation density compared to hillslope A). Despite the short sampling campaign and associated uncertainties, this study allowed to thoroughly assess runoff generation mechanisms in a humid tropical catchment. Our results also provide a first comparison of two increasingly used mixing models and suggest that EMMA and MixSIAR yield comparable estimates of water source partitioning in this tropical, volcanic rainforest environment.

Original language	English
Article number	e14153
Number of pages	15
Journal	Hydrological Processes
Volume	35
Issue number	4
Early online date	19 Apr 2021
DOIs	https://doi.org/10.1002/hyp.14153
Publication status	Published - 19 Apr 2021

Bibliographical note

Research funding
International Atomic Energy Agency. Grant Number: IAEA CRP22009
UCREA. Grant Number: B8276
Universidad de Costa Rica. Grant Numbers: B8709, ED-3319

ACKNOWLEDGEMENTS
The authors would like to thank the helpful staff at the ReBAMB station for support during the extensive fieldwork campaign and the major sampling effort by Katrin Schulz and Julia Balzer. A.C. acknowledges a UCR-funded postdoctoral research fellowship. C.B. would like to acknowledge UCR support for the projects B8709, ED-3319 and UCREA-B8276 and the IAEA CRP22009. C.D. thanks Dr. Dioni Cendón and ANSTO for streamwater tritium analyses and the Australian Research Council for a postdoctoral fellowship. R.S.M. thanks the support of the GNIP-IAEA for monthly and event-based tritium analysis of rainfall.
The data that support the findings of this research are available from the corresponding author upon request.

Keywords

Costa Rica
EMMA
humid tropic
MixSIAR
runoff generation
tracers
water source contribution

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Birkel, C., Correa Barahona, A., Duvert, C., Granados Bolaños, S., Chavarría Palma, A., Durán Quesada, A. M., Sánchez Murillo, R., & Biester, H. (2021). End member and Bayesian mixing models consistently indicate near‐surface flowpath dominance in a pristine humid tropical rainforest. Hydrological Processes, 35(4), Article e14153. https://doi.org/10.1002/hyp.14153

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abstract = "The impacts of forest conversion on runoff generation in the tropics have received much interest, but scientific progress is still hampered by challenging fieldwork conditions and limited knowledge about runoff mechanisms. Here, we assessed the runoff generation, flow paths and water source dynamics of a pristine rainforest catchment in Costa Rica using end member mixing analysis (EMMA) and a Bayesian mixing model (MixSIAR). Geochemical tracer data collected over a 4-week field campaign were combined with tritium data used to assess potential deeper groundwater flow pathways to the perennial stream. The streamflow composition was best captured using three end-members, namely throughfall, shallow (5–15 cm) and deeper (15–50 cm) soil water. We estimated the end-member contributions to the main stream and two tributaries using the two mixing approaches and found good agreement between results obtained from EMMA and MixSIAR. The system was overwhelmingly dominated by near-surface sources, with little evidence for deeper and older groundwater as tritium-derived baseflow mean transit time was between 2.0 and 4.4 years. The shallow soil flow pathway dominated streamflow contributions in the main stream (median 39% and 49% based on EMMA and MixSIAR, respectively), followed by the deeper soil (32% and 31%) and throughfall (25% and 19%). The two tributaries had even greater shallow soil water contributions relative to the main stream (83% and 74% for tributary A and 42% and 63% for tributary B). Tributary B had no detectable deep soil water contribution, reflecting the morphology of the hillslope (steeper slopes, shallower soils and lower vegetation density compared to hillslope A). Despite the short sampling campaign and associated uncertainties, this study allowed to thoroughly assess runoff generation mechanisms in a humid tropical catchment. Our results also provide a first comparison of two increasingly used mixing models and suggest that EMMA and MixSIAR yield comparable estimates of water source partitioning in this tropical, volcanic rainforest environment.",

keywords = "Costa Rica, EMMA, humid tropic, MixSIAR, runoff generation, tracers, water source contribution",

author = "Christian Birkel and {Correa Barahona}, Alicia and Cl{\'e}ment Duvert and {Granados Bola{\~n}os}, Sebasti{\'a}n and {Chavarr{\'i}a Palma}, Andres and {Dur{\'a}n Quesada}, {Ana Maria} and {S{\'a}nchez Murillo}, Ricardo and Harald Biester",

note = "Research funding International Atomic Energy Agency. Grant Number: IAEA CRP22009 UCREA. Grant Number: B8276 Universidad de Costa Rica. Grant Numbers: B8709, ED-3319 ACKNOWLEDGEMENTS The authors would like to thank the helpful staff at the ReBAMB station for support during the extensive fieldwork campaign and the major sampling effort by Katrin Schulz and Julia Balzer. A.C. acknowledges a UCR-funded postdoctoral research fellowship. C.B. would like to acknowledge UCR support for the projects B8709, ED-3319 and UCREA-B8276 and the IAEA CRP22009. C.D. thanks Dr. Dioni Cend{\'o}n and ANSTO for streamwater tritium analyses and the Australian Research Council for a postdoctoral fellowship. R.S.M. thanks the support of the GNIP-IAEA for monthly and event-based tritium analysis of rainfall. The data that support the findings of this research are available from the corresponding author upon request.",

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doi = "10.1002/hyp.14153",

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T1 - End member and Bayesian mixing models consistently indicate near‐surface flowpath dominance in a pristine humid tropical rainforest

AU - Birkel, Christian

AU - Correa Barahona, Alicia

AU - Duvert, Clément

AU - Granados Bolaños, Sebastián

AU - Chavarría Palma, Andres

AU - Durán Quesada, Ana Maria

AU - Sánchez Murillo, Ricardo

AU - Biester, Harald

N1 - Research funding International Atomic Energy Agency. Grant Number: IAEA CRP22009 UCREA. Grant Number: B8276 Universidad de Costa Rica. Grant Numbers: B8709, ED-3319 ACKNOWLEDGEMENTS The authors would like to thank the helpful staff at the ReBAMB station for support during the extensive fieldwork campaign and the major sampling effort by Katrin Schulz and Julia Balzer. A.C. acknowledges a UCR-funded postdoctoral research fellowship. C.B. would like to acknowledge UCR support for the projects B8709, ED-3319 and UCREA-B8276 and the IAEA CRP22009. C.D. thanks Dr. Dioni Cendón and ANSTO for streamwater tritium analyses and the Australian Research Council for a postdoctoral fellowship. R.S.M. thanks the support of the GNIP-IAEA for monthly and event-based tritium analysis of rainfall. The data that support the findings of this research are available from the corresponding author upon request.

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Y1 - 2021/4/19

N2 - The impacts of forest conversion on runoff generation in the tropics have received much interest, but scientific progress is still hampered by challenging fieldwork conditions and limited knowledge about runoff mechanisms. Here, we assessed the runoff generation, flow paths and water source dynamics of a pristine rainforest catchment in Costa Rica using end member mixing analysis (EMMA) and a Bayesian mixing model (MixSIAR). Geochemical tracer data collected over a 4-week field campaign were combined with tritium data used to assess potential deeper groundwater flow pathways to the perennial stream. The streamflow composition was best captured using three end-members, namely throughfall, shallow (5–15 cm) and deeper (15–50 cm) soil water. We estimated the end-member contributions to the main stream and two tributaries using the two mixing approaches and found good agreement between results obtained from EMMA and MixSIAR. The system was overwhelmingly dominated by near-surface sources, with little evidence for deeper and older groundwater as tritium-derived baseflow mean transit time was between 2.0 and 4.4 years. The shallow soil flow pathway dominated streamflow contributions in the main stream (median 39% and 49% based on EMMA and MixSIAR, respectively), followed by the deeper soil (32% and 31%) and throughfall (25% and 19%). The two tributaries had even greater shallow soil water contributions relative to the main stream (83% and 74% for tributary A and 42% and 63% for tributary B). Tributary B had no detectable deep soil water contribution, reflecting the morphology of the hillslope (steeper slopes, shallower soils and lower vegetation density compared to hillslope A). Despite the short sampling campaign and associated uncertainties, this study allowed to thoroughly assess runoff generation mechanisms in a humid tropical catchment. Our results also provide a first comparison of two increasingly used mixing models and suggest that EMMA and MixSIAR yield comparable estimates of water source partitioning in this tropical, volcanic rainforest environment.

AB - The impacts of forest conversion on runoff generation in the tropics have received much interest, but scientific progress is still hampered by challenging fieldwork conditions and limited knowledge about runoff mechanisms. Here, we assessed the runoff generation, flow paths and water source dynamics of a pristine rainforest catchment in Costa Rica using end member mixing analysis (EMMA) and a Bayesian mixing model (MixSIAR). Geochemical tracer data collected over a 4-week field campaign were combined with tritium data used to assess potential deeper groundwater flow pathways to the perennial stream. The streamflow composition was best captured using three end-members, namely throughfall, shallow (5–15 cm) and deeper (15–50 cm) soil water. We estimated the end-member contributions to the main stream and two tributaries using the two mixing approaches and found good agreement between results obtained from EMMA and MixSIAR. The system was overwhelmingly dominated by near-surface sources, with little evidence for deeper and older groundwater as tritium-derived baseflow mean transit time was between 2.0 and 4.4 years. The shallow soil flow pathway dominated streamflow contributions in the main stream (median 39% and 49% based on EMMA and MixSIAR, respectively), followed by the deeper soil (32% and 31%) and throughfall (25% and 19%). The two tributaries had even greater shallow soil water contributions relative to the main stream (83% and 74% for tributary A and 42% and 63% for tributary B). Tributary B had no detectable deep soil water contribution, reflecting the morphology of the hillslope (steeper slopes, shallower soils and lower vegetation density compared to hillslope A). Despite the short sampling campaign and associated uncertainties, this study allowed to thoroughly assess runoff generation mechanisms in a humid tropical catchment. Our results also provide a first comparison of two increasingly used mixing models and suggest that EMMA and MixSIAR yield comparable estimates of water source partitioning in this tropical, volcanic rainforest environment.

KW - Costa Rica

KW - EMMA

KW - humid tropic

KW - MixSIAR

KW - runoff generation

KW - tracers

KW - water source contribution

U2 - 10.1002/hyp.14153

DO - 10.1002/hyp.14153

M3 - Article

SN - 0885-6087

VL - 35

JO - Hydrological Processes

JF - Hydrological Processes

IS - 4

M1 - e14153

ER -

End member and Bayesian mixing models consistently indicate near‐surface flowpath dominance in a pristine humid tropical rainforest

Abstract

Bibliographical note

Keywords

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