Water table depth modulates productivity and biomass across Amazonian forests

Thaiane R. Sousa; Juliana Schietti; IO Ribeiro; Thaise Emílio; Rafael Herrera Fernández; Steege H ter; Carolina V. Castilho; A Esquivel‐Muelbert; Timothy Baker; A Pontes‐Lopes; CVJ Silva; JM Silveira; Géraldine Derroire; Wendeson Castro; AM Mendoza; Ademir Ruschel; Adriana Prieto; Adriano José Nogueira Lima; Agustín Rudas; A Araujo‐Murakami; Alexander Parada Gutierrez; Ana Andrade; Anand Roopsind; Angelo Gilberto Manzatto; Fiore A Di; A Torres‐Lezama; Aurélie Dourdain; B Marimon; BH Marimon; Benoit Burban; Ulft B van; Bruno Herault; Carlos Quesada; C Mendoza; Clement Stahl; Damien Bonal; David Galbraith; David Neill; Oliveira EA de; Eduardo Hase; E Jimenez‐Rojas; Emilio Vilanova; Eric Arets; Erika Berenguer; E Alvarez‐Davila; Coronado EN Honorio; Everton Almeida; Fernanda Coelho; Fernando Cornejo Valverde; Fernando Elias; Foster Brown; Frans Bongers; Freddy Ramirez Arevalo; G Lopez‐Gonzalez; der Heijden G van; C. GA Aymard; Gerardo Flores Llampazo; Guido Pardo; H Ramírez‐Angulo; Amaral IL do; ICG Vieira; I Huamantupa‐Chuquimaco; James A. Comiskey; James Singh; Javier Silva Espejo; Aguila‐Pasquel J del; Joeri Alexander Zwerts; Joey Talbot; John Terborgh; J Ferreira; Jorcely G. Barroso; Jos Barlow; JL Camargo; Juliana Stropp; Julie Peacock; Julio Serrano; Karina Melgaço; LV Ferreira; Lilian Blanc; Lourens Poorter; Sophie Fauset

doi:10.1111/geb.13531

Water table depth modulates productivity and biomass across Amazonian forests

Thaiane R. Sousa^*
, Juliana Schietti
, IO Ribeiro
, Thaise Emílio
, Rafael Herrera Fernández
, Steege H ter
, Carolina V. Castilho
, A Esquivel‐Muelbert
, Timothy Baker
, A Pontes‐Lopes
, CVJ Silva
, JM Silveira
, Géraldine Derroire
, Wendeson Castro
, AM Mendoza
, Ademir Ruschel
, Adriana Prieto
, Adriano José Nogueira Lima
, Agustín Rudas
, A Araujo‐Murakami

Alexander Parada Gutierrez, Ana Andrade, Anand Roopsind, Angelo Gilberto Manzatto, Fiore A Di, A Torres‐Lezama, Aurélie Dourdain, B Marimon, BH Marimon, Benoit Burban, Ulft B van, Bruno Herault, Carlos Quesada, C Mendoza, Clement Stahl, Damien Bonal, David Galbraith, David Neill, Oliveira EA de, Eduardo Hase, E Jimenez‐Rojas, Emilio Vilanova, Eric Arets, Erika Berenguer, E Alvarez‐Davila, Coronado EN Honorio, Everton Almeida, Fernanda Coelho, Fernando Cornejo Valverde, Fernando Elias, Foster Brown, Frans Bongers, Freddy Ramirez Arevalo, G Lopez‐Gonzalez, der Heijden G van, C. GA Aymard, Gerardo Flores Llampazo, Guido Pardo, H Ramírez‐Angulo, Amaral IL do, ICG Vieira, I Huamantupa‐Chuquimaco, James A. Comiskey, James Singh, Javier Silva Espejo, Aguila‐Pasquel J del, Joeri Alexander Zwerts, Joey Talbot, John Terborgh, J Ferreira, Jorcely G. Barroso, Jos Barlow, JL Camargo, Juliana Stropp, Julie Peacock, Julio Serrano, Karina Melgaço, LV Ferreira, Lilian Blanc, Lourens Poorter, Sophie Fauset

^*Corresponding author for this work

School of Geography, Earth and Environmental Sciences

Instituto Nacional de Pesquisas da Amazônia
Universidade Federal do Amazonas
Universidade Estadual de Campinas
Instituto Venezolano de Investigaciones Científicas
Empresa Brasileira de Pesquisa Agropecuária
University of Leeds
Université des Antilles
Programa Mudança Climática e Restauração da Paisagem Florestal
Universidade Federal do Acre
Universidad Nacional de Colombia
Universidad Autónoma Gabriel René Moreno
Iwokrama International Centre for Rainforest Conservation and Development
Fundação Universidade Federal de Rondônia
Écologie des Forêts de Guyane (UMR-CNRS 8172)
Université de Lorraine
Universidad Estatal Amazonica
University of California at Berkeley
Wageningen University & Research
Lancaster University
University of Oxford
Universidade Federal do Oeste do Pará
Universidade de Brasília
Proyecto Castaña
Universidade Federal do Pará
Woods Hole Research Center
Instituto de Investigaciones de la Amazonía Peruana
Instituto de Investigaciones Forestales de la Amazonía
Universidad Autonoma del Beni
United States Geological Survey
Guyana Forestry Commission
Universidad Nacional Amazónica de Madre de Dios
Utrecht University
Duke University
Museo Nacional de Ciencias Naturales-CSIC
Centre de Coopération Internationale en Recherche Agronomique pour le Developpement (CIRAD)

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Abstract

Aim: Water availability is the major driver of tropical forest structure and dynamics. Most research has focused on the impacts of climatic water availability, whereas remarkably little is known about the influence of water table depth and excess soil water on forest processes. Nevertheless, given that plants take up water from the soil, the impacts of climatic water supply on plants are likely to be modulated by soil water conditions. Location: Lowland Amazonian forests. Time period: 1971–2019. Methods: We used 344 long-term inventory plots distributed across Amazonia to analyse the effects of long-term climatic and edaphic water supply on forest functioning. We modelled forest structure and dynamics as a function of climatic, soil-water and edaphic properties. Results: Water supplied by both precipitation and groundwater affects forest structure and dynamics, but in different ways. Forests with a shallow water table (depth <5 m) had 18% less above-ground woody productivity and 23% less biomass stock than forests with a deep water table. Forests in drier climates (maximum cumulative water deficit < −160 mm) had 21% less productivity and 24% less biomass than those in wetter climates. Productivity was affected by the interaction between climatic water deficit and water table depth. On average, in drier climates the forests with a shallow water table had lower productivity than those with a deep water table, with this difference decreasing within wet climates, where lower productivity was confined to a very shallow water table. Main conclusions: We show that the two extremes of water availability (excess and deficit) both reduce productivity in Amazon upland (terra-firme) forests. Biomass and productivity across Amazonia respond not simply to regional climate, but rather to its interaction with water table conditions, exhibiting high local differentiation. Our study disentangles the relative contribution of those factors, helping to improve understanding of the functioning of tropical ecosystems and how they are likely to respond to climate change.

Original language	English
Pages (from-to)	1571-1588
Journal	Global Ecology and Biogeography
Volume	31
Issue number	8
Early online date	22 May 2022
DOIs	https://doi.org/10.1111/geb.13531
Publication status	Published - Aug 2022

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10.1111/geb.13531

Sousa et al GEB WTD Amazon paper update3

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Sousa, T. R., Schietti, J., Ribeiro, IO., Emílio, T., Fernández, R. H., ter, S. H., Castilho, C. V., Esquivel‐Muelbert, A., Baker, T., Pontes‐Lopes, A., Silva, CVJ., Silveira, JM., Derroire, G., Castro, W., Mendoza, AM., Ruschel, A., Prieto, A., Lima, A. J. N., Rudas, A., ... Fauset, S. (2022). Water table depth modulates productivity and biomass across Amazonian forests. Global Ecology and Biogeography, 31(8), 1571-1588. https://doi.org/10.1111/geb.13531

@article{a917b834bc4a4ddaaa2e2bba223f8d28,

title = "Water table depth modulates productivity and biomass across Amazonian forests",

abstract = " Aim: Water availability is the major driver of tropical forest structure and dynamics. Most research has focused on the impacts of climatic water availability, whereas remarkably little is known about the influence of water table depth and excess soil water on forest processes. Nevertheless, given that plants take up water from the soil, the impacts of climatic water supply on plants are likely to be modulated by soil water conditions. Location: Lowland Amazonian forests. Time period: 1971–2019. Methods: We used 344 long-term inventory plots distributed across Amazonia to analyse the effects of long-term climatic and edaphic water supply on forest functioning. We modelled forest structure and dynamics as a function of climatic, soil-water and edaphic properties. Results: Water supplied by both precipitation and groundwater affects forest structure and dynamics, but in different ways. Forests with a shallow water table (depth <5 m) had 18\% less above-ground woody productivity and 23\% less biomass stock than forests with a deep water table. Forests in drier climates (maximum cumulative water deficit < −160 mm) had 21\% less productivity and 24\% less biomass than those in wetter climates. Productivity was affected by the interaction between climatic water deficit and water table depth. On average, in drier climates the forests with a shallow water table had lower productivity than those with a deep water table, with this difference decreasing within wet climates, where lower productivity was confined to a very shallow water table. Main conclusions: We show that the two extremes of water availability (excess and deficit) both reduce productivity in Amazon upland (terra-firme) forests. Biomass and productivity across Amazonia respond not simply to regional climate, but rather to its interaction with water table conditions, exhibiting high local differentiation. Our study disentangles the relative contribution of those factors, helping to improve understanding of the functioning of tropical ecosystems and how they are likely to respond to climate change.",

author = "Sousa, \{Thaiane R.\} and Juliana Schietti and IO Ribeiro and Thaise Em{\'i}lio and Fern{\'a}ndez, \{Rafael Herrera\} and ter, \{Steege H\} and Castilho, \{Carolina V.\} and A Esquivel‐Muelbert and Timothy Baker and A Pontes‐Lopes and CVJ Silva and JM Silveira and G{\'e}raldine Derroire and Wendeson Castro and AM Mendoza and Ademir Ruschel and Adriana Prieto and Lima, \{Adriano Jos{\'e} Nogueira\} and Agust{\'i}n Rudas and A Araujo‐Murakami and Gutierrez, \{Alexander Parada\} and Ana Andrade and Anand Roopsind and Manzatto, \{Angelo Gilberto\} and Di, \{Fiore A\} and A Torres‐Lezama and Aur{\'e}lie Dourdain and B Marimon and BH Marimon and Benoit Burban and van, \{Ulft B\} and Bruno Herault and Carlos Quesada and C Mendoza and Clement Stahl and Damien Bonal and David Galbraith and David Neill and de, \{Oliveira EA\} and Eduardo Hase and E Jimenez‐Rojas and Emilio Vilanova and Eric Arets and Erika Berenguer and E Alvarez‐Davila and Honorio, \{Coronado EN\} and Everton Almeida and Fernanda Coelho and Valverde, \{Fernando Cornejo\} and Fernando Elias and Foster Brown and Frans Bongers and Arevalo, \{Freddy Ramirez\} and G Lopez‐Gonzalez and van, \{der Heijden G\} and Aymard, \{C. GA\} and Llampazo, \{Gerardo Flores\} and Guido Pardo and H Ram{\'i}rez‐Angulo and do, \{Amaral IL\} and ICG Vieira and I Huamantupa‐Chuquimaco and Comiskey, \{James A.\} and James Singh and Espejo, \{Javier Silva\} and del, \{Aguila‐Pasquel J\} and Zwerts, \{Joeri Alexander\} and Joey Talbot and John Terborgh and J Ferreira and Barroso, \{Jorcely G.\} and Jos Barlow and JL Camargo and Juliana Stropp and Julie Peacock and Julio Serrano and Karina Melga{\c c}o and LV Ferreira and Lilian Blanc and Lourens Poorter and Sophie Fauset",

year = "2022",

month = aug,

doi = "10.1111/geb.13531",

language = "English",

volume = "31",

pages = "1571--1588",

journal = "Global Ecology and Biogeography",

issn = "1466-822X",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "8",

}

Sousa, TR, Schietti, J, Ribeiro, IO, Emílio, T, Fernández, RH, ter, SH, Castilho, CV, Esquivel‐Muelbert, A, Baker, T, Pontes‐Lopes, A, Silva, CVJ, Silveira, JM, Derroire, G, Castro, W, Mendoza, AM, Ruschel, A, Prieto, A, Lima, AJN, Rudas, A, Araujo‐Murakami, A, Gutierrez, AP, Andrade, A, Roopsind, A, Manzatto, AG, Di, FA, Torres‐Lezama, A, Dourdain, A, Marimon, B, Marimon, BH, Burban, B, van, UB, Herault, B, Quesada, C, Mendoza, C, Stahl, C, Bonal, D, Galbraith, D, Neill, D, de, OEA, Hase, E, Jimenez‐Rojas, E, Vilanova, E, Arets, E, Berenguer, E, Alvarez‐Davila, E, Honorio, CEN, Almeida, E, Coelho, F, Valverde, FC, Elias, F, Brown, F, Bongers, F, Arevalo, FR, Lopez‐Gonzalez, G, van, DHG, Aymard, CGA, Llampazo, GF, Pardo, G, Ramírez‐Angulo, H, do, AIL, Vieira, ICG, Huamantupa‐Chuquimaco, I, Comiskey, JA, Singh, J, Espejo, JS, del, APJ, Zwerts, JA, Talbot, J, Terborgh, J, Ferreira, J, Barroso, JG, Barlow, J, Camargo, JL, Stropp, J, Peacock, J, Serrano, J, Melgaço, K, Ferreira, LV, Blanc, L, Poorter, L & Fauset, S 2022, 'Water table depth modulates productivity and biomass across Amazonian forests', Global Ecology and Biogeography, vol. 31, no. 8, pp. 1571-1588. https://doi.org/10.1111/geb.13531

TY - JOUR

T1 - Water table depth modulates productivity and biomass across Amazonian forests

AU - Sousa, Thaiane R.

AU - Schietti, Juliana

AU - Ribeiro, IO

AU - Emílio, Thaise

AU - Fernández, Rafael Herrera

AU - ter, Steege H

AU - Castilho, Carolina V.

AU - Esquivel‐Muelbert, A

AU - Baker, Timothy

AU - Pontes‐Lopes, A

AU - Silva, CVJ

AU - Silveira, JM

AU - Derroire, Géraldine

AU - Castro, Wendeson

AU - Mendoza, AM

AU - Ruschel, Ademir

AU - Prieto, Adriana

AU - Lima, Adriano José Nogueira

AU - Rudas, Agustín

AU - Araujo‐Murakami, A

AU - Gutierrez, Alexander Parada

AU - Andrade, Ana

AU - Roopsind, Anand

AU - Manzatto, Angelo Gilberto

AU - Di, Fiore A

AU - Torres‐Lezama, A

AU - Dourdain, Aurélie

AU - Marimon, B

AU - Marimon, BH

AU - Burban, Benoit

AU - van, Ulft B

AU - Herault, Bruno

AU - Quesada, Carlos

AU - Mendoza, C

AU - Stahl, Clement

AU - Bonal, Damien

AU - Galbraith, David

AU - Neill, David

AU - de, Oliveira EA

AU - Hase, Eduardo

AU - Jimenez‐Rojas, E

AU - Vilanova, Emilio

AU - Arets, Eric

AU - Berenguer, Erika

AU - Alvarez‐Davila, E

AU - Honorio, Coronado EN

AU - Almeida, Everton

AU - Coelho, Fernanda

AU - Valverde, Fernando Cornejo

AU - Elias, Fernando

AU - Brown, Foster

AU - Bongers, Frans

AU - Arevalo, Freddy Ramirez

AU - Lopez‐Gonzalez, G

AU - van, der Heijden G

AU - Aymard, C. GA

AU - Llampazo, Gerardo Flores

AU - Pardo, Guido

AU - Ramírez‐Angulo, H

AU - do, Amaral IL

AU - Vieira, ICG

AU - Huamantupa‐Chuquimaco, I

AU - Comiskey, James A.

AU - Singh, James

AU - Espejo, Javier Silva

AU - del, Aguila‐Pasquel J

AU - Zwerts, Joeri Alexander

AU - Talbot, Joey

AU - Terborgh, John

AU - Ferreira, J

AU - Barroso, Jorcely G.

AU - Barlow, Jos

AU - Camargo, JL

AU - Stropp, Juliana

AU - Peacock, Julie

AU - Serrano, Julio

AU - Melgaço, Karina

AU - Ferreira, LV

AU - Blanc, Lilian

AU - Poorter, Lourens

AU - Fauset, Sophie

PY - 2022/8

Y1 - 2022/8

N2 - Aim: Water availability is the major driver of tropical forest structure and dynamics. Most research has focused on the impacts of climatic water availability, whereas remarkably little is known about the influence of water table depth and excess soil water on forest processes. Nevertheless, given that plants take up water from the soil, the impacts of climatic water supply on plants are likely to be modulated by soil water conditions. Location: Lowland Amazonian forests. Time period: 1971–2019. Methods: We used 344 long-term inventory plots distributed across Amazonia to analyse the effects of long-term climatic and edaphic water supply on forest functioning. We modelled forest structure and dynamics as a function of climatic, soil-water and edaphic properties. Results: Water supplied by both precipitation and groundwater affects forest structure and dynamics, but in different ways. Forests with a shallow water table (depth <5 m) had 18% less above-ground woody productivity and 23% less biomass stock than forests with a deep water table. Forests in drier climates (maximum cumulative water deficit < −160 mm) had 21% less productivity and 24% less biomass than those in wetter climates. Productivity was affected by the interaction between climatic water deficit and water table depth. On average, in drier climates the forests with a shallow water table had lower productivity than those with a deep water table, with this difference decreasing within wet climates, where lower productivity was confined to a very shallow water table. Main conclusions: We show that the two extremes of water availability (excess and deficit) both reduce productivity in Amazon upland (terra-firme) forests. Biomass and productivity across Amazonia respond not simply to regional climate, but rather to its interaction with water table conditions, exhibiting high local differentiation. Our study disentangles the relative contribution of those factors, helping to improve understanding of the functioning of tropical ecosystems and how they are likely to respond to climate change.

AB - Aim: Water availability is the major driver of tropical forest structure and dynamics. Most research has focused on the impacts of climatic water availability, whereas remarkably little is known about the influence of water table depth and excess soil water on forest processes. Nevertheless, given that plants take up water from the soil, the impacts of climatic water supply on plants are likely to be modulated by soil water conditions. Location: Lowland Amazonian forests. Time period: 1971–2019. Methods: We used 344 long-term inventory plots distributed across Amazonia to analyse the effects of long-term climatic and edaphic water supply on forest functioning. We modelled forest structure and dynamics as a function of climatic, soil-water and edaphic properties. Results: Water supplied by both precipitation and groundwater affects forest structure and dynamics, but in different ways. Forests with a shallow water table (depth <5 m) had 18% less above-ground woody productivity and 23% less biomass stock than forests with a deep water table. Forests in drier climates (maximum cumulative water deficit < −160 mm) had 21% less productivity and 24% less biomass than those in wetter climates. Productivity was affected by the interaction between climatic water deficit and water table depth. On average, in drier climates the forests with a shallow water table had lower productivity than those with a deep water table, with this difference decreasing within wet climates, where lower productivity was confined to a very shallow water table. Main conclusions: We show that the two extremes of water availability (excess and deficit) both reduce productivity in Amazon upland (terra-firme) forests. Biomass and productivity across Amazonia respond not simply to regional climate, but rather to its interaction with water table conditions, exhibiting high local differentiation. Our study disentangles the relative contribution of those factors, helping to improve understanding of the functioning of tropical ecosystems and how they are likely to respond to climate change.

UR - https://pearl.plymouth.ac.uk/gees-research/1339/

U2 - 10.1111/geb.13531

DO - 10.1111/geb.13531

M3 - Article

SN - 1466-822X

VL - 31

SP - 1571

EP - 1588

JO - Global Ecology and Biogeography

JF - Global Ecology and Biogeography

IS - 8

ER -

Water table depth modulates productivity and biomass across Amazonian forests

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