Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate

Rebecca Ostertag; Carla Restrepo; James W. Dalling; Patrick H. Martin; Iveren Abiem; Shin ichiro Aiba; Esteban Alvarez-Dávila; Roxana Aragón; Michelle Ataroff; Hazel Chapman; Augusta Y. Cueva-Agila; Belen Fadrique; Romina D. Fernández; Grizelle González; Sybil G. Gotsch; Achim Häger; Jürgen Homeier; Carlos Iñiguez-Armijos; Luis Daniel Llambí; Georgianne W. Moore; Rikke Reese Næsborg; Laura Nohemy Poma López; Patrícia Vieira Pompeu; Jennifer R. Powell; Jorge Andrés Ramírez Correa; Klara Scharnagl; Conrado Tobón; Cameron B. Williams

doi:10.1111/btp.13044

Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate

Rebecca Ostertag^*, Carla Restrepo, James W. Dalling, Patrick H. Martin, Iveren Abiem, Shin ichiro Aiba, Esteban Alvarez-Dávila, Roxana Aragón, Michelle Ataroff, Hazel Chapman, Augusta Y. Cueva-Agila, Belen Fadrique, Romina D. Fernández, Grizelle González, Sybil G. Gotsch, Achim Häger, Jürgen Homeier, Carlos Iñiguez-Armijos, Luis Daniel Llambí, Georgianne W. MooreRikke Reese Næsborg, Laura Nohemy Poma López, Patrícia Vieira Pompeu, Jennifer R. Powell, Jorge Andrés Ramírez Correa, Klara Scharnagl, Conrado Tobón, Cameron B. Williams

^*Corresponding author for this work

PUCE Ibarra

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

11 Scopus citations

Abstract

The “hierarchy of factors” hypothesis states that decomposition rates are controlled primarily by climatic, followed by biological and soil variables. Tropical montane forests (TMF) are globally important ecosystems, yet there have been limited efforts to provide a biome-scale characterization of litter decomposition. We designed a common litter decomposition experiment replicated in 23 tropical montane sites across the Americas, Asia, and Africa and combined these results with a previous study of 23 sites in tropical lowland forests (TLF). Specifically, we investigated (1) spatial heterogeneity in decomposition, (2) the relative importance of biological factors that affect leaf and wood decomposition in TMF, and (3) the role of climate in determining leaf litter decomposition rates within and across the TMF and TLF biomes. Litterbags of two mesh sizes containing Laurus nobilis leaves or birchwood popsicle sticks were spatially dispersed and incubated in TMF sites, for 3 and 7 months on the soil surface and at 10–15 cm depth. The within-site replication demonstrated spatial variability in mass loss. Within TMF, litter type was the predominant biological factor influencing decomposition (leaves > wood), with mesh and burial effects playing a minor role. When comparing across TMF and TLF, climate was the predominant control over decomposition, but the Yasso07 global model (based on mean annual temperature and precipitation) only modestly predicted decomposition rate. Differences in controlling factors between biomes suggest that TMF, with their high rates of carbon storage, must be explicitly considered when developing theory and models to elucidate carbon cycling rates in the tropics. Abstract in Spanish is available with online material.

Original language	English
Pages (from-to)	309-326
Number of pages	18
Journal	Biotropica
Volume	54
Issue number	2
DOIs	https://doi.org/10.1111/btp.13044
State	Published - Mar 2022

Bibliographical note

Publisher Copyright:
© 2021 The Association for Tropical Biology and Conservation

Funding

This work was supported by National Science Foundation grant from the Division of Environmental Biology (DEB)‐1146446 and the NSF‐sponsored research coordination network ( http://ducloudnet.wpengine.com ). We thank William K. Cornwell for help with litterfitter. At individual sites, we would like to acknowledge the following: CEM: We thank Federico Valverde for granting permission to work at Cerro de la Muerte Field Station. The School for Field Studies Costa Rica provided logistical support for data collection at the Cerro de la Muerte site. Emily Blau and Anne Häger assisted with field and laboratory work. Meteorological data were provided by the Instituto Meteorologico de Costa Rica. CLB: We thank Cloudbridge Nature Reserve for their support of this project as well as Tim Carlson and Janina Harms for their assistance with fieldwork. EXT and VIR: We thank The Nature Conservancy (TNC) and the São Paulo Research Foundation—FAPESP (grant 2015/50682‐6) for the fieldwork support. LAU: We thank Mikkel Gantzler and Oliver Andersen for field sampling support, and Christa Nicholas, Kaikea Blakemore, and Rebecca Carpenter for assembling the litter bags, and Tabetha Block for permitting help. MON: We thank to the Monteverde Cloud Forest Reserve for research permission and to the National Science Foundation for financial support (Gotsch IOS Award #1556289). MUC: We thank INPARQUES (Venezuela) for facilitating access to the plots and J.E. Torres and M. Fernandez for assistance during fieldwork. NGE: We thank the Nigerian Montane Forest Project field assistants. HON and QUE: We thank Evidelio García and Juliana Pardo for field assistance. SAN: We thank the Deutsche Forschungsgemeinschaft (DFG) for the fieldwork support (grant Ho 3296/4‐2). SLM: work in the SLM was possible through grant NSF‐DEB 1556878 to CR. CloudNet This work was supported by National Science Foundation grant from the Division of Environmental Biology (DEB)-1146446 and the NSF-sponsored research coordination network CloudNet (http://ducloudnet.wpengine.com). We thank William K. Cornwell for help with litterfitter. At individual sites, we would like to acknowledge the following: CEM: We thank Federico Valverde for granting permission to work at Cerro de la Muerte Field Station. The School for Field Studies Costa Rica provided logistical support for data collection at the Cerro de la Muerte site. Emily Blau and Anne H?ger assisted with field and laboratory work. Meteorological data were provided by the Instituto Meteorologico de Costa Rica. CLB: We thank Cloudbridge Nature Reserve for their support of this project as well as Tim Carlson and Janina Harms for their assistance with fieldwork. EXT and VIR: We thank The Nature Conservancy (TNC) and the S?o Paulo Research Foundation?FAPESP (grant 2015/50682-6) for the fieldwork support. LAU: We thank Mikkel Gantzler and Oliver Andersen for field sampling support, and Christa Nicholas, Kaikea Blakemore, and Rebecca Carpenter for assembling the litter bags, and Tabetha Block for permitting help. MON: We thank to the Monteverde?Cloud?Forest Reserve for research permission and to the National Science Foundation?for financial support?(Gotsch IOS Award #1556289). MUC: We thank INPARQUES (Venezuela) for facilitating access to the plots and J.E. Torres and M. Fernandez for assistance during fieldwork. NGE: We thank the Nigerian Montane Forest Project field assistants. HON and QUE: We thank Evidelio Garc?a and Juliana Pardo for field assistance. SAN: We thank the Deutsche Forschungsgemeinschaft (DFG) for the fieldwork support (grant Ho 3296/4-2). SLM: work in the SLM was possible through grant NSF-DEB 1556878 to CR.

Funders	Funder number
INPARQUES
Instituto Meteorologico de Costa Rica
NSF-sponsored
S?o Paulo Research Foundation?FAPESP
National Science Foundation
Division of Environmental Biology	1146446, DEB)-1146446
Nature Conservancy
Deutsche Forschungsgemeinschaft	Ho 3296/4‐2
Fundação de Amparo à Pesquisa do Estado de São Paulo	2015/50682‐6, 1556289

Keywords

Climate
common litter experiment
decomposition coefficient
leaves
litter arthropods
soil depth
wood

Access to Document

10.1111/btp.13044

Cite this

Ostertag, R., Restrepo, C., Dalling, J. W., Martin, P. H., Abiem, I., Aiba, S. I., Alvarez-Dávila, E., Aragón, R., Ataroff, M., Chapman, H., Cueva-Agila, A. Y., Fadrique, B., Fernández, R. D., González, G., Gotsch, S. G., Häger, A., Homeier, J., Iñiguez-Armijos, C., Llambí, L. D., ... Williams, C. B. (2022). Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate. Biotropica, 54(2), 309-326. https://doi.org/10.1111/btp.13044

@article{d417ab074b6d4894a7783e6b19b4c317,

title = "Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate",

abstract = "The “hierarchy of factors” hypothesis states that decomposition rates are controlled primarily by climatic, followed by biological and soil variables. Tropical montane forests (TMF) are globally important ecosystems, yet there have been limited efforts to provide a biome-scale characterization of litter decomposition. We designed a common litter decomposition experiment replicated in 23 tropical montane sites across the Americas, Asia, and Africa and combined these results with a previous study of 23 sites in tropical lowland forests (TLF). Specifically, we investigated (1) spatial heterogeneity in decomposition, (2) the relative importance of biological factors that affect leaf and wood decomposition in TMF, and (3) the role of climate in determining leaf litter decomposition rates within and across the TMF and TLF biomes. Litterbags of two mesh sizes containing Laurus nobilis leaves or birchwood popsicle sticks were spatially dispersed and incubated in TMF sites, for 3 and 7 months on the soil surface and at 10–15 cm depth. The within-site replication demonstrated spatial variability in mass loss. Within TMF, litter type was the predominant biological factor influencing decomposition (leaves > wood), with mesh and burial effects playing a minor role. When comparing across TMF and TLF, climate was the predominant control over decomposition, but the Yasso07 global model (based on mean annual temperature and precipitation) only modestly predicted decomposition rate. Differences in controlling factors between biomes suggest that TMF, with their high rates of carbon storage, must be explicitly considered when developing theory and models to elucidate carbon cycling rates in the tropics. Abstract in Spanish is available with online material.",

keywords = "Climate, common litter experiment, decomposition coefficient, leaves, litter arthropods, soil depth, wood",

author = "Rebecca Ostertag and Carla Restrepo and Dalling, {James W.} and Martin, {Patrick H.} and Iveren Abiem and Aiba, {Shin ichiro} and Esteban Alvarez-D{\'a}vila and Roxana Arag{\'o}n and Michelle Ataroff and Hazel Chapman and Cueva-Agila, {Augusta Y.} and Belen Fadrique and Fern{\'a}ndez, {Romina D.} and Grizelle Gonz{\'a}lez and Gotsch, {Sybil G.} and Achim H{\"a}ger and J{\"u}rgen Homeier and Carlos I{\~n}iguez-Armijos and Llamb{\'i}, {Luis Daniel} and Moore, {Georgianne W.} and N{\ae}sborg, {Rikke Reese} and {Poma L{\'o}pez}, {Laura Nohemy} and Pompeu, {Patr{\'i}cia Vieira} and Powell, {Jennifer R.} and {Ram{\'i}rez Correa}, {Jorge Andr{\'e}s} and Klara Scharnagl and Conrado Tob{\'o}n and Williams, {Cameron B.}",

note = "Publisher Copyright: {\textcopyright} 2021 The Association for Tropical Biology and Conservation",

year = "2022",

month = mar,

doi = "10.1111/btp.13044",

language = "English",

volume = "54",

pages = "309--326",

journal = "Biotropica",

issn = "0006-3606",

publisher = "Wiley-Blackwell",

number = "2",

}

Ostertag, R, Restrepo, C, Dalling, JW, Martin, PH, Abiem, I, Aiba, SI, Alvarez-Dávila, E, Aragón, R, Ataroff, M, Chapman, H, Cueva-Agila, AY, Fadrique, B, Fernández, RD, González, G, Gotsch, SG, Häger, A, Homeier, J, Iñiguez-Armijos, C, Llambí, LD, Moore, GW, Næsborg, RR, Poma López, LN, Pompeu, PV, Powell, JR, Ramírez Correa, JA, Scharnagl, K, Tobón, C & Williams, CB 2022, 'Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate', Biotropica, vol. 54, no. 2, pp. 309-326. https://doi.org/10.1111/btp.13044

TY - JOUR

T1 - Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate

AU - Ostertag, Rebecca

AU - Restrepo, Carla

AU - Dalling, James W.

AU - Martin, Patrick H.

AU - Abiem, Iveren

AU - Aiba, Shin ichiro

AU - Alvarez-Dávila, Esteban

AU - Aragón, Roxana

AU - Ataroff, Michelle

AU - Chapman, Hazel

AU - Cueva-Agila, Augusta Y.

AU - Fadrique, Belen

AU - Fernández, Romina D.

AU - González, Grizelle

AU - Gotsch, Sybil G.

AU - Häger, Achim

AU - Homeier, Jürgen

AU - Iñiguez-Armijos, Carlos

AU - Llambí, Luis Daniel

AU - Moore, Georgianne W.

AU - Næsborg, Rikke Reese

AU - Poma López, Laura Nohemy

AU - Pompeu, Patrícia Vieira

AU - Powell, Jennifer R.

AU - Ramírez Correa, Jorge Andrés

AU - Scharnagl, Klara

AU - Tobón, Conrado

AU - Williams, Cameron B.

PY - 2022/3

Y1 - 2022/3

N2 - The “hierarchy of factors” hypothesis states that decomposition rates are controlled primarily by climatic, followed by biological and soil variables. Tropical montane forests (TMF) are globally important ecosystems, yet there have been limited efforts to provide a biome-scale characterization of litter decomposition. We designed a common litter decomposition experiment replicated in 23 tropical montane sites across the Americas, Asia, and Africa and combined these results with a previous study of 23 sites in tropical lowland forests (TLF). Specifically, we investigated (1) spatial heterogeneity in decomposition, (2) the relative importance of biological factors that affect leaf and wood decomposition in TMF, and (3) the role of climate in determining leaf litter decomposition rates within and across the TMF and TLF biomes. Litterbags of two mesh sizes containing Laurus nobilis leaves or birchwood popsicle sticks were spatially dispersed and incubated in TMF sites, for 3 and 7 months on the soil surface and at 10–15 cm depth. The within-site replication demonstrated spatial variability in mass loss. Within TMF, litter type was the predominant biological factor influencing decomposition (leaves > wood), with mesh and burial effects playing a minor role. When comparing across TMF and TLF, climate was the predominant control over decomposition, but the Yasso07 global model (based on mean annual temperature and precipitation) only modestly predicted decomposition rate. Differences in controlling factors between biomes suggest that TMF, with their high rates of carbon storage, must be explicitly considered when developing theory and models to elucidate carbon cycling rates in the tropics. Abstract in Spanish is available with online material.

AB - The “hierarchy of factors” hypothesis states that decomposition rates are controlled primarily by climatic, followed by biological and soil variables. Tropical montane forests (TMF) are globally important ecosystems, yet there have been limited efforts to provide a biome-scale characterization of litter decomposition. We designed a common litter decomposition experiment replicated in 23 tropical montane sites across the Americas, Asia, and Africa and combined these results with a previous study of 23 sites in tropical lowland forests (TLF). Specifically, we investigated (1) spatial heterogeneity in decomposition, (2) the relative importance of biological factors that affect leaf and wood decomposition in TMF, and (3) the role of climate in determining leaf litter decomposition rates within and across the TMF and TLF biomes. Litterbags of two mesh sizes containing Laurus nobilis leaves or birchwood popsicle sticks were spatially dispersed and incubated in TMF sites, for 3 and 7 months on the soil surface and at 10–15 cm depth. The within-site replication demonstrated spatial variability in mass loss. Within TMF, litter type was the predominant biological factor influencing decomposition (leaves > wood), with mesh and burial effects playing a minor role. When comparing across TMF and TLF, climate was the predominant control over decomposition, but the Yasso07 global model (based on mean annual temperature and precipitation) only modestly predicted decomposition rate. Differences in controlling factors between biomes suggest that TMF, with their high rates of carbon storage, must be explicitly considered when developing theory and models to elucidate carbon cycling rates in the tropics. Abstract in Spanish is available with online material.

KW - Climate

KW - common litter experiment

KW - decomposition coefficient

KW - leaves

KW - litter arthropods

KW - soil depth

KW - wood

UR - http://www.scopus.com/inward/record.url?scp=85121380022&partnerID=8YFLogxK

U2 - 10.1111/btp.13044

DO - 10.1111/btp.13044

M3 - Article

AN - SCOPUS:85121380022

SN - 0006-3606

VL - 54

SP - 309

EP - 326

JO - Biotropica

JF - Biotropica

IS - 2

ER -

Litter decomposition rates across tropical montane and lowland forests are controlled foremost by climate

Abstract

Bibliographical note

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Cite this