The pervasive and multifaceted influence of biocrusts on water in the world's drylands

David J. Eldridge; Sasha Reed; Samantha K. Travers; Matthew A. Bowker; Fernando T. Maestre; Jingyi Ding; Caroline Havrilla; Emilio Rodriguez-Caballero; Nichole Barger; Bettina Weber; Anita Antoninka; Jayne Belnap; Bala Chaudhary; Akasha Faist; Scott Ferrenberg; Elisabeth Huber-Sannwald; Oumarou Malam Issa; Yunge Zhao

doi:10.1111/gcb.15232

The pervasive and multifaceted influence of biocrusts on water in the world's drylands

David J. Eldridge
, Sasha Reed
, Samantha K. Travers
, Matthew A. Bowker
, Fernando T. Maestre
, Jingyi Ding
, Caroline Havrilla
, Emilio Rodriguez-Caballero
, Nichole Barger
, Bettina Weber
, Anita Antoninka
, Jayne Belnap
, Bala Chaudhary
, Akasha Faist
, Scott Ferrenberg
, Elisabeth Huber-Sannwald
, Oumarou Malam Issa
, Yunge Zhao

W. A. Franke College of Forestry and Conservation

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

238 Scopus citations

Abstract

The capture and use of water are critically important in drylands, which collectively constitute Earth's largest biome. Drylands will likely experience lower and more unreliable rainfall as climatic conditions change over the next century. Dryland soils support a rich community of microphytic organisms (biocrusts), which are critically important because they regulate the delivery and retention of water. Yet despite their hydrological significance, a global synthesis of their effects on hydrology is lacking. We synthesized 2,997 observations from 109 publications to explore how biocrusts affected five hydrological processes (times to ponding and runoff, early [sorptivity] and final [infiltration] stages of water flow into soil, and the rate or volume of runoff) and two hydrological outcomes (moisture storage, sediment production). We found that increasing biocrust cover reduced the time for water to pond on the surface (−40%) and commence runoff (−33%), and reduced infiltration (−34%) and sediment production (−68%). Greater biocrust cover had no significant effect on sorptivity or runoff rate/amount, but increased moisture storage (+14%). Infiltration declined most (−56%) at fine scales, and moisture storage was greatest (+36%) at large scales. Effects of biocrust type (cyanobacteria, lichen, moss, mixed), soil texture (sand, loam, clay), and climatic zone (arid, semiarid, dry subhumid) were nuanced. Our synthesis provides novel insights into the magnitude, processes, and contexts of biocrust effects in drylands. This information is critical to improve our capacity to manage dwindling dryland water supplies as Earth becomes hotter and drier.

Original language	English
Pages (from-to)	6003-6014
Number of pages	12
Journal	Global Change Biology
Volume	26
Issue number	10
DOIs	https://doi.org/10.1111/gcb.15232
State	Published - Oct 1 2020

Funding

This work was conducted as part of the Powell Working Group “Completing the dryland puzzle: creating a predictive framework for biological soil crust function and response to climate change” supported by the John Wesley Powell Center for Analysis and Synthesis, funded by the US Geological Survey. Shinichi Nakagawa and Max Mallen‐Cooper guided us through the R code for the meta‐analyses. J.B. and S.R. were funded by USGS Ecosystems and Land Use Change Mission Areas, by the US Department of Energy (DESC‐0008168), and by the Strategic Environmental Research and Development Program (RC18‐1322). J.D. is supported by grants from the Holsworth Wildlife Research Endowment & The Ecological Society of Australia, and a scholarship from China Scholarship Council (No. 201706040073). B.C. is supported by grants from the National Science Foundation (award DEB‐1844531) and DePaul University. M.A.B. is supported by a grant from the National Science Foundation (award DEB‐1638966). B.W. was supported by the Max Planck Society and a Paul Crutzen Nobel Laureate Fellowship. E.H.‐S. was supported by CONACYT grant 251388 B. F.T.M. was supported by the European Research Council (ERC grant agreement 647038 [BIODESERT]) and Generalitat Valenciana (CIDEGENT/2018/041). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the US Government. This work was conducted as part of the Powell Working Group ?Completing the dryland puzzle: creating a predictive framework for biological soil crust function and response to climate change? supported by the John Wesley Powell Center for Analysis and Synthesis, funded by the US Geological Survey. Shinichi Nakagawa and Max Mallen-Cooper guided us through the R code for the meta-analyses. J.B. and S.R. were funded by USGS Ecosystems and Land Use Change Mission Areas, by the US Department of Energy (DESC-0008168), and by the Strategic Environmental Research and Development Program (RC18-1322). J.D. is supported by grants from the Holsworth Wildlife Research Endowment & The Ecological Society of Australia, and a scholarship from China Scholarship Council (No. 201706040073). B.C. is supported by grants from the National Science Foundation (award DEB-1844531) and DePaul University. M.A.B. is supported by a grant from the National Science Foundation (award DEB-1638966). B.W. was supported by the Max Planck Society and a Paul Crutzen Nobel Laureate Fellowship. E.H.-S. was supported by CONACYT grant 251388 B. F.T.M. was supported by the European Research Council (ERC grant agreement 647038 [BIODESERT]) and Generalitat Valenciana (CIDEGENT/2018/041). Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the US Government.

Funders	Funder number
DESC-0008168
DEB‐1844531
DESC‐0008168
DePaul University	DEB‐1638966
647038
RC18‐1322
Consejo Nacional de Ciencia y Tecnologia Mexico	251388
CIDEGENT/2018/041
201706040073

Keywords

biological soil crust
bryophyte
cryptogam
cyanobacteria
hydrological cycle
infiltration
lichen
sediment production
soil hydrology
soil moisture

Access to Document

10.1111/gcb.15232

Cite this

Eldridge, D. J., Reed, S., Travers, S. K., Bowker, M. A., Maestre, F. T., Ding, J., Havrilla, C., Rodriguez-Caballero, E., Barger, N., Weber, B., Antoninka, A., Belnap, J., Chaudhary, B., Faist, A., Ferrenberg, S., Huber-Sannwald, E., Malam Issa, O., & Zhao, Y. (2020). The pervasive and multifaceted influence of biocrusts on water in the world's drylands. Global Change Biology, 26(10), 6003-6014. https://doi.org/10.1111/gcb.15232

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title = "The pervasive and multifaceted influence of biocrusts on water in the world's drylands",

abstract = "The capture and use of water are critically important in drylands, which collectively constitute Earth's largest biome. Drylands will likely experience lower and more unreliable rainfall as climatic conditions change over the next century. Dryland soils support a rich community of microphytic organisms (biocrusts), which are critically important because they regulate the delivery and retention of water. Yet despite their hydrological significance, a global synthesis of their effects on hydrology is lacking. We synthesized 2,997 observations from 109 publications to explore how biocrusts affected five hydrological processes (times to ponding and runoff, early [sorptivity] and final [infiltration] stages of water flow into soil, and the rate or volume of runoff) and two hydrological outcomes (moisture storage, sediment production). We found that increasing biocrust cover reduced the time for water to pond on the surface (−40\%) and commence runoff (−33\%), and reduced infiltration (−34\%) and sediment production (−68\%). Greater biocrust cover had no significant effect on sorptivity or runoff rate/amount, but increased moisture storage (+14\%). Infiltration declined most (−56\%) at fine scales, and moisture storage was greatest (+36\%) at large scales. Effects of biocrust type (cyanobacteria, lichen, moss, mixed), soil texture (sand, loam, clay), and climatic zone (arid, semiarid, dry subhumid) were nuanced. Our synthesis provides novel insights into the magnitude, processes, and contexts of biocrust effects in drylands. This information is critical to improve our capacity to manage dwindling dryland water supplies as Earth becomes hotter and drier.",

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author = "Eldridge, \{David J.\} and Sasha Reed and Travers, \{Samantha K.\} and Bowker, \{Matthew A.\} and Maestre, \{Fernando T.\} and Jingyi Ding and Caroline Havrilla and Emilio Rodriguez-Caballero and Nichole Barger and Bettina Weber and Anita Antoninka and Jayne Belnap and Bala Chaudhary and Akasha Faist and Scott Ferrenberg and Elisabeth Huber-Sannwald and \{Malam Issa\}, Oumarou and Yunge Zhao",

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Eldridge, DJ, Reed, S, Travers, SK, Bowker, MA, Maestre, FT, Ding, J, Havrilla, C, Rodriguez-Caballero, E, Barger, N, Weber, B, Antoninka, A, Belnap, J, Chaudhary, B, Faist, A , Ferrenberg, S, Huber-Sannwald, E, Malam Issa, O & Zhao, Y 2020, 'The pervasive and multifaceted influence of biocrusts on water in the world's drylands', Global Change Biology, vol. 26, no. 10, pp. 6003-6014. https://doi.org/10.1111/gcb.15232

TY - JOUR

T1 - The pervasive and multifaceted influence of biocrusts on water in the world's drylands

AU - Eldridge, David J.

AU - Reed, Sasha

AU - Travers, Samantha K.

AU - Bowker, Matthew A.

AU - Maestre, Fernando T.

AU - Ding, Jingyi

AU - Havrilla, Caroline

AU - Rodriguez-Caballero, Emilio

AU - Barger, Nichole

AU - Weber, Bettina

AU - Antoninka, Anita

AU - Belnap, Jayne

AU - Chaudhary, Bala

AU - Faist, Akasha

AU - Ferrenberg, Scott

AU - Huber-Sannwald, Elisabeth

AU - Malam Issa, Oumarou

AU - Zhao, Yunge

PY - 2020/10/1

Y1 - 2020/10/1

N2 - The capture and use of water are critically important in drylands, which collectively constitute Earth's largest biome. Drylands will likely experience lower and more unreliable rainfall as climatic conditions change over the next century. Dryland soils support a rich community of microphytic organisms (biocrusts), which are critically important because they regulate the delivery and retention of water. Yet despite their hydrological significance, a global synthesis of their effects on hydrology is lacking. We synthesized 2,997 observations from 109 publications to explore how biocrusts affected five hydrological processes (times to ponding and runoff, early [sorptivity] and final [infiltration] stages of water flow into soil, and the rate or volume of runoff) and two hydrological outcomes (moisture storage, sediment production). We found that increasing biocrust cover reduced the time for water to pond on the surface (−40%) and commence runoff (−33%), and reduced infiltration (−34%) and sediment production (−68%). Greater biocrust cover had no significant effect on sorptivity or runoff rate/amount, but increased moisture storage (+14%). Infiltration declined most (−56%) at fine scales, and moisture storage was greatest (+36%) at large scales. Effects of biocrust type (cyanobacteria, lichen, moss, mixed), soil texture (sand, loam, clay), and climatic zone (arid, semiarid, dry subhumid) were nuanced. Our synthesis provides novel insights into the magnitude, processes, and contexts of biocrust effects in drylands. This information is critical to improve our capacity to manage dwindling dryland water supplies as Earth becomes hotter and drier.

AB - The capture and use of water are critically important in drylands, which collectively constitute Earth's largest biome. Drylands will likely experience lower and more unreliable rainfall as climatic conditions change over the next century. Dryland soils support a rich community of microphytic organisms (biocrusts), which are critically important because they regulate the delivery and retention of water. Yet despite their hydrological significance, a global synthesis of their effects on hydrology is lacking. We synthesized 2,997 observations from 109 publications to explore how biocrusts affected five hydrological processes (times to ponding and runoff, early [sorptivity] and final [infiltration] stages of water flow into soil, and the rate or volume of runoff) and two hydrological outcomes (moisture storage, sediment production). We found that increasing biocrust cover reduced the time for water to pond on the surface (−40%) and commence runoff (−33%), and reduced infiltration (−34%) and sediment production (−68%). Greater biocrust cover had no significant effect on sorptivity or runoff rate/amount, but increased moisture storage (+14%). Infiltration declined most (−56%) at fine scales, and moisture storage was greatest (+36%) at large scales. Effects of biocrust type (cyanobacteria, lichen, moss, mixed), soil texture (sand, loam, clay), and climatic zone (arid, semiarid, dry subhumid) were nuanced. Our synthesis provides novel insights into the magnitude, processes, and contexts of biocrust effects in drylands. This information is critical to improve our capacity to manage dwindling dryland water supplies as Earth becomes hotter and drier.

KW - biological soil crust

KW - bryophyte

KW - cryptogam

KW - cyanobacteria

KW - hydrological cycle

KW - infiltration

KW - lichen

KW - sediment production

KW - soil hydrology

KW - soil moisture

UR - https://www.scopus.com/pages/publications/85088790999

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DO - 10.1111/gcb.15232

M3 - Article

C2 - 32729653

AN - SCOPUS:85088790999

SN - 1354-1013

VL - 26

SP - 6003

EP - 6014

JO - Global Change Biology

JF - Global Change Biology

IS - 10

ER -

The pervasive and multifaceted influence of biocrusts on water in the world's drylands

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