Identifying areas at risk of drought-induced tree mortality across South-Eastern Australia

Martin G. De Kauwe; Belinda E. Medlyn; Anna M. Ukkola; Mengyuan Mu; Manon E.B. Sabot; Andrew J. Pitman; Patrick Meir; Lucas A. Cernusak; Sami W. Rifai; Brendan Choat; David T. Tissue; Chris J. Blackman; Ximeng Li; Michael Roderick; Peter R. Briggs

doi:10.1111/gcb.15215

Identifying areas at risk of drought-induced tree mortality across South-Eastern Australia

Martin G. De Kauwe^*, Belinda E. Medlyn, Anna M. Ukkola, Mengyuan Mu, Manon E.B. Sabot, Andrew J. Pitman, Patrick Meir, Lucas A. Cernusak, Sami W. Rifai, Brendan Choat, David T. Tissue, Chris J. Blackman, Ximeng Li, Michael Roderick, Peter R. Briggs

^*Corresponding author for this work

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

89 Citations (Scopus)

Abstract

South-East Australia has recently been subjected to two of the worst droughts in the historical record (Millennium Drought, 2000–2009 and Big Dry, 2017–2019). Unfortunately, a lack of forest monitoring has made it difficult to determine whether widespread tree mortality has resulted from these droughts. Anecdotal observations suggest the Big Dry may have led to more significant tree mortality than the Millennium drought. Critically, to be able to robustly project future expected climate change effects on Australian vegetation, we need to assess the vulnerability of Australian trees to drought. Here we implemented a model of plant hydraulics into the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model. We parameterized the drought response behaviour of five broad vegetation types, based on a common garden dry-down experiment with species originating across a rainfall gradient (188–1,125 mm/year) across South-East Australia. The new hydraulics model significantly improved (~35%–45% reduction in root mean square error) CABLE’s previous predictions of latent heat fluxes during periods of water stress at two eddy covariance sites in Australia. Landscape-scale predictions of the greatest percentage loss of hydraulic conductivity (PLC) of about 40%–60%, were broadly consistent with satellite estimates of regions of the greatest change in both droughts. In neither drought did CABLE predict that trees would have reached critical PLC in widespread areas (i.e. it projected a low mortality risk), although the model highlighted critical levels near the desert regions of South-East Australia where few trees live. Overall, our experimentally constrained model results imply significant resilience to drought conferred by hydraulic function, but also highlight critical data and scientific gaps. Our approach presents a promising avenue to integrate experimental data and make regional-scale predictions of potential drought-induced hydraulic failure.

Original language	English
Pages (from-to)	5716-5733
Number of pages	18
Journal	Global Change Biology
Volume	26
Issue number	10
DOIs	https://doi.org/10.1111/gcb.15215
Publication status	Published - 1 Oct 2020

Access to Document

10.1111/gcb.15215

Cite this

De Kauwe, M. G., Medlyn, B. E., Ukkola, A. M., Mu, M., Sabot, M. E. B., Pitman, A. J., Meir, P., Cernusak, L. A., Rifai, S. W., Choat, B., Tissue, D. T., Blackman, C. J., Li, X., Roderick, M., & Briggs, P. R. (2020). Identifying areas at risk of drought-induced tree mortality across South-Eastern Australia. Global Change Biology, 26(10), 5716-5733. https://doi.org/10.1111/gcb.15215

@article{b87eaef75255416b9c7dcbaccf37c1ed,

title = "Identifying areas at risk of drought-induced tree mortality across South-Eastern Australia",

abstract = "South-East Australia has recently been subjected to two of the worst droughts in the historical record (Millennium Drought, 2000–2009 and Big Dry, 2017–2019). Unfortunately, a lack of forest monitoring has made it difficult to determine whether widespread tree mortality has resulted from these droughts. Anecdotal observations suggest the Big Dry may have led to more significant tree mortality than the Millennium drought. Critically, to be able to robustly project future expected climate change effects on Australian vegetation, we need to assess the vulnerability of Australian trees to drought. Here we implemented a model of plant hydraulics into the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model. We parameterized the drought response behaviour of five broad vegetation types, based on a common garden dry-down experiment with species originating across a rainfall gradient (188–1,125 mm/year) across South-East Australia. The new hydraulics model significantly improved (~35%–45% reduction in root mean square error) CABLE{\textquoteright}s previous predictions of latent heat fluxes during periods of water stress at two eddy covariance sites in Australia. Landscape-scale predictions of the greatest percentage loss of hydraulic conductivity (PLC) of about 40%–60%, were broadly consistent with satellite estimates of regions of the greatest change in both droughts. In neither drought did CABLE predict that trees would have reached critical PLC in widespread areas (i.e. it projected a low mortality risk), although the model highlighted critical levels near the desert regions of South-East Australia where few trees live. Overall, our experimentally constrained model results imply significant resilience to drought conferred by hydraulic function, but also highlight critical data and scientific gaps. Our approach presents a promising avenue to integrate experimental data and make regional-scale predictions of potential drought-induced hydraulic failure.",

keywords = "Australia, cavitation resistance, drought tolerance, land surface model, plant hydraulics",

author = "{De Kauwe}, {Martin G.} and Medlyn, {Belinda E.} and Ukkola, {Anna M.} and Mengyuan Mu and Sabot, {Manon E.B.} and Pitman, {Andrew J.} and Patrick Meir and Cernusak, {Lucas A.} and Rifai, {Sami W.} and Brendan Choat and Tissue, {David T.} and Blackman, {Chris J.} and Ximeng Li and Michael Roderick and Briggs, {Peter R.}",

note = "Publisher Copyright: {\textcopyright} 2020 John Wiley & Sons Ltd",

year = "2020",

month = oct,

day = "1",

doi = "10.1111/gcb.15215",

language = "English",

volume = "26",

pages = "5716--5733",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell Publishing Ltd",

number = "10",

}

TY - JOUR

T1 - Identifying areas at risk of drought-induced tree mortality across South-Eastern Australia

AU - De Kauwe, Martin G.

AU - Medlyn, Belinda E.

AU - Ukkola, Anna M.

AU - Mu, Mengyuan

AU - Sabot, Manon E.B.

AU - Pitman, Andrew J.

AU - Meir, Patrick

AU - Cernusak, Lucas A.

AU - Rifai, Sami W.

AU - Choat, Brendan

AU - Tissue, David T.

AU - Blackman, Chris J.

AU - Li, Ximeng

AU - Roderick, Michael

AU - Briggs, Peter R.

PY - 2020/10/1

Y1 - 2020/10/1

N2 - South-East Australia has recently been subjected to two of the worst droughts in the historical record (Millennium Drought, 2000–2009 and Big Dry, 2017–2019). Unfortunately, a lack of forest monitoring has made it difficult to determine whether widespread tree mortality has resulted from these droughts. Anecdotal observations suggest the Big Dry may have led to more significant tree mortality than the Millennium drought. Critically, to be able to robustly project future expected climate change effects on Australian vegetation, we need to assess the vulnerability of Australian trees to drought. Here we implemented a model of plant hydraulics into the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model. We parameterized the drought response behaviour of five broad vegetation types, based on a common garden dry-down experiment with species originating across a rainfall gradient (188–1,125 mm/year) across South-East Australia. The new hydraulics model significantly improved (~35%–45% reduction in root mean square error) CABLE’s previous predictions of latent heat fluxes during periods of water stress at two eddy covariance sites in Australia. Landscape-scale predictions of the greatest percentage loss of hydraulic conductivity (PLC) of about 40%–60%, were broadly consistent with satellite estimates of regions of the greatest change in both droughts. In neither drought did CABLE predict that trees would have reached critical PLC in widespread areas (i.e. it projected a low mortality risk), although the model highlighted critical levels near the desert regions of South-East Australia where few trees live. Overall, our experimentally constrained model results imply significant resilience to drought conferred by hydraulic function, but also highlight critical data and scientific gaps. Our approach presents a promising avenue to integrate experimental data and make regional-scale predictions of potential drought-induced hydraulic failure.

AB - South-East Australia has recently been subjected to two of the worst droughts in the historical record (Millennium Drought, 2000–2009 and Big Dry, 2017–2019). Unfortunately, a lack of forest monitoring has made it difficult to determine whether widespread tree mortality has resulted from these droughts. Anecdotal observations suggest the Big Dry may have led to more significant tree mortality than the Millennium drought. Critically, to be able to robustly project future expected climate change effects on Australian vegetation, we need to assess the vulnerability of Australian trees to drought. Here we implemented a model of plant hydraulics into the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model. We parameterized the drought response behaviour of five broad vegetation types, based on a common garden dry-down experiment with species originating across a rainfall gradient (188–1,125 mm/year) across South-East Australia. The new hydraulics model significantly improved (~35%–45% reduction in root mean square error) CABLE’s previous predictions of latent heat fluxes during periods of water stress at two eddy covariance sites in Australia. Landscape-scale predictions of the greatest percentage loss of hydraulic conductivity (PLC) of about 40%–60%, were broadly consistent with satellite estimates of regions of the greatest change in both droughts. In neither drought did CABLE predict that trees would have reached critical PLC in widespread areas (i.e. it projected a low mortality risk), although the model highlighted critical levels near the desert regions of South-East Australia where few trees live. Overall, our experimentally constrained model results imply significant resilience to drought conferred by hydraulic function, but also highlight critical data and scientific gaps. Our approach presents a promising avenue to integrate experimental data and make regional-scale predictions of potential drought-induced hydraulic failure.

KW - Australia

KW - cavitation resistance

KW - drought tolerance

KW - land surface model

KW - plant hydraulics

UR - http://www.scopus.com/inward/record.url?scp=85089480087&partnerID=8YFLogxK

U2 - 10.1111/gcb.15215

DO - 10.1111/gcb.15215

M3 - Article

SN - 1354-1013

VL - 26

SP - 5716

EP - 5733

JO - Global Change Biology

JF - Global Change Biology

IS - 10

ER -

Identifying areas at risk of drought-induced tree mortality across South-Eastern Australia

Abstract

Access to Document

Other files and links

Fingerprint

Cite this