Biodiversity impacts of the 2019-2020 Australian megafires

Don A. Driscoll; Kristina J. Macdonald; Rebecca K. Gibson; Tim S. Doherty; Dale G. Nimmo; Rachael H. Nolan; Euan G. Ritchie; Grant J. Williamson; Geoffrey W. Heard; Elizabeth M. Tasker; Rohan Bilney; Nick Porch; Rachael A. Collett; Ross A. Crates; Alison C. Hewitt; Elise Pendall; Matthias M. Boer; Jody Gates; Rebecca L. Boulton; Christopher M. Mclean; Heidi Groffen; Alex C. Maisey; Chad T. Beranek; Shelby A. Ryan; Alex Callen; Andrew J. Hamer; Andrew Stauber; Garry J. Daly; John Gould; Kaya L. Klop-Toker; Michael J. Mahony; Oliver W. Kelly; Samantha L. Wallace; Sarah E. Stock; Christopher J. Weston; Liubov Volkova; Dennis Black; Heloise Gibb; Joshua J. Grubb; Melodie A. McGeoch; Nick P. Murphy; Joshua S. Lee; Chris R. Dickman; Victor J. Neldner; Michael R. Ngugi; Mike Letnic; Sarah Barrett; Amy Marie Gilpin; James M. Cook; Sally A. Power

doi:10.1038/s41586-024-08174-6

Biodiversity impacts of the 2019-2020 Australian megafires

Don A. Driscoll
, Kristina J. Macdonald
, Rebecca K. Gibson
, Tim S. Doherty
, Dale G. Nimmo
, Rachael H. Nolan
, Euan G. Ritchie
, Grant J. Williamson
, Geoffrey W. Heard
, Elizabeth M. Tasker
, Rohan Bilney
, Nick Porch
, Rachael A. Collett
, Ross A. Crates
, Alison C. Hewitt
, Elise Pendall
, Matthias M. Boer
, Jody Gates
, Rebecca L. Boulton
, Christopher M. Mclean

Heidi Groffen, Alex C. Maisey, Chad T. Beranek, Shelby A. Ryan, Alex Callen, Andrew J. Hamer, Andrew Stauber, Garry J. Daly, John Gould, Kaya L. Klop-Toker, Michael J. Mahony, Oliver W. Kelly, Samantha L. Wallace, Sarah E. Stock, Christopher J. Weston, Liubov Volkova, Dennis Black, Heloise Gibb, Joshua J. Grubb, Melodie A. McGeoch, Nick P. Murphy, Joshua S. Lee, Chris R. Dickman, Victor J. Neldner, Michael R. Ngugi, Mike Letnic, Sarah Barrett, Amy Marie Gilpin, James M. Cook, Sally A. Power

Deakin University
the Environment and Water
The University of Sydney
Conservation and Attractions
Charles Sturt University
University of Tasmania
University of Queensland
Australian National University
Environment and Water
Forestry Corporation of New South Wales
SA Department of Environment and Water
University of Adelaide
Central Coast Council
Kangaroo Island Land for Wildlife Association
La Trobe University
University of Newcastle
Centre for Ecological Research
Gaia Research P/L
University of Melbourne
School of Biological
University of New South Wales
Queensland Department of Environment and Science
South Coast Region
Parks and Wildlife Service

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

86 Citations (Scopus)

37 Downloads (Pure)

Abstract

With large wildfires becoming more frequent1,2, we must rapidly learn how megafires impact biodiversity to prioritize mitigation and improve policy. A key challenge is to discover how interactions among fire-regime components, drought and land tenure shape wildfire impacts. The globally unprecedented3,4 2019-2020 Australian megafires burnt more than 10 million hectares5, prompting major investment in biodiversity monitoring. Collated data include responses of more than 2,000 taxa, providing an unparalleled opportunity to quantify how megafires affect biodiversity. We reveal that the largest effects on plants and animals were in areas with frequent or recent past fires and within extensively burnt areas. Areas burnt at high severity, outside protected areas or under extreme drought also had larger effects. The effects included declines and increases after fire, with the largest responses in rainforests and by mammals. Our results implicate species interactions, dispersal and extent of in situ survival as mechanisms underlying fire responses. Building wildfire resilience into these ecosystems depends on reducing fire recurrence, including with rapid wildfire suppression in areas frequently burnt. Defending wet ecosystems, expanding protected areas and considering localized drought could also contribute. While these countermeasures can help mitigate the impacts of more frequent megafires, reversing anthropogenic climate change remains the urgent broad-scale solution.

Original language	English
Pages (from-to)	898-905
Number of pages	8
Journal	Nature
Volume	635
Issue number	8040
DOIs	https://doi.org/10.1038/s41586-024-08174-6
Publication status	Published - 28 Nov 2024

Bibliographical note

Publisher Copyright:
© The Author(s) 2024.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action

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Driscoll, D. A., Macdonald, K. J., Gibson, R. K., Doherty, T. S., Nimmo, D. G., Nolan, R. H., Ritchie, E. G., Williamson, G. J., Heard, G. W., Tasker, E. M., Bilney, R., Porch, N., Collett, R. A., Crates, R. A., Hewitt, A. C., Pendall, E., Boer, M. M., Gates, J., Boulton, R. L., ... Power, S. A. (2024). Biodiversity impacts of the 2019-2020 Australian megafires. Nature, 635(8040), 898-905. https://doi.org/10.1038/s41586-024-08174-6

@article{7cce74fd927e45359333b2fc3fb31fbc,

title = "Biodiversity impacts of the 2019-2020 Australian megafires",

abstract = "With large wildfires becoming more frequent1,2, we must rapidly learn how megafires impact biodiversity to prioritize mitigation and improve policy. A key challenge is to discover how interactions among fire-regime components, drought and land tenure shape wildfire impacts. The globally unprecedented3,4 2019-2020 Australian megafires burnt more than 10 million hectares5, prompting major investment in biodiversity monitoring. Collated data include responses of more than 2,000 taxa, providing an unparalleled opportunity to quantify how megafires affect biodiversity. We reveal that the largest effects on plants and animals were in areas with frequent or recent past fires and within extensively burnt areas. Areas burnt at high severity, outside protected areas or under extreme drought also had larger effects. The effects included declines and increases after fire, with the largest responses in rainforests and by mammals. Our results implicate species interactions, dispersal and extent of in situ survival as mechanisms underlying fire responses. Building wildfire resilience into these ecosystems depends on reducing fire recurrence, including with rapid wildfire suppression in areas frequently burnt. Defending wet ecosystems, expanding protected areas and considering localized drought could also contribute. While these countermeasures can help mitigate the impacts of more frequent megafires, reversing anthropogenic climate change remains the urgent broad-scale solution.",

author = "Driscoll, \{Don A.\} and Macdonald, \{Kristina J.\} and Gibson, \{Rebecca K.\} and Doherty, \{Tim S.\} and Nimmo, \{Dale G.\} and Nolan, \{Rachael H.\} and Ritchie, \{Euan G.\} and Williamson, \{Grant J.\} and Heard, \{Geoffrey W.\} and Tasker, \{Elizabeth M.\} and Rohan Bilney and Nick Porch and Collett, \{Rachael A.\} and Crates, \{Ross A.\} and Hewitt, \{Alison C.\} and Elise Pendall and Boer, \{Matthias M.\} and Jody Gates and Boulton, \{Rebecca L.\} and Mclean, \{Christopher M.\} and Heidi Groffen and Maisey, \{Alex C.\} and Beranek, \{Chad T.\} and Ryan, \{Shelby A.\} and Alex Callen and Hamer, \{Andrew J.\} and Andrew Stauber and Daly, \{Garry J.\} and John Gould and Klop-Toker, \{Kaya L.\} and Mahony, \{Michael J.\} and Kelly, \{Oliver W.\} and Wallace, \{Samantha L.\} and Stock, \{Sarah E.\} and Weston, \{Christopher J.\} and Liubov Volkova and Dennis Black and Heloise Gibb and Grubb, \{Joshua J.\} and McGeoch, \{Melodie A.\} and Murphy, \{Nick P.\} and Lee, \{Joshua S.\} and Dickman, \{Chris R.\} and Neldner, \{Victor J.\} and Ngugi, \{Michael R.\} and Mike Letnic and Sarah Barrett and Gilpin, \{Amy Marie\} and Cook, \{James M.\} and Power, \{Sally A.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = nov,

day = "28",

doi = "10.1038/s41586-024-08174-6",

language = "English",

volume = "635",

pages = "898--905",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "8040",

}

Driscoll, DA, Macdonald, KJ, Gibson, RK, Doherty, TS, Nimmo, DG, Nolan, RH, Ritchie, EG, Williamson, GJ, Heard, GW, Tasker, EM, Bilney, R, Porch, N, Collett, RA, Crates, RA, Hewitt, AC, Pendall, E , Boer, MM, Gates, J, Boulton, RL, Mclean, CM, Groffen, H, Maisey, AC, Beranek, CT, Ryan, SA, Callen, A, Hamer, AJ, Stauber, A, Daly, GJ, Gould, J, Klop-Toker, KL, Mahony, MJ, Kelly, OW, Wallace, SL, Stock, SE, Weston, CJ, Volkova, L, Black, D, Gibb, H, Grubb, JJ, McGeoch, MA, Murphy, NP, Lee, JS, Dickman, CR, Neldner, VJ, Ngugi, MR, Letnic, M, Barrett, S, Gilpin, AM , Cook, JM & Power, SA 2024, 'Biodiversity impacts of the 2019-2020 Australian megafires', Nature, vol. 635, no. 8040, pp. 898-905. https://doi.org/10.1038/s41586-024-08174-6

TY - JOUR

T1 - Biodiversity impacts of the 2019-2020 Australian megafires

AU - Driscoll, Don A.

AU - Macdonald, Kristina J.

AU - Gibson, Rebecca K.

AU - Doherty, Tim S.

AU - Nimmo, Dale G.

AU - Nolan, Rachael H.

AU - Ritchie, Euan G.

AU - Williamson, Grant J.

AU - Heard, Geoffrey W.

AU - Tasker, Elizabeth M.

AU - Bilney, Rohan

AU - Porch, Nick

AU - Collett, Rachael A.

AU - Crates, Ross A.

AU - Hewitt, Alison C.

AU - Pendall, Elise

AU - Boer, Matthias M.

AU - Gates, Jody

AU - Boulton, Rebecca L.

AU - Mclean, Christopher M.

AU - Groffen, Heidi

AU - Maisey, Alex C.

AU - Beranek, Chad T.

AU - Ryan, Shelby A.

AU - Callen, Alex

AU - Hamer, Andrew J.

AU - Stauber, Andrew

AU - Daly, Garry J.

AU - Gould, John

AU - Klop-Toker, Kaya L.

AU - Mahony, Michael J.

AU - Kelly, Oliver W.

AU - Wallace, Samantha L.

AU - Stock, Sarah E.

AU - Weston, Christopher J.

AU - Volkova, Liubov

AU - Black, Dennis

AU - Gibb, Heloise

AU - Grubb, Joshua J.

AU - McGeoch, Melodie A.

AU - Murphy, Nick P.

AU - Lee, Joshua S.

AU - Dickman, Chris R.

AU - Neldner, Victor J.

AU - Ngugi, Michael R.

AU - Letnic, Mike

AU - Barrett, Sarah

AU - Gilpin, Amy Marie

AU - Cook, James M.

AU - Power, Sally A.

PY - 2024/11/28

Y1 - 2024/11/28

N2 - With large wildfires becoming more frequent1,2, we must rapidly learn how megafires impact biodiversity to prioritize mitigation and improve policy. A key challenge is to discover how interactions among fire-regime components, drought and land tenure shape wildfire impacts. The globally unprecedented3,4 2019-2020 Australian megafires burnt more than 10 million hectares5, prompting major investment in biodiversity monitoring. Collated data include responses of more than 2,000 taxa, providing an unparalleled opportunity to quantify how megafires affect biodiversity. We reveal that the largest effects on plants and animals were in areas with frequent or recent past fires and within extensively burnt areas. Areas burnt at high severity, outside protected areas or under extreme drought also had larger effects. The effects included declines and increases after fire, with the largest responses in rainforests and by mammals. Our results implicate species interactions, dispersal and extent of in situ survival as mechanisms underlying fire responses. Building wildfire resilience into these ecosystems depends on reducing fire recurrence, including with rapid wildfire suppression in areas frequently burnt. Defending wet ecosystems, expanding protected areas and considering localized drought could also contribute. While these countermeasures can help mitigate the impacts of more frequent megafires, reversing anthropogenic climate change remains the urgent broad-scale solution.

AB - With large wildfires becoming more frequent1,2, we must rapidly learn how megafires impact biodiversity to prioritize mitigation and improve policy. A key challenge is to discover how interactions among fire-regime components, drought and land tenure shape wildfire impacts. The globally unprecedented3,4 2019-2020 Australian megafires burnt more than 10 million hectares5, prompting major investment in biodiversity monitoring. Collated data include responses of more than 2,000 taxa, providing an unparalleled opportunity to quantify how megafires affect biodiversity. We reveal that the largest effects on plants and animals were in areas with frequent or recent past fires and within extensively burnt areas. Areas burnt at high severity, outside protected areas or under extreme drought also had larger effects. The effects included declines and increases after fire, with the largest responses in rainforests and by mammals. Our results implicate species interactions, dispersal and extent of in situ survival as mechanisms underlying fire responses. Building wildfire resilience into these ecosystems depends on reducing fire recurrence, including with rapid wildfire suppression in areas frequently burnt. Defending wet ecosystems, expanding protected areas and considering localized drought could also contribute. While these countermeasures can help mitigate the impacts of more frequent megafires, reversing anthropogenic climate change remains the urgent broad-scale solution.

UR - https://www.scopus.com/pages/publications/85209096956

U2 - 10.1038/s41586-024-08174-6

DO - 10.1038/s41586-024-08174-6

M3 - Article

C2 - 39537920

AN - SCOPUS:85209096956

SN - 0028-0836

VL - 635

SP - 898

EP - 905

JO - Nature

JF - Nature

IS - 8040

ER -

Biodiversity impacts of the 2019-2020 Australian megafires

Abstract

Bibliographical note

UN SDGs

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