Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/wiley/climate-and-geochemistry-as-drivers-of-eucalypt-diversification-in-IhDYt7R8Ey
References (68)
-
F. Blanchet, P. Legendre, D. Borcard (2008)
Forward selection of explanatory variables.Ecology, 89 9
-
D. Borcard, F. Gillet, P. Legendre (2011)
Numerical ecology with R -
J. Lennon, Patricia Koleff, J. Greenwood, K. Gaston (2001)
The geographical structure of British bird distributions: diversity, spatial turnover and scaleJournal of Animal Ecology, 70
-
M. Bayly, P. Rigault, Antanas Spokevicius, P. Ladiges, P. Ades, Charlotte Anderson, G. Bossinger, A. Merchant, F. Udovicic, I. Woodrow, J. Tibbits (2013)
Chloroplast genome analysis of Australian eucalypts--Eucalyptus, Corymbia, Angophora, Allosyncarpia and Stockwellia (Myrtaceae).Molecular phylogenetics and evolution, 69 3
-
N. C. W. Beadle (1981)
The vegetation of Australia -
P. Wellman, I. Mcdougall (1974)
Cainozoic igneous activity in eastern australiaTectonophysics, 23
-
A. Thornhill, S. Ho, C. Külheim, M. Crisp (2015)
Interpreting the modern distribution of Myrtaceae using a dated molecular phylogeny.Molecular phylogenetics and evolution, 93
-
M. Austin, J. Pausas, A. Nicholls (1996)
Patterns of tree species richness in relation to environment in southeastern New South Wales, AustraliaAustral Ecology, 21
-
Laura Pollock, M. Bayly, P. Vesk (2015)
The Roles of Ecological and Evolutionary Processes in Plant Community Assembly: The Environment, Hybridization, and Introgression Influence Co-occurrence of EucalyptusThe American Naturalist, 185
-
L. Merwin, Tianhua He, B. Lamont (2012)
Phylogenetic and phenotypic structure among Banksia communities in south‐western AustraliaJournal of Biogeography, 39
-
F. Adams, P. Reddell, M. Webb, W. Shipton (2006)
Arbuscular mycorrhizas and ectomycorrhizas on Eucalyptus grandis (Myrtaceae) trees and seedlings in native forests of tropical north-eastern AustraliaAustralian Journal of Botany, 54
-
D. Nicolle (2006)
A classification and census of regenerative strategies in the eucalypts (Angophora, Corymbia and Eucalyptus—Myrtaceae), with special reference to the obligate seedersAustralian Journal of Botany, 54
-
S. Hill, G. Taylor, K. McQueen, R. Anand, C. Phang, J. Wildman, M. Lintern (1997)
Genesis of some calcretes in the southern Yilgarn Craton, Western Australia: Implications for mineral explorationAustralian Journal of Earth Sciences, 44
-
K. Williams, S. Ferrier, D. Rosauer, D. Yeates, G. Manion, T. Harwood, J. Stein, D. Faith, Tania Laity, Anthony Whalen (2010)
Harnessing Continent-Wide Biodiversity Datasets for Prioritising National Conservation Investment -
E. Bui, Carlos González‐Orozco, Joseph Miller (2014)
Acacia, climate, and geochemistry in AustraliaPlant and Soil, 381
-
M. Ebach, Carlos González‐Orozco, Joseph Miller, D. Murphy (2015)
A revised area taxonomy of phytogeographical regions within the Australian Bioregionalisation AtlasPhytotaxa, 208
-
Laura Pollock, M. Bayly, P. Nevill, P. Vesk (2013)
Chloroplast DNA diversity associated with protected slopes and valleys for hybridizing Eucalyptus species on isolated ranges in south‐eastern AustraliaJournal of Biogeography, 40
-
L. Tedersoo, T. Jairus, B. Horton, K. Abarenkov, T. Suvi, I. Saar, U. Kõljalg (2008)
Strong host preference of ectomycorrhizal fungi in a Tasmanian wet sclerophyll forest as revealed by DNA barcoding and taxon-specific primers.The New phytologist, 180 2
-
J. Sander, G. Wardell-Johnson (2011)
Impacts of soil fertility on species and phylogenetic turnover in the high - rainfall zone of the Southwest Australian global biodiversity hotspotPlant and Soil, 345
-
M. Brooker (2000)
A new classification of the genus Eucalyptus L'Hér. (Myrtaceae)Australian Systematic Botany, 13
-
P. Caritat, M. Cooper (2011)
National geochemical survey of Australia; data quality assessment -
R. Ricklefs (2004)
A comprehensive framework for global patterns in biodiversityEcology Letters, 7
-
P. Legendre (2008)
Studying beta diversity: ecological variation partitioning by multiple regression and canonical analysisJournal of Plant Ecology, 1
-
G. Virgilio, S. Laffan, M. Ebach (2012)
Fine‐scale quantification of floral and faunal breaks and their geographic correlates, with an example from south‐eastern AustraliaJournal of Biogeography, 39
-
P. Caritat, C. Reimann (2012)
Comparing results from two continental geochemical surveys to world soil composition and deriving Predicted Empirical Global Soil (PEGS2) reference valuesEarth and Planetary Science Letters, 319
-
R. Cowling, E. Witkowski, A. Milewski, K. Newbrey (1994)
Taxonomic, edaphic and biological aspects of narrow plant endemism on marched sites in mediterranean South Africa and AustraliaJournal of Biogeography, 21
-
B. Bowen, K. Benison (2009)
Geochemical characteristics of naturally acid and alkaline saline lakes in southern Western AustraliaApplied Geochemistry, 24
-
B. Potts, J. Reid (1990)
THE EVOLUTIONARY SIGNIFICANCE OF HYBRIDIZATION IN EUCALYPTUSEvolution, 44
-
G. Holdgate, M. Wallace, S. Gallagher, B. Wagstaff, D. Moore (2008)
No mountains to snow on: major post-Eocene uplift of the East Victoria Highlands; evidence from Cenozoic depositsAustralian Journal of Earth Sciences, 55
-
R. Hill, Y. Beer, K. Hill, E. Maciunas, M. Tarran, C. Wainman (2016)
Evolution of the eucalypts – an interpretation from the macrofossil recordAustralian Journal of Botany, 64
-
L. Pryor, L. Johnson (1981)
Eucalyptus, the universal Australian -
R. Ricklefs (1977)
Environmental Heterogeneity and Plant Species Diversity: A HypothesisThe American Naturalist, 111
-
David Smith, C. Reimann (2008)
Low-density geochemical mapping and the robustness of geochemical patternsGeochemistry: Exploration, Environment, Analysis, 8
-
J. Webb, T. Gardner, D. Kapostasy, Kathy Bremar, D. Fabel (2011)
Mountain building along a passive margin: Late Neogene tectonism in southeastern Victoria, AustraliaGeomorphology, 125
-
M. Crisp, G. Burrows, L. Cook, A. Thornhill, D. Bowman (2011)
Flammable biomes dominated by eucalypts originated at the Cretaceous-Palaeogene boundary.Nature communications, 2
-
H. Martin (2006)
Cenozoic climatic change and the development of the arid vegetation in AustraliaJournal of Arid Environments, 66
-
J. McArthur, J. Turner, W. Lyons, A. Osborn, M. Thirlwall (1991)
Hydrochemistry on the yilgarn block, western Australia: Ferrolysis and mineralisation in acidic brinesGeochimica et Cosmochimica Acta, 55
-
Carlos González‐Orozco, M. Ebach, S. Laffan, A. Thornhill, Nunzio Knerr, A. Schmidt‐Lebuhn, Christine Cargill, M. Clements, N. Nagalingum, B. Mishler, Joseph Miller (2014)
Quantifying Phytogeographical Regions of Australia Using Geospatial Turnover in Species CompositionPLoS ONE, 9
-
J. Kruskal (1964)
Multidimensional scaling by optimizing goodness of fit to a nonmetric hypothesisPsychometrika, 29
-
K. Benison, B. Bowen (2013)
Extreme sulfur-cycling in acid brine lake environments of Western AustraliaChemical Geology, 351
-
H. Martin (1997)
The Use of Ecological Tolerances for the Reconstruction of Tertiary PalaeoclimatesAustralian Journal of Botany, 45
-
S. Hopper, P. Gioia (2004)
The Southwest Australian Floristic Region: Evolution and Conservation of a Global Hot Spot of BiodiversityAnnual Review of Ecology, Evolution, and Systematics, 35
-
N. Beadle (1962)
An alternative hypothesis to account for the generally low phosphate content of Australian soilsCrop & Pasture Science, 13
-
G. Burrows (2013)
Buds, bushfires and resprouting in the eucalyptsAustralian Journal of Botany, 61
-
R. Brinkman (1970)
Ferrolysis, a hydromorphic soil forming processGeoderma, 3
-
J. Wilford, P. Caritat, E. Bui (2015)
Modelling the abundance of soil calcium carbonate across Australia using geochemical survey data and environmental predictorsGeoderma, 259
-
I. Fordyce, D. Eamus, G. Duff, Richard Williams (1997)
The role of seedling age and size in the recovery of Allosyncarpia ternata following fireAustral Ecology, 22
-
G. Burrows (2002)
Epicormic strand structure in Angophora, Eucalyptus and Lophostemon (Myrtaceae): implications for fire resistance and recoveryNew Phytologist, 153
-
E. Bui, B. Henderson, K. Viergever (2006)
Knowledge discovery from models of soil properties developed through data miningEcological Modelling, 191
-
Carlos González‐Orozco, A. Thornhill, Nunzio Knerr, S. Laffan, Joseph Miller (2014)
Biogeographical regions and phytogeography of the eucalyptsDiversity and Distributions, 20
-
E. Schulze, N. Turner, D. Nicolle, J. Schumacher (2006)
Leaf and wood carbon isotope ratios, specific leaf areas and wood growth of Eucalyptus species across a rainfall gradient in Australia.Tree physiology, 26 4
-
M. Austin, R. Cunningham, J. Wood (1983)
The Subgeneric Composition of Eucalypt Forest Stands in a Region of South-Eastern AustraliaAustralian Journal of Botany, 31
-
A. Thornhill, L. Popple, R. Carter, S. Ho, M. Crisp (2012)
Are pollen fossils useful for calibrating relaxed molecular clock dating of phylogenies? A comparative study using Myrtaceae.Molecular phylogenetics and evolution, 63 1
-
J. McArthur, J. Turner, W. Lyons, M. Thirlwall (1989)
Salt sources and water-rock interaction on the Yilgarn Block, Australia: isotopic and major element tracersApplied Geochemistry, 4
-
M. Crisp, L. Cook (2007)
A congruent molecular signature of vicariance across multiple plant lineages.Molecular phylogenetics and evolution, 43 3
-
S. Laffan, E. Lubarsky, D. Rosauer (2010)
Biodiverse, a tool for the spatial analysis of biological and related diversityEcography, 33
-
T. Booth (2013)
Eucalypt plantations and climate changeForest Ecology and Management, 301
-
Yinglong Chen, Mark Brundrett, B. Dell (2000)
Effects of ectomycorrhizas and vesicular-arbuscular mycorrhizas, alone or in competition, on root colonization and growth of Eucalyptus globulus and E. urophylla.New Phytologist, 146
-
R. Whittaker (1972)
Evolution and measurement of species diversityTaxon, 21
-
M. Macphail, A. Thornhill (2016)
How old are the eucalypts? A review of the microfossil and phylogenetic evidenceAustralian Journal of Botany, 64
-
R. Anand, M. Paine (2002)
Regolith geology of the Yilgarn Craton, Western Australia: Implications for explorationAustralian Journal of Earth Sciences, 49
-
Carlos González‐Orozco, S. Laffan, Joseph Miller (2011)
Spatial distribution of species richness and endemism of the genus Acacia in AustraliaAustralian Journal of Botany, 59
-
Hongbo Zheng, K. Wyrwoll, Zheng‐Xiang Li, C. Powell (1998)
Onset of aridity in southern Western Australia—a preliminary palaeomagnetic appraisal, 18
-
R. Shepard (1962)
The analysis of proximities: Multidimensional scaling with an unknown distance function. IIPsychometrika, 27
-
Carlos González‐Orozco, S. Laffan, Nunzio Knerr, Joseph Miller (2013)
A biogeographical regionalization of Australian Acacia speciesJournal of Biogeography, 40
-
Carlos González‐Orozco, Laura Pollock, A. Thornhill, B. Mishler, Nunzio Knerr, S. Laffan, Joseph Miller, D. Rosauer, D. Faith, David Nipperess, H. Kujala, S. Linke, N. Butt, C. Külheim, M. Crisp, B. Gruber (2016)
Phylogenetic approaches reveal biodiversity threats under climate changeNature Climate Change, 6
-
E. Bui, A. Thornhill, Joseph Miller (2014)
Salt- and alkaline-tolerance are linked in AcaciaBiology Letters, 10
-
R. Rossel, Chengrong Chen, M. Grundy, R. Searle, D. Clifford, P. Campbell (2015)
The Australian three-dimensional soil grid: Australia’s contribution to the GlobalSoilMap projectSoil Research, 53
- Publisher
- Wiley
- Copyright
- Copyright © 2017 John Wiley & Sons Ltd
- ISSN
- 1472-4677
- eISSN
- 1472-4669
- DOI
- 10.1111/gbi.12235
- pmid
- 28371135
- Publisher site
- See Article on Publisher Site
Abstract
Eucalypts cover most of Australia. Here, we investigate the relative contribution of climate and geochemistry to the distribution and diversity of eucalypts. Using geostatistics, we estimate major element concentrations, pH, and electrical conductivity at sites where eucalypts have been recorded. We compare the median predicted geochemistry and reported substrate for individual species that appear associated with extreme conditions; this provides a partial evaluation of the predictions. We generate a site‐by‐species matrix by aggregating observations to the centroids of 100‐km‐wide grid cells, calculate diversity indices, and use numerical ecology methods (ordination, variation partitioning) to investigate the ecology of eucalypts and their response to climatic and geochemical gradients. We find that β‐diversity coincides with variations in climatic and geochemical patterns. Climate and geochemistry together account for less than half of the variation in eucalypt species assemblages across Australia but for greater than 80% in areas of high species richness. Climate is more important than geochemistry in explaining eucalypts species distribution and change in assemblages across Australia as a whole but there are correlations between the two sets of environmental variables. Many individual eucalypt species and entire taxonomic sections (Aromatica, Longistylus of subgenus Eucalyptus, Dumaria, and Liberivalvae of subgenus Symphyomyrtus) have distributions affected strongly by geochemistry. We conclude that eucalypt diversity is driven by steep geochemical gradients that have arisen as climate patterns have fluctuated over Australia over the Cenozoic, generally aridifying since the Miocene. The diversification of eucalypts across Australia is thus an excellent example of co‐evolution of landscapes and biota in space and time and challenges accepted notions of macroecology.
Journal
Geobiology – Wiley
Published: May 1, 2017
Keywords: ; ; ; ; ; ; ; ; ; ;