New species of xeromorphic Banksia (Proteaceae) foliage and Banksia-like pollen from the late Eocene of Western Australia
Raymond J. Carpenter A C and Lynne A. Milne BA School of Biological Sciences, University of Adelaide, Adelaide, SA 5005, Australia.
B School of Earth and Planetary Sciences, Curtin University, GPO Box U1987, Perth, WA 6845, Australia.
C Corresponding author. Email: raymond.carpenter@adelaide.edu.au
Australian Journal of Botany 68(3) 165-178 https://doi.org/10.1071/BT19110
Submitted: 19 June 2019 Accepted: 18 October 2019 Published: 31 January 2020
Abstract
Banksia microphylla leaf fossils and Banksieaeidites zanthus pollen are newly described from late Eocene lignite of the Zanthus-11 borehole, drilled east of Norseman in Western Australia. The leaf fossils are the first known in Banksia to show extreme narrowness (<1.5 mm wide) combined with the xeromorphic trait of margins rolled onto the lower surface so that the diffusely placed stomata are exposed to the outside environment only via grooves on each side of a thick, abaxial midrib. Both this Banksia leaf type and another with encrypted stomata evolved before the widespread initiation of severe climatic aridity in the late Neogene, likely in regions of edaphic infertility and periodic water stress. New interpretations of leaf morphology and foliar evolutionary pathways in Banksia are proposed. Banksia microphylla probably belongs to subgenus Spathulatae, where it strongly resembles many species in the large, wholly Western Australian clade that includes most species in section Oncostylis, series Abietinae. Banksieaeidites zanthus is morphologically consistent with Banksia pollen, and its extremely small size also suggests placement in Spathulatae. The new fossils and other evidence from Zanthus-11 indicate the local presence of quite open, sclerophyll vegetation with conifers, which was unlikely to have been frequently burnt.
Additional keywords: Cenozoic, fire, fossil, heathland, palynology, phylogeny, sclerophyll, stomata.
References
Bannister JM, Conran JG, Lee DE (2012) Lauraceae from rainforest surrounding an early Miocene maar lake, Otago, southern New Zealand. Review of Palaeobotany and Palynology 178, 13–34.| Lauraceae from rainforest surrounding an early Miocene maar lake, Otago, southern New Zealand.Crossref | GoogleScholarGoogle Scholar |
Beadle NCW (1981) Origins of the Australian angiosperm flora. In ‘Ecological biogeography of Australia’. (Ed. A Keast) pp. 409–425. (W. Junk: The Hague, The Netherlands)
Bond WJ (2015) Fires in the Cenozoic: a late flowering of flammable ecosystems. Frontiers in Plant Science 5, 749
| Fires in the Cenozoic: a late flowering of flammable ecosystems.Crossref | GoogleScholarGoogle Scholar | 25601873PubMed |
Byrne M, Yeates DK, Joseph L, Kearney M, Bowler J, Williams MA, Cooper S, Donnellan SC, Keogh JS, Leys R, Melville J, Murphy DJ, Porch N, Wyrwoll KH (2008) Birth of a biome: insights into the assembly and maintenance of the Australian arid zone biota. Molecular Ecology 17, 4398–4417.
| Birth of a biome: insights into the assembly and maintenance of the Australian arid zone biota.Crossref | GoogleScholarGoogle Scholar | 18761619PubMed |
Byrne M, Coates DJ, Forest F, Hopper SD, Krauss SL, Sniderman JMK, Thiele KR (2014) A diverse flora – species and genetic relationships. In ‘Plant life on the sandplains in southwest Australia, a global biodiversity hotspot’. (Ed. H Lambers) pp. 81–99. (University of Western Australia Publishing: Perth, WA)
Cardillo M, Pratt R (2013) Evolution of a hotspot genus: geographic variation in speciation and extinction rates in Banksia (Proteaceae). BMC Evolutionary Biology 13, 155
| Evolution of a hotspot genus: geographic variation in speciation and extinction rates in Banksia (Proteaceae).Crossref | GoogleScholarGoogle Scholar | 23957450PubMed |
Carpenter RJ (1994) Cuticular morphology and aspects of the ecology and fossil history of North Queensland rainforest Proteaceae. Botanical Journal of the Linnean Society 116, 249–303.
| Cuticular morphology and aspects of the ecology and fossil history of North Queensland rainforest Proteaceae.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ (2012) Proteaceae leaf fossils: phylogeny, diversity, ecology and austral distributions. Botanical Review 78, 261–287.
| Proteaceae leaf fossils: phylogeny, diversity, ecology and austral distributions.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, Jordan GJ (1997) Early Tertiary macrofossils of Proteaceae from Tasmania. Australian Systematic Botany 10, 533–563.
| Early Tertiary macrofossils of Proteaceae from Tasmania.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, Jordan GJ, Hill RS (1994) Banksieaephyllum taylorii (Proteaceae) from the Late Palaeocene of New South Wales and its relevance to the origin of Australia’s scleromorphic flora. Australian Systematic Botany 7, 385–392.
| Banksieaephyllum taylorii (Proteaceae) from the Late Palaeocene of New South Wales and its relevance to the origin of Australia’s scleromorphic flora.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, Hill RS, Greenwood DR, Partridge AD, Banks MA (2004) No snow in the mountains: early Eocene plant fossils from Hotham Heights, Victoria, Australia. Australian Journal of Botany 52, 685–718.
| No snow in the mountains: early Eocene plant fossils from Hotham Heights, Victoria, Australia.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, Jordan GJ, Lee DE, Hill RS (2010) Leaf fossils of Banksia (Proteaceae) from New Zealand: an Australian abroad. American Journal of Botany 97, 288–297.
| Leaf fossils of Banksia (Proteaceae) from New Zealand: an Australian abroad.Crossref | GoogleScholarGoogle Scholar | 21622389PubMed |
Carpenter RJ, Bannister JM, Lee DE, Jordan GJ (2012) Proteaceae leaf fossils from the Oligo–Miocene of New Zealand: new species and evidence of biome and trait conservatism. Australian Systematic Botany 25, 375–389.
| Proteaceae leaf fossils from the Oligo–Miocene of New Zealand: new species and evidence of biome and trait conservatism.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, McLoughlin S, Hill RS, McNamara KJ, Jordan GJ (2014) Early evidence of xeromorphy in angiosperms: stomatal encryption in a new Eocene species of Banksia (Proteaceae) from Western Australia. American Journal of Botany 101, 1486–1497.
| Early evidence of xeromorphy in angiosperms: stomatal encryption in a new Eocene species of Banksia (Proteaceae) from Western Australia.Crossref | GoogleScholarGoogle Scholar | 25253709PubMed |
Carpenter RJ, Macphail MK, Jordan GJ, Hill RS (2015) Fossil evidence for open, Proteaceae dominated heathlands and fire in the Late Cretaceous of Australia. American Journal of Botany 102, 2092–2107.
| Fossil evidence for open, Proteaceae dominated heathlands and fire in the Late Cretaceous of Australia.Crossref | GoogleScholarGoogle Scholar | 26643888PubMed |
Carpenter RJ, Jordan GJ, Hill RS (2016a) Fossil leaves of Banksia, Banksieae and pretenders: resolving the fossil genus Banksieaephyllum. Australian Systematic Botany 29, 126–141.
| Fossil leaves of Banksia, Banksieae and pretenders: resolving the fossil genus Banksieaephyllum.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, Holman AI, Abell AD, Grice K (2016b) Cretaceous fire in Australia: a review with new geochemical evidence, and relevance to the rise of the angiosperms. Australian Journal of Botany 64, 564–578.
| Cretaceous fire in Australia: a review with new geochemical evidence, and relevance to the rise of the angiosperms.Crossref | GoogleScholarGoogle Scholar |
Carpenter RJ, Tarran M, Hill RS (2017) Leaf fossils of Proteaceae subfamily Persoonioideae, tribe Persoonieae: tracing the past of an important Australasian sclerophyll lineage. Australian Systematic Botany 30, 148–158.
| Leaf fossils of Proteaceae subfamily Persoonioideae, tribe Persoonieae: tracing the past of an important Australasian sclerophyll lineage.Crossref | GoogleScholarGoogle Scholar |
Cavanagh AK, Pieroni M (2006) ‘The Dryandras.’ (Australian Plants Society (SGAP Victoria) Inc.: Hawthorn, Vic. and Wildflower Society of Western Australia, Inc.: Nedlands, WA)
Christophel DC (1984) Early Tertiary Proteaceae: the first floral evidence for the Musgraveinae. Australian Journal of Botany 32, 177–186.
| Early Tertiary Proteaceae: the first floral evidence for the Musgraveinae.Crossref | GoogleScholarGoogle Scholar |
Clarke JDA, Gammon PR, Hou B, Gallagher SJ (2003) Middle to Upper Eocene stratigraphic nomenclature and deposition in the Eucla Basin. Australian Journal of Earth Sciences 50, 231–248.
| Middle to Upper Eocene stratigraphic nomenclature and deposition in the Eucla Basin.Crossref | GoogleScholarGoogle Scholar |
Cookson IC (1950) Fossil pollen grains of Proteaceous type from Tertiary deposits in Australia. Australian Journal of Scientific Research, Series B: Biological Sciences 3, 166–177.
| Fossil pollen grains of Proteaceous type from Tertiary deposits in Australia.Crossref | GoogleScholarGoogle Scholar |
Cookson IC, Duigan SL (1950) Fossil Banksieae from Yallourn, Victoria, with notes on the morphology and anatomy of living species. Australian Journal of Scientific Research, Series B: Biological Sciences 3, 133–165.
| Fossil Banksieae from Yallourn, Victoria, with notes on the morphology and anatomy of living species.Crossref | GoogleScholarGoogle Scholar |
Crisp MD, Arroyo MTK, Cook LG, Gandolfo MA, Jordan GJ, McGlone MS, Weston PH, Westoby M, Wilf P, Linder HP (2009) Phylogenetic biome conservatism on a global scale. Nature 458, 754–756.
| Phylogenetic biome conservatism on a global scale.Crossref | GoogleScholarGoogle Scholar | 19219025PubMed |
Dudgeon MJ (1983) Eocene pollen of probable proteaceous affinity from the Yaamba Basin, central Queensland. Memoirs of the Association of Australasian Palaeontologists 1, 339–362.
Dunn RE, Strömberg CAE, Madden RH, Kohn MJ, Carlini AA (2015) Linked canopy, climate, and faunal change in the Cenozoic of Patagonia. Science 347, 258–261.
| Linked canopy, climate, and faunal change in the Cenozoic of Patagonia.Crossref | GoogleScholarGoogle Scholar | 25593182PubMed |
Ellis B, Johnson KR (2013) Comparison of leaf samples from mapped tropical and temperate forests: implications for interpretations of the diversity of fossil assemblages. Palaios 28, 163–177.
| Comparison of leaf samples from mapped tropical and temperate forests: implications for interpretations of the diversity of fossil assemblages.Crossref | GoogleScholarGoogle Scholar |
Ferguson DK, Lee DE, Bannister JM, Zetter R, Jordan GJ, Vavra N, Mildenhall DC (2010) The taphonomy of a remarkable leaf bed assemblage from the Late Oligocene – Early Miocene Gore Lignite measures, southern New Zealand. International Journal of Coal Geology 83, 173–181.
| The taphonomy of a remarkable leaf bed assemblage from the Late Oligocene – Early Miocene Gore Lignite measures, southern New Zealand.Crossref | GoogleScholarGoogle Scholar |
George AS (1981) The genus Banksia L.f (Proteaceae). Nuytsia 3, 239–473.
George AS (1999a) Banksia. In ‘Flora of Australia, Vol. 17B. Proteaceae 3, Hakea to Dryandra’. (Ed. A Wilson) pp. 175–250. (ABRS: Canberra and CSIRO Publishing: Melbourne, Vic)
George AS (1999b). Dryandra. In ‘Flora of Australia, Vol. 17B. Proteaceae 3, Hakea to Dryandra’. (Ed. A Wilson) pp. 251–363. (ABRS: Canberra and CSIRO Publishing: Melbourne, Vic.)
George AS (2014) The case against the transfer of Dryandra to Banksia (Proteaceae). Annals of the Missouri Botanical Garden 100, 32–49.
| The case against the transfer of Dryandra to Banksia (Proteaceae).Crossref | GoogleScholarGoogle Scholar |
Glasspool IJ, Scott AC (2010) Phanerozoic concentrations of atmospheric oxygen reconstructed from sedimentary charcoal. Nature Geoscience 3, 627–630.
| Phanerozoic concentrations of atmospheric oxygen reconstructed from sedimentary charcoal.Crossref | GoogleScholarGoogle Scholar |
Greenwood DR (1996) Eocene monsoon forests in Central Australia? Australian Systematic Botany 9, 95–112.
| Eocene monsoon forests in Central Australia?Crossref | GoogleScholarGoogle Scholar |
Greenwood D, Christophel D (2005) The origins and Tertiary history of Australian ‘tropical’ rainforests. In ‘Tropical rainforests: past, present and future’. (Eds E Bermingham, CW Dick, C Moritz) pp. 336–373. (University of Chicago Press: Chicago, IL, USA)
Harris WK (1971) Tertiary stratigraphic palynology, Otway Basin. In ‘The Otway Basin of southeastern Australia’. (Eds H Wopfner, JG Douglas) pp. 67–87. (Geological Survey of South Australia and Geological Survey of Victoria: Adelaide, SA)
He T, Lamont BB, Downes KS (2011) Banksia born to burn. New Phytologist 191, 184–196.
| Banksia born to burn.Crossref | GoogleScholarGoogle Scholar | 21388378PubMed |
Hill RS (1986) Lauraceous leaves from the Eocene of Nerriga, New South Wales. Alcheringa 10, 327–351.
| Lauraceous leaves from the Eocene of Nerriga, New South Wales.Crossref | GoogleScholarGoogle Scholar |
Hill RS (1998) Fossil evidence for the onset of xeromorphy and scleromorphy in Australian Proteaceae. Australian Systematic Botany 11, 391–400.
| Fossil evidence for the onset of xeromorphy and scleromorphy in Australian Proteaceae.Crossref | GoogleScholarGoogle Scholar |
Hill RS, Brodribb TJ (2001) Macrofossil evidence for the onset of xeromorphy in Australian Casuarinaceae and tribe Banksieae (Proteaceae). Journal of Mediterranean Ecology 2, 127–136.
Hill RS, Christophel DC (1988) Tertiary leaves of the tribe Banksieae (Proteaceae) from south-eastern Australia. Botanical Journal of the Linnean Society 97, 205–227.
| Tertiary leaves of the tribe Banksieae (Proteaceae) from south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Hou B, Frakes LA, Sandiford M, Worrall L, Keeling J, Alley NF (2008) Cenozoic Eucla Basin and associated palaeovalleys, southern Australia – climatic and tectonic influences on landscape evolution, sedimentation and heavy mineral accumulation. Sedimentary Geology 203, 112–130.
| Cenozoic Eucla Basin and associated palaeovalleys, southern Australia – climatic and tectonic influences on landscape evolution, sedimentation and heavy mineral accumulation.Crossref | GoogleScholarGoogle Scholar |
Hyland BPM (1989) A revision of Lauraceae in Australia (excluding Cassytha). Australian Systematic Botany 2, 135–367.
| A revision of Lauraceae in Australia (excluding Cassytha).Crossref | GoogleScholarGoogle Scholar |
Jordan GJ, Hill RS (1991) Two new Banksia species from Pleistocene sediments in western Tasmania. Australian Systematic Botany 4, 499–511.
| Two new Banksia species from Pleistocene sediments in western Tasmania.Crossref | GoogleScholarGoogle Scholar |
Jordan GJ, Dillon RA, Weston PH (2005) Solar radiation as a factor in the evolution of scleromorphic leaf anatomy in Proteaceae. American Journal of Botany 92, 789–796.
| Solar radiation as a factor in the evolution of scleromorphic leaf anatomy in Proteaceae.Crossref | GoogleScholarGoogle Scholar | 21652458PubMed |
Jordan GJ, Weston PH, Carpenter RJ, Dillon RA, Brodribb TJ (2008) The evolutionary relations of sunken, covered, and encrypted stomata to dry habitats in Proteaceae. American Journal of Botany 95, 521–530.
| The evolutionary relations of sunken, covered, and encrypted stomata to dry habitats in Proteaceae.Crossref | GoogleScholarGoogle Scholar | 21632378PubMed |
Korasidis VA, Wallace MW, Wagstaff BE, Hill RS (2019) Evidence of fire in Australian Cenozoic rainforests. Palaeogeography, Palaeoclimatology, Palaeoecology 516, 35–43.
| Evidence of fire in Australian Cenozoic rainforests.Crossref | GoogleScholarGoogle Scholar |
Lamont BB, Connell SW (1996) Biogeography of Banksia in south-western Australia. Journal of Biogeography 23, 295–309.
| Biogeography of Banksia in south-western Australia.Crossref | GoogleScholarGoogle Scholar |
Lamont BB, He T (2017) When did a Mediterranean-type climate originate in southwestern Australia? Global and Planetary Change 156, 46–58.
| When did a Mediterranean-type climate originate in southwestern Australia?Crossref | GoogleScholarGoogle Scholar |
Mack CL, Milne LA (2015) Eocene palynology of the Mulga Rocks deposits, southern Gunbarrel Basin, Western Australia. Alcheringa 39, 444–458.
| Eocene palynology of the Mulga Rocks deposits, southern Gunbarrel Basin, Western Australia.Crossref | GoogleScholarGoogle Scholar |
Mack CL, Milne LA (2016) New Banksieaeidites species and pollen morphology in Banksia. Australian Systematic Botany 29, 303–323.
| New Banksieaeidites species and pollen morphology in Banksia.Crossref | GoogleScholarGoogle Scholar |
Macphail MK (1996) Palynostratigraphy of the Murray-Darling Basin, inland Southeastern Australia. Australian Geological Survey Organisation Record 1996, 1–38.
Macphail MK (1999) Palynostratigraphy of the Murray Basin, inland southeastern Australia. Palynology 23, 197–240.
| Palynostratigraphy of the Murray Basin, inland southeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Macphail MK (2007) ‘Australian palaeoclimates: Cretaceous to Tertiary – a review of palaeobotanical and related evidence to the year 2000.’ (Cooperative Research Centre for Landscape Environments and Mineral Exploration: Canberra)
Macphail MK, Alley NF, Truswell EM, Sluiter IRK (1994) Early Tertiary vegetation: evidence from spores and pollen. In ‘History of the Australian vegetation: Cretaceous to Recent’. (Ed. RS Hill) pp. 189–261. (Cambridge University Press: Cambridge, UK)
Martin ARH (1982) Proteaceae and the early differentiation of the central Australian flora. In ‘Evolution of the flora and fauna of arid Australia’. (Eds WR Barker, PJ Greenslade) pp. 77–83. (Peacock Publications: Adelaide, SA)
Martin ARH (1995) Palaeogene proteaceous pollen and phylogeny. Alcheringa 19, 27–40.
| Palaeogene proteaceous pollen and phylogeny.Crossref | GoogleScholarGoogle Scholar |
Mast AR (1998) Molecular systematics of subtribe Banksiinae (Banksia and Dryandra; Proteaceae) based on cpDNA and nrDNA sequence data: implications for taxonomy and biogeography. Australian Systematic Botany 11, 321–342.
| Molecular systematics of subtribe Banksiinae (Banksia and Dryandra; Proteaceae) based on cpDNA and nrDNA sequence data: implications for taxonomy and biogeography.Crossref | GoogleScholarGoogle Scholar |
Mast AR, Givnish TJ (2002) Historical biogeography and the origin of stomatal distributions in Banksia and Dryandra (Proteaceae) based on their cpDNA phylogeny. American Journal of Botany 89, 1311–1323.
| Historical biogeography and the origin of stomatal distributions in Banksia and Dryandra (Proteaceae) based on their cpDNA phylogeny.Crossref | GoogleScholarGoogle Scholar | 21665734PubMed |
Mast AR, Thiele K (2007) The transfer of Dryandra R.Br. to Banksia L.f. (Proteaceae). Australian Systematic Botany 20, 63–71.
| The transfer of Dryandra R.Br. to Banksia L.f. (Proteaceae).Crossref | GoogleScholarGoogle Scholar |
McGowran B, Archer M, Bock P, Darragh TA, Godthelp H, Hageman S, Hand SJ, Hill R, Li Q, Maxwell PA, McNamara KJ, Macphail M, Mildenhall D, Partridge AD, Richardson J, Shafik S, Truswell EM, Warne M (2000) Australasian palaeobiogeography: the Palaeogene and Neogene record. Memoirs of the Association of Australasian Palaeontologists 23, 405–470.
McLoughlin S, Hill RS (1996) The succession of Western Australian Phanerozoic floras. In ‘Gondwanan heritage: past, present and future of the Western Australian biota. Proceedings of the conference on systematics, evolution and conservation of the Western Australian biota. Perth, WA’. (Eds SD Hopper, JA Chappill, MS Harvey, AS George) pp. 61–80. (Surrey Beatty: Sydney)
McLoughlin S, McNamara K (2001) ‘Ancient floras of Western Australia’. (Western Australian Museum: Perth, WA)
Metcalfe CR, Chalk L (1979) ‘Anatomy of the dicotyledons. Vol 1. Systematic anatomy of leaf and stem, with a brief history of the subject.’ (Clarendon: Oxford, UK)
Milne LA (1981) Palynology of Eocene sediments from near the Fraser Range, Western Australia: a preliminary study. Honours thesis, University of Western Australia, Perth, WA.
Milne LA (1988) Palynology of a late Eocene lignitic sequence from the western margin of the Eucla Basin, Western Australia. Memoirs of the Association of Australasian Palaeontologists 5, 285–310.
Milne LA (1994) Relationship between Propylipollis annularis (Tertiary dispersed pollen) and extant Xylomelum (Proteaceae). In ‘Ultrastructure of fossil spores and pollen’. (Eds MH Kurmann, JA Doyle) pp. 193–214. (The Royal Botanic Gardens, Kew: London)
Milne LA (1997) Palynology of selected extant Proteaceae and Eocene palynofloras of Western Australia. PhD thesis, University of Queensland, Brisbane, Qld.
Milne LA (1998) Tertiary palynology: Beaupreaidites and new Conospermeae (Proteoideae) affiliates. Australian Systematic Botany 11, 553–603.
| Tertiary palynology: Beaupreaidites and new Conospermeae (Proteoideae) affiliates.Crossref | GoogleScholarGoogle Scholar |
Olde PM, Marriott NR (2002) One new Banksia and two new Grevillea species (Proteaceae: Grevilleoideae) from Western Australia. Nuytsia 15, 85–99.
Partridge AD (1976) The geological expression of eustacy in the early Tertiary of the Gippsland Basin. APEA Journal 16, 73–79.
| The geological expression of eustacy in the early Tertiary of the Gippsland Basin.Crossref | GoogleScholarGoogle Scholar |
Partridge AD (2006) Late Cretaceous–Cenozoic palynology zonations Gippsland Basin. In ‘Australian Mesozoic and Cenozoic palynology zonations – updated to the 2004 geologic time scale’. (Co-ordinated by E. Monteil) Geoscience Australia Record 2006/23. (Australian Government: Canberra)
Pole M (2007) Lauraceae macrofossils and dispersed cuticle from the Miocene of southern New Zealand. Palaeontologia Electronica 10, 38
Sauquet H, Weston PH, Anderson CL, Barker NP, Cantrill DJ, Mast AR, Savolainen V (2009) Contrasted patterns of hyperdiversification in Mediterranean hotspots. Proceedings of the National Academy of Sciences of the United States of America 106, 221–225.
| Contrasted patterns of hyperdiversification in Mediterranean hotspots.Crossref | GoogleScholarGoogle Scholar | 19116275PubMed |
Scott AC (2000) The Pre-Quaternary history of fire. Palaeogeography, Palaeoclimatology, Palaeoecology 164, 281–329.
| The Pre-Quaternary history of fire.Crossref | GoogleScholarGoogle Scholar |
Sniderman JMK, Woodhead JD, Hellstrom J, Jordan GJ, Drysdale RN, Tyler JJ, Porch N (2016) Pliocene reversal of late Neogene aridification. Proceedings of the National Academy of Sciences of the United States of America 113, 1999–2004.
| Pliocene reversal of late Neogene aridification.Crossref | GoogleScholarGoogle Scholar |
Solereder H (1908) ‘Systematic anatomy of the dicotyledons. 2. Monochlamydeae (English edn).’ (Clarendon Press: Oxford, UK)
Specht RL (1979) Heathlands and related shrublands of the world. In ‘Ecosystems of the world. Volume 9A. Heathlands and related shrublands: descriptive studies’. (Ed. RL Specht) pp. 1–18. (Elsevier Scientific: Amsterdam)
Specht RL (1981) The water relations of heathlands: seasonal waterlogging. In ‘Ecosystems of the world. Volume 9B. Heathlands and related shrublands: analytical studies’. (Ed. RL Specht) pp. 99–106. (Elsevier Scientific: Amsterdam)
Specht RL, Specht A (1999) Waterlogging. In ‘Australian plant communities: dynamics of structure, growth and biodiversity’. pp. 263–276. (Oxford University Press: South Melbourne)
Stevenson J, Hope G (2005) A comparison of late Quaternary forest changes in New Caledonia and northeastern Australia. Quaternary Research 64, 372–383.
| A comparison of late Quaternary forest changes in New Caledonia and northeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Stimpson ML, Weston PH, Telford IRH, Bruhl JJ (2012) First instalment in resolution of the Banksia spinulosa complex (Proteaceae): B. neoanglica, a new species supported by phenetic analysis, ecology and geography. PhytoKeys 14, 57–80.
| First instalment in resolution of the Banksia spinulosa complex (Proteaceae): B. neoanglica, a new species supported by phenetic analysis, ecology and geography.Crossref | GoogleScholarGoogle Scholar |
Stimpson ML, Bruhl JJ, Weston PH (2014) Could this be Australia’s rarest Banksia? Banksia vincentia (Proteaceae), a new species known from fourteen plants from south-eastern New South Wales, Australia. Phytotaxa 163, 269–286.
| Could this be Australia’s rarest Banksia? Banksia vincentia (Proteaceae), a new species known from fourteen plants from south-eastern New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |
Stover LE, Partridge AD (1973) Tertiary and Late Cretaceous spores and pollen from the Gippsland Basin, southeastern Australia. Proceedings of the Royal Society of Victoria 85, 237–286.
Thiele K, Ladiges PY (1996) A cladistic analysis of Banksia (Proteaceae). Australian Systematic Botany 9, 661–733.
| A cladistic analysis of Banksia (Proteaceae).Crossref | GoogleScholarGoogle Scholar |
Thiele KR, Weston PH, Mast AR (2015) Paraphyly, modern systematics and the transfer of Dryandra into Banksia (Proteaceae): a response to George. Australian Systematic Botany 28, 194–202.
| Paraphyly, modern systematics and the transfer of Dryandra into Banksia (Proteaceae): a response to George.Crossref | GoogleScholarGoogle Scholar |
Watson RW (1942) The effect of cuticular hardening on the form of epidermal cells. New Phytologist 41, 223–229.
| The effect of cuticular hardening on the form of epidermal cells.Crossref | GoogleScholarGoogle Scholar |
Weston PH (2014) What has molecular systematics contributed to our knowledge of the plant family Proteaceae? In ‘Molecular plant taxonomy: methods and protocols. Methods in molecular biology. Vol. 1115’. (Ed. P Besse) pp. 365–397. (Springer: New York)
Wilf P, Escapa IH (2015) Green Web or megabiased clock? Plant fossils from Gondwanan Patagonia speak on evolutionary radiations. New Phytologist 207, 283–290.
| Green Web or megabiased clock? Plant fossils from Gondwanan Patagonia speak on evolutionary radiations.Crossref | GoogleScholarGoogle Scholar | 25441060PubMed |
Zachos JC, Dickens GR, Zeebe RE (2008) An early Cenozoic perspective on greenhouse warming and carbon-cycle dynamics. Nature 451, 279–283.
| An early Cenozoic perspective on greenhouse warming and carbon-cycle dynamics.Crossref | GoogleScholarGoogle Scholar | 18202643PubMed |