: Modern Pollen Deposition Under Vegetation of the Blue Mountains, New South Wales Jane M. Chalson' and Helene A. Martin^ ' 46 Kilmarnock St. Engadine, N.S.W. 2233 -School ofBiological, Environmental and Earth Sciences, University ofNew South Wales, SydneyAustralia 2052 ([email protected]) Chalson, J.M. and Martin H.A. (200x). Modem pollen deposition undervegetation ofthe Blue Mountains, New South Wales. Proceedings oftheLinnean SocietyofNewSouth Wales 130, 111-137. Pollenwasextractedfromsurfacesamplesofswampsedimentsandsoilsundervarioustypesofvegetation in the catchments ofthese swamps. The pollen assemblages in these surface samples were compared with the floristic composition of the vegetation to provide a means of interpreting the assemblages of fossil pollen retrieved from the swamp sediments. Thesurfacepollenassemblagesreilectedthelocalvegetation,indicatingmore/lesstreecover,swampand/ oradjacent drylandenvironment andlocal floradiversity.All theevidence pointedto very local deposition andlittle longdistance dispersal ofpollen.Anumberofdifferentunitsmaybedefinedwithinthe onemajor vegetationtype, dry sclerophyll forest/woodlandinthis case,butthefloristics ofthe units aretoo similarto allow discrimination ofthem from theirmodempollen assemblages. Manuscript received21 May 2008, accepted forpublication 17 December2008. KEYWORDS: Blue Mountains, local pollen deposition, long distancepollendispersal, modempollen deposition, pollen spectra. INTRODUCTION THE STUDY SITES Pollen is deposited in sediments by the The Blue Mountains are a deeply dissected contemporaneous vegetation, but a number offactors plateau rising from the Cumberland Plain in the affecttherepresentationofeachtaxoninthesediments east. The plateau surface is undulating and small so that it is not possible to relate a fossil pollen creeks form upland valleys. Where the underlying assemblage in a deposit directly to the vegetation rock type is Hawkesbury Sandstone, the upland that produced it. Pollen productivity, dispersal and valleys become incised and develop into V-shaped preservation are the main factors that influence gorges. In the west where rock type is Banks Wall representation of a taxon, and each of these factors sandstone, the valley sides and floors slope gently are in turn influenced by the local environmental and the streams flow through a series ofswamps conditions. Pollen deposited from under known plant (Chalson, 1991). communities, however, may be used to characterize The swamps chosen for study are as follows that community and hence assist in the interpretation (see Fig. 1) and the species found at each site are ofpollen spectra recovered from swamp sediments. listed inAppendix 1 The nature of pollen deposition of individual taxa may also be deduced from the surface pollen spectra. Burralow Creek Swamp at 33° 32'S, 150° 38'E and , Sites for a study ofthe history ofthe vegetation 310-330maltitude,isanarrowswampthatfollowsthe were chosen from swamps in an altitudinal sequence creek for some 3.5 km. The upper end ofthe swamp intheBlueMountains (Fig. 1).These sitesaresituated is 2 km southeast ofKurrajong Heights. The core site on a relatively uniform substrate, sandstone, within is 1 km downstream from the northern end. There are dry sclerophyll woodland/open forest. Observations few cleared areas near the swamp, the nearest being of modem pollen deposition are reported in this over 2 km away. paper, and the Holocene history of the vegetation The vegetation around Burralow Creek is open from the swamps is reported in Chalson and Martin forest, woodland and swamps (Keith and Benson, (this volume). r MODERN POLLEN DEPOSITION IN THE BLUE MOUNTAINS 33° 15'- • / ^. Lithgow 33° 30' - ' Kurrajong. ^^^ CrBeuerkraSlwo.w^. ^. : \ Mt. Victoria J^,^^ r,,, W Blacl^heatliy MedlowBath-i / #/ "^ "\ J LawsonSpriJn'tgw^ood # Pennth iw^°"''^^ ^^^^ ^ Katoomba S;;;^^^-^ Nyrr^^p^^ - ^ ^^tv,aTi,"bJw°.° .^s^^m^ 33° 45' Murphys Glen ' "" Kings -- IngarSw. Glenbrook ~* Jenolan R. Tablelands Sw. »_. Notts Sw Warragamba Dam y) ^ — — -p 150° 00' 15' 30' 150° 45' { >lr Swamp, this study Scale 15 km N - s- ^-* Road i)^ other study site Urban area A Other surface sample Figure 1. Locality map 1988). Angophora bakeri, A. costata, Corymbia Warrimoo Oval Swamp at 33° 43' 21.44"S, 150° 36' , m eximia. Eucalyptus eugenioides, E. multicaulis, E. 58.35"E and 190-200 altitude, is approximately 1.5 pauciflora and E. radiata are locally dominant with km east of Warrimoo Post office and 0.4 km south a few kilometers of the swamp. The surface of the ofWarrimoo Oval. There are substantial urban areas swamp supports an open heathland ofLeptospermum within a kilometer ofthe swamp and weed invasion polygalifolium, L. trinervium and Eleocharis is considerable. sphacelata. Nomenclature follows Harden (1992; The vegetation is mainly woodland with 1993; 2000; 2002) and PlantNet (2006) some open forest and swamp communities (Keith and Benson, 1988). Locally, Angophora bakeri. 112 Proc. Linn. Soc. N.S.W., 130, 2009 CHALSON AND MARTIN J.M. H.A. Eucalyptus pauciflora and E. radiata are dominant. BanksiaserrataandHakeateretifolia. The dominants The swamp surface supports an open heathland with on the swamp are Leptospermumjuniperinum andL. Leptospermum spp. grandiflorum. Notts Swamp, at 33° 48' 35.44" S, 150° 24' 27.66" Katoomba Swamp, at 33° 43' 03" S, 150° 19' 18" E E and about 682 m altitude is approximately 12 km and950maltitude,is 1 kmeastnortheastofKatoomba south-southeast ofWentworth Falls andto the west of Post Office and 1 km west ofLeura Post Office. This Notts Hill. The lower third ofthe swamp is used as a swamp is surrounded byurban activity, with drainage market garden, but there is no sign ofdisturbance or ditches and a sealed road running across the swamp. weed invasion atthe study site. There is no indication Much ofthe swamp is (orhas been) used foryards for of European activities in the catchment upstream of light industry and horse paddocks. Housing extends the study site andthe nearest settlement is some 7 km to the edge ofthe swamp. to the north-northeast. Most of the area around the swamp has been The major plant community is open woodland cleared but there are a few remnant pockets of and there is a little open forest and some swamps Sandstone Plateau Forest (Keith and Benson, 1988) (Keith and Benson 1988). Eucalyptus eugenioides, E. remaining. Eucalyptus acmenoides, E. oreades, E. multicaulis, E. piperita, E. racemosa and E. sieberi stellulata, E. oblongata and E. sieberi are dominant. are locally dominant. The swamp supports a closed The understorey is problematic as the remnant stands sedgeland of Gymnoschoenus sphaerocephalus, are heavily weed infested. Leptospermum trinervium andBaloskion australe. Little remains of the original vegetation over the swamp surface and species of Poaceae are Ingar Swamp, at 33° 46' 11.65" S, 150° 27' 22.92" E predominant.Asmallpatchofswampedgevegetation and 584m altitude, is approximately 8 km southeast forms a dense thicket ofLeptospermumjuniperinum of Lawson. European settlement is some five km to andL. scoparium. the northeast, along the highway, and includes some very large, old conifertrees. Newnes Swamp at 33° 22' 57" S,150° 13' 20" E and , m The vegetation is mainly woodland with 1,060 altitude, is within a forestry area with pine Corymbia gummifera, Eucalyptus oblongata, E. plantations. Regularburning maintains fire breaks. piperita, E. pauciflora, and Angophora costata Woodland communities are found around the dominant locally. Open forest in gorges along swamp (Benson and Keith, 1990) but the shrub layer the creeks is dominated by E. eugenioides, E. has been much reduced by frequent burning. Shrubs sclerophylla, Tristania neriifolia and Angophora remaining on the swamp include Leptospermum costata. The swamp community is aclosed sedgeland trinervium andGrevilleaacanthifolia.Agroundcover of Gymnoschoenus sphaerocephalus, Leptocarpus ofgrasses is found in all but the wettest areas where tenax, Baumea sp., Chorizandra sp., Baloskion Juncaceae and Restionaceae are domiriant. australe and, towards the edge, Hakea teretifolia, H. dactyloides andLeptospermum lanigerum. METHODS KingsTablelands at33° 45'47" S. 150°22'43"Eand Thevegetationunits ateach siteweredetermined , about 780-790 m altitude, is located in small valley from maps in Benson (1992), Keith and Benson offQueen Victoria Creek. It is about 0.6 km east of (1988) and Benson and Keith (1990). Each site was Queen Victoria Memorial Hospital near Wentworth visited, the vegetation checked with the maps and as Falls. An urban area is found less than 1 km to the many species as possible were identified in each of west where exotic conifers have been planted in the the vegetation units. Since palynology cannot reveal gardens. the structure of the vegetation, the focus of survey The vegetation is mainly open forest around the was on the species list. Dominance was determined study site, with woodland on the ridges and closed subjectively from the abundance ofthe species sedgelands in the swamps (Keith and Benson, 1988). Samples from the surface of the soil, or where Locally, Eucalyptus dives, E. oreades, E. sieberi possible, from moss polsters, were collected from the and E. piperita are dominant in the open forest and centre of the swamp, the swamp edge and the plant Corymbiagummifera, E. racemosa andE. sieberi are communities adjacent or local to, the swamp sites. dominant in the woodland. On the exposed plateau Samples were taken from at least 100 m away from to the northeast, the dominants in an open heathland community boundaries where possible. The sample are Allocasuarina distyla, E. ligustrina, E. stricta, types and vegetation are listed in Table 1 and the Proc. Linn. Soc. N.S.W., 130, 2009 113 MODERN POLLEN DEPOSITION IN THE BLUE MOUNTAINS Table 1 Surface samples used for pollen spectra presented in Figs 2 and 3. Codes for vegetation map units are from Keith and Benson (1988). Surface Vegetation sample no. Vegoetation map unit Sample material Burralow Creek 1 Open sedgeland mid-swamp 28a Soil 2 Open sedgeland mid-swamp 28a cm core 3 Swamp fringe 28a Soil 4 Low Woodland lOar Soil 5 Open forest lOag Soil Warrimoo Oval 6 Closed sedgeland mid-swamp 26a Soil 7 Closed sedgeland mid-swamp 26a cm core 8 Closed sedgeland swamp fringe 26a Soil 9 Low woodland lOar Soil Notts 10 Closed sedgeland mid-swamp 26a Soil 11 Closed sedgeland swamp fringe 26a Soil Ingar 12 Closed sedgeland mid-swamp 26a Soil 13 Closed sedgeland swamp fringe 26a Soil 14 Low woodland lOar Soil „.^Xow woodland lOar Soil 1^ Kings Tableland 16 Closed sedgeland mid-swamp 26a cm core 17 Closed sedgeland swamp fringe 26a Soil 18 Low woodland lOar Soil 19 Low woodland lOar Soil 20 Open forest 9i Soil 21 Open forest 9i Soil 22 Open heath 21f Soil Katoomba 23 Closed sedgeland mid-swamp 26a Soil 24 Closed sedgeland swamp fringe 26a Soil 25 Open forest 9i Soil 26 Open forest 9i Soil Newnes 27 Closed heath mid-swamp 20a Moss 28 Closed heath swamp fringe 20a Moss 29 Woodland 1Of/11a Moss 30 Woodland 1Of/1la Moss 31 Woodland 1Of/1la Soil 32 Woodland 1Of/1la Soil 33 Open heath 21d Soil 34 Open heath 21c Soil 35 Forest lOf Soil 36 Forest lOf Soil Murphys Glen 37 Tall open forest 6c Soil 38 Tall open forest 6c Soil Wolgan 39 Open woodland 11a Soil 40 Open woodland 11a Soil WoodNymphs Dell 41 Open forest lOag Soil Medlow Bath 42 Open forest 9i Soil 114 Proc. Linn. Soc. N.S.W., 130, 2009 CHALSON AND MARTIN J.M. H.A. study sites are shown in Fig. 1 highest count at Warimoo Oval Swamp is close to Six to ten sub-samples were taken from each substantial urban areas. Leptospermum/Baeckea has plant community over a transect ofapproximately 20 been identified from some swamp samples (Fig. 2A) m. The sub-samples were mixed together to reduce where counts may be considerable. Leptospermum the possible over-representation of any one species spp. are often dominant in the swamp communities duetocloseproximitytoanindividualplant(Chalson, (seeAppendix 1) 1991). The unidentified Myrtaceae group is larger than The samples were treated with hydrochloric and the other groups of Mytaceae and counts fi-om the hydrofluoric acidstoremove siliceous material (Birks swamp samples are the lowest of all. The woodland and Birks, 1980), oxidised with Schultz solution (a orforest samples from theborders ofthe swamp (Fig. saturated solution of potassium perchlorate in nitric 2A) all have higher counts than the swamp samples. acid), cleared in 10% potassium carbonate and the Frequencies in samples from the dry-land vegetation residue was mounted in glycerine jelly (Brown, (3A) are much higher than those from swamps. Lack 1960). of specific identification was generally due to poor Pollen was identified by comparing the grains preservation. with reference pollen treated with standard acetolysis Casuarinaceae frequencies are usually low, with (Moore et al., 1991). Grains were counted along a few higher values. The highest value (Fig. 3A) transects across the slides and tests showed that a comes from heathland vegetation. count of 140 grains adequately sampled the residues. Poaceae frequencies are generally low and the The counts of each pollen type were presented high values are associated with urbanisation and as percentages of the total count on the pollen disturbance (Katoomba, Fig. 2A). diagrams. Restionaceae fi-equencies are variable but most ofthe high values are found in the swamp samples. Cyperaceaehasnotbeenrecordedfrommanysamples, RESULTS andwhere it ispresent, irequencies are generally low, with the few higher firequencies being found in the Fig. 2 presentsthepollen spectrafiromvegetation swamp samples. on the swamp surface and at the edge ofthe swamp, Selaginella is present in a few samples and and Fig 3. presents spectra fi"om the dry-land appreciable firequencies may be recorded in some communities in the surrounding vegetation. Table 2 swamp samples. Gleichenia may be present in presentsthename onthepollen diagram, theprobable appreciable fi-equencies in some swamp samples source ofthe pollen in the vegetation and ecological also. Other fern spores are usually recorded in low inference. frequencies and are more common in the dry-land Preservation, although adequate, was not samples. good enough for the identification of Eucalyptus Table 2 also lists the likely environmental species beyond broad groups (Chalson and Martin, indication of the pollen groups on the diagrams, 1995). The pollen fi-om moss polsters may be better but this is difficult, given that a group may include preserved than that from the soil, but moss polsters many possible species. For example, the families were not common and usually dried out severely Restionaceae and Cyperaceae include both swamp in the forest environment, hence soil samples were and dry-land species, butthe species inthevegetation usually collected in all but the dampest areas. and patterns of high pollen frequencies on the Exotic Pinus is present in all samples (Figs 2A, diagrams may indicate the nature ofthe environment 3B) and values are highest at sites near urban areas when considered together. Thus the species of (Kings Tableland, Katoomba). Surprisingly, Pinus Restionaceae and Cyperaceae found in the local values are not high at Newnes, in the forestry area vegetation (Appendix 1) are almost entirely species with pine plantations, but the pines were very young ofswamps or damp places (Table 2). at the time ofthis study. Angophora/CorymbiaandEucalyptus/Melaleuca have been identified in low frequencies in some of DISCUSSION the samples which were better preserved. Melaleuca styphelioides has been identified in some of the There are many indications that the pollen swamp samples (Fig. 2A) where counts maybe high. recovered from the surface samples was M styphelioides was not found during the survey of produced mainly by the local vegetation and the vegetation, but it may be grown in gardens. The thus the pollen spectra can indicate the type of Proc. Linn. Soc. N.S.W., 130, 2009 115 MODERN POLLEN DEPOSITION IN THE BLUE MOUNTAINS (sj W w PCTOt -f6O. Mto ^ a> a> U3 CD --J OS w ro -*. crssi I IS eSn 0^> 5a. s£ n 3 g I I i: § I I S. 3 II n^ jTT' "I I 1 ~'^.'-^* O -^^ -p-^ -rj ^r roe -^''-^S?^ '^C'^ &3 ^^^^n 3 =^ z Tx 3 ^ So"- fmR — 0) in 3 5* CO «3« roBs 3 0eIB5r c3mr T&=3)3 3&> f»T 3B 3 Q. C/3 3 sr &s9 np^ 3 a. 1/1 » aV3 yj <o/) nn <n n r-T-r 3 M 1 I ' ''^'^^r. ^^e. ft Q, '^e TT T~t~pT TT *^. "5© 8 to 3 I ft :$ — S ~r~r "pT "~^ T H? = "I I '^'O",?a% '3e ft ^ -j . - C", X %« s. 3 '«-%6. '/A'©>& ore TT %; o '<^< '-s'-'^,-& -% -TT '®r I ! I 1 «/•/, '^AS;"e* 116 Proc. Linn. Soc. N.S.W., 130, 2009 1 ) J.M. CHALSON AND H.A. MARTIN # Scale 20%oftotalcount .# r-6/# ^ #JP /rf <? #^^ //// <If <#fJ*#^ <^^ / o=^1^/,^ /.^ i# ^ ^ # ^ ^i^" <&" Q*' <?" ^« ^^ ;e ce cJ T T O- 1 * I Blrralow Creek Swamp 1 Midswamp - . 2 Midswamp • • - . _ . I* 3 Swampedge ^ ^ 4 Woodland - - Warrimoo Ova Swamp 6 Midswamp h ^ - 7 Midswamp 1 . h 8 Swampedge 1^^ - 9 Woodland - • - Notts Swamp 10 Midswamp 1 Swampedge \l IngarSwamp 12 Midswamp 13 Swampedge 1 1 - I- pf Kings Tableland Swamp 1 J 18 Woodland , - * - 16 Midswamp > : • 17 Swampedge - . - 21 Forest - \ Katoomba Swamp 23 Midswamp , ^ 24 Swampedge i — 25 Forest » i K - • «- . , . \ - I Newnes Swamp 2287 SMiwdasmwpaemdpge ^1" 11 h r h- t » {1 29 'Atoodland u h • k - 1. 11- _ - Figure 2B. The pollen spectra from plant communities associated with swamps within low frequency taxa. The Sample number (extreme left hand side) refers to the sample in Table 1 vegetation from which it came. For example, the of Cyperaceae probably indicate swamps which are Myrtaceae pollen content (Figs. 2A, 3A), is lowest more permanently waterlogged than swamps with from swamp sites, intermediate from the dry-land high frequencies of Restionaceae. Both Selaginella communities bordering the swamps and highest from and Gleichenia are found in wet places, on the edge the woodland and forestsites away from the swamps, ofswamps and streams (PlantNet, 2007). thus inferring a parallel approximate tree cover. The pollen of sclerophyllous shrub taxa (Figs Swamp samples contain much higher pollen 2B, 3B) are usually found sporadically and in very frequencies of Restionaceae and/or Cyperaceae than low frequencies, indicating under-representation and the dry-land sites, although both of these families very localised distribution. contain swamp and dry-land species. The species of These findings are in accord with other studies Restionaceaerecorded inthevegetation (Appendix 1 of surface pollen assemblages which indicate very are foundonwetandpoorly drainedsoils andindamp localised distribution of pollen (Dodson, 1983; to wet heaths (PlantNet, 2007). Most of the species Kodela, 1990). Kershaw and Strickland (1990) found ofCyperaceae, on the other hand, are found in fresh that, in a 10 year pollen trapping experiment, most m water swamps and swampy areas (Sainty and Jacobs, pollen came from within 10 ofthe trap. 1981; PlantNet, 2007), although one dry-land species These study sites are all contained within small is also recorded (Appendix 1). Thus high frequencies valleys where some barrier impedes drainage of the Proc. Linn. Soc. N.S.W., 130, 2009 117 1 MODERN POLLEN DEPOSITION IN THE BLUE MOUNTAINS -r-T-T T "T~r rr T "H" '^l '<^S a- L 0) o •o«D g aO TO9» oOo o - 3 O 3 ' 3 3 ' a- »/'^*4 •on . 3 S" oS 3 5= - '''^'«. *«*'C>* n 3 i o o <5. '<::, A 3 -OA fi) H 0) '^.'% ro p. M A « pr T-r~T -^^^% ^ '^. nr M T -f -^-r- < ^°^. I '^.'% X T r T-n- -T—T- ' ' 1 ''^o *© "^ T ~~^-7 "I I I n r r— .... ,' , ^ 'e^/ =^'"/?.. ^^. ''©.. 6r3e0 os' re" (3a ^S3.-r&e^< 3h"r*l o 3 s -a 9 re ^ TS rf 3 3 Q, I— C C 0000 (S^ re O3" 2^ -ss -ofl w> n re o "1 &":1< a re re 1^ re § "-5 V) J1? o ^ ??> SB « 3 Tr3t"- o1^. -2Sr§3e "? re r<e T ^ 3 S r3t"- TrOe Vrel HH-Nrt=3* g2re IsaS r&e9 &3i i re rt- re t« I Proc. Linn. Soc. N.S.W., 130, 2009 118 CHALSON AND MARTIN J.M. H.A. Scale 20%oftotalcount ^"^ >^^ i # P ^^ -^ S> ^ ^ Jj Woodland lOar 4 9 14 IS- IS Woodland 10f/11a 29- rr 30- 31 - 32- [ OpenWoodland 11a 39- i r 40- \ V Open forest lOag 5 ' ^ — 41 : \ 1 \ Open forest 91 _ — 42 - r r 18 20 - - - ; 25 — 26 L - ^ 1 f* Tall Open Forest 6c 35- r l[ 36 h - ! Open Forest lOf 37- !^ r 38 Open Heath 21f, 21d, 21c 22 -h- 33. Figure 3B. Pollen spectra associated with dry-land plant com- munities within low frequency taxa. 1 The sample number refers to the sample in Table 1. Codes for the vegetation map units are from Keith and Benson (1988) streamandmaintainsthe swamp (forafulldescription assemblage. Whilethismayhappen, ithasbeenfound ofthe sites, see Chalson and Martin, this volume). It that very little pollen is transported into the site so may be argued that pollen can be transported a long that the assemblage truly reflects the local vegetation distance by a stream, to be deposited with the local (Chmura and Liu, 1990). Proc. Linn. Soc. N.S.W., 130, 2009 119 MODERN POLLEN DEPOSITION IN THE BLUE MOUNTAINS Table 2. Pollen type name on the pollen diagrams (Figs 2, 3) and the probable source in the vegetation. Name on the pollen diagrams Probable source in the vegetation and ecological inference. 2A and 3A From Plantnet (2007) Podocarpus ProbablyPodocarpus spinulosus: sclerophyllous shrub/small tree Pinus Pinus sp(p), Introduced: Pollen input from urban/forestry areas. Angophora/Corymbia Species within the two genera: sclerophyll woodland Eucalyptus/Melaleuca Species within the two genera sclerophyll woodland/forest : Melaleucastyphelioides Melaleucastyphelioides: moist stream bank habitat Leptospermum/Baeckea Species within the two genera: ?mainly swamp communities Tristaniopsis Tristaniopsis spp moist habitats in sclerophyll communities : Unindetified Myrtaceae All pollen types not identifiable further Casuarinaceae Casuarina, Allocasuarina sp(p): A distyla and^. nana in this study Native and exotic species in the family: open situations, dryland Poaceae and swamp species Restionaceae All species in the family: swamp and dry land species Cyperaceae All species in the family: swamp and dry land species Selaginella All species in the genus: damp sites, edge ofswamp Gleichenia Gleichenia sp(p): damp sites, edge ofswamp Other fern spores Other ferns: many possible species Names on 2B and 3B Grevillea acanthifolia G. acanthifolia: sclerophyllous understorey Grevillea Grevillea sp(p): sclerophyllous understorey Hakea Hakea sp(p): sclerophyllous understorey Persoonia Persoonia sp(p): sclerophyllous understorey Symphionema montanum S. montanum: heath or dry sclerophyll forest Banksia Banksia sp(p): sclerophyllous understorey Proteaceae Othertaxa in the family sclerophyllous understorey Acacia All species in the genus Styphelia Styphelia sp(p): sclerophyllous understorey Monotoca Monotoca sp(p): sclerophyllous understorey Ericaceae Othertaxa in the family: sclerophyllous understorey Rutaceae All taxa in the family: sclerophyllous understorey Pimelea Pimelea sp(p): sclerophyllous understorey Plantago Plantago sp(p): native and introduced herbs Haloragis/Gonocarpus sp(p): Damp sites, sclerophyllous Haloragis understorey Asteraceae/Liguliflorae Fenestrate-grained taxa in the subfamily Liguliflorae: herbs Asteraceae/Tubuliflorae Echinate-grained taxa in the subfam. Tubuliflorae: shrubs and herbs Chenopodiaceae Ruderals, salt tolerant 120 Proc. Linn. Soc. N.S.W., 130, 2009