ATOLL RESEAFWH BULLETIN 
NO. 328 
ISSUED BY 
NATIONAL MUSEUM OF NATURAL HISTORY 
SMlTHSONIAN INSTITUTION 
WASHINGTON, D.C., U.S.A. 
October 1989 
VEGETATION OF HENDERSON ISLAND 
BY 
GUSTAV PAULAY ' AND T. SPENCER 
On the basis of field surveys from the north and north-west beaches, the vegetation of 
Henderson Island can be classified into 11 vegetation communities: 2 in littoral 
environments with sandy substrates, 4 on rocky coasts and 5 associated with the limestone 
plateau. Apart from the cutting of 'miro' wood by Pitcairn islanders, the communities are 
remarkably undisturbed, with only 5 adventive species recorded. Whereas the littoral 
communities are clearly differentiated into well-defined zones from shore to plateau, the 
island interior limestone forests ( canopy 5-8m, with an understorey of herbs and shrubs) 
show many combinations of species, resulting in a complex mosaic of forest types. 9 
species or varieties are presently recognised as  endemic to Henderson and all are 
primarily plants of the island's interior. 
The study of the vegetation communities of Henderson Island is of both great interest and 
importance. Henderson's vegetation is  of interest  in a regional context, first, 
biogeographically, because of the island's remoteness in the south-east Pacific Ocean 
(Fosberg 1984) and secondly, because its floristic composition reflects a relatively rare 
stage in the continuum of vegetation types, controlled by increasing elevation above sea 
level, from the motus of sea-level atolls to the 'high' islands of Polynesia constructed from 
both volcanic rocks and limestones (Sachet 1985). In addition, Henderson's vegetation is 
of great significance to the wider debate on the structure and function of island ecosystems 
both past and present. As a result of the island's isolation, unsuitability for sustained 
human habitation and lack of economic phosphate deposits, the vegetation of Henderson 
Island has survived Polynesian and successive Western impacts (with only 5 introduced 
plant species) and provides an almost unique glimpse of the natural vegetation cover of a 
former atoll and lagoon well-raised above present sea level (for classification of different 
emergent reef surfaces see Figure 1; Fosberg 1985a). Furthermore, the continued removal 
of the natural vegetation communities of fragile tropical island ecosystems makes the 
field study of locations such as  Henderson doubly important (Fosberg e t  al. 1983, Fosberg 
198513). 
I Department of Zoology, University of Washington, Seattle, WA98195, USA; present 
address: Department of Biology, University of North Carolina, Chapel Hill, NC27599-3280, 
USA. 
Department of Geography, University of Manchester, Manchester M13 9PL, UK; present 
address: Department of Geography, University of Cambridge, Cambridge CB2 3EN, UK. 
Uplifted islands are  also important because they offer a rare analogue for what  Pacific 
atolls may have been like during the  low sea stands t h a t  characterised much of the  
Pleistocene. As tectonic uplift took place in the relatively recent past (< 1.0 my ago, Spencer 
and Paulay, this  volume) a t  Henderson, the  island is especially appropriate a s  a model for 
atoll environments during low sea stands (mean duration of Pleistocene low sea levels - 
100 kyr; Shackleton and Opdyke 1976). Thus, for example, soil development on Henderson 
h a s  been poor by comparison with other  uplifted islands such a s  Niue, S.W.Pacific 
(Wright and van Westerndorp 1965) or the  makatea islands of the Southern Cook Islands 
(Wood and Hay 1970). Meagre soil development has  likely been the  result of both the  
recency of uplift and the  lack of source minerals other than  those available in limestone 
and humus. By contrast, fluvial inputs from the central volcanic highlands on Mangaia, 
S.Cook Islands (Wood and Hay 1970) and  atmospherically-sourced volcanic particles 
(likely to be ash;  Fieldes e t  al. 1960, Wright and van Westerndorp 1965) on Niue have 
contributed considerably to  pedogenesis on these islands. Henderson's lack of soil 
accumulation and  the  coarse coral rubble (see Spencer and Paulay, this  volume) which 
covers most of the  island, probably explain the low stature of the  vegetation, which rarely 
exceeds 10m in height. This  contrasts with much taller mature forests on other uplifted 
islands: thus, for example, the canopy of the primary forest of Niue i s  20-30m high (Sykes 
1970, pers. obs. G.P.). 
In this paper we consider aspects of vegetation (i) structure; (ii) function and adaptation; 
(iii) physiognomy; and (iv) floristic composition and ecological interactions. As such, i t  
complements the  published checklists of the  island's flora (St John and Philipson 1962, 
Fosberg et al. 1983, this volume). 
CLASSIFICATION OF VEGETATION COMMUNITIES 
Vegetation units  on Henderson Island can be broadly equated with topographic units  
andlor sedimentary environments. The following classification is proposed. 
A. LITTORAL VEGETATION 
(a) Sandy substrates 
1. Strand pioneer vegetation and seaward beachridge slope community 
2. Beachridge crest and back-barrier swale community 
(b) Rocky substrates 
3. Limestone platform community 
4. 'Miro' woodland community 
5. Limestone buttress and cliff face community 
6. Fern slopes community 
B. LIMESTONE PLATEAU MARGIN AND ISLAND INTERIOR VEGETATION 
7. Cliff top and plateau margin community 
8. Pinnacled-pitted limestone community 
9. Timonius scrub community 
10. Limestone glade woodland community 
11. Lagoonal patch reef community 
It should be stressed, however, that  this classification is empirical and strictly only applies 
to those areas of the island, primarily the north and north-west coasts, visited by the 1987 
expedition (for locations; see Spencer and Paulay, this volume). I t  is interesting to note that  
3 species (Asplenium lobulatum , Fimbristylis cymosa and Lycium carolinense var. 
sandwichense) only collected on one occasion, by D R Tait in 1912, are indicated by S t  John 
and Philipson (1972) as  being restricted to the South Point region. Whilst coral ledges and 
a reef flat dissipate wave attack on the north-western, northern and eastern shores, waves 
break directly onto the undercut cliffs of the south-western and south coasts with sea spray 
being thrown to heights above that  of the cliff margin under even moderate sea conditions. 
Thus  different ecological conditions prevail a t  the southern end of Henderson by 
comparison with the northern coasts. Even within the latter region field observations 
suggest that  there may be micro-climatic differences between neighbouring coasts; for 
example, the cliff face and plateau margin environments above the north-west beach 
appear to be moister than the corresponding areas on the north coast. One reflection of these 
differences may be the apparently much poorer epiphytic flora on the northern plateau; 
further differences are considered below. 
One of the great  problems in delimiting the different vegetation communities on 
Henderson Island is that  not only are they floristically diverse but also that  many species 
are present in more than one, and often several, different communities. The following 
species lists by community document all the species seen by us in each community; the 
accompanying text indicates which species make each community recognizable and adds 
information from the work of previous plant collectors. Nomenclature follows Fosberg e t  
al. (1983, and see also this volume). 
E S  ION OF VEGETATION COrVfMUNITlES 
k VEGETATION 
The littoral vegetation, defined as seaward of the plateau margin, has more diverse and 
clearly differentiated communities than the interior vegetation. This diversity and 
differentiation is  the result of a greater variation from shore to cliff top in elevation, 
substrate type, exposure to sea spray, and other microclimatic factors than are found in the 
island interior. The arrangement of most of this variation i s  normal to the coast, 
producing well-defined zones from shore to plateau. 
The most seaward community may be either on sandy substrates (1. Strand pioneer and 
seaward beachridge community: see below) especially along the north coast, or on solid 
limestone (3. Limestone platform community: see below) depending on local 
physiography. These shoreward communities consist of a few salt tolerant species. In their 
shelter follow more diverse woodland communities on gently sloping or level ground on 
sand (2. Beachridge crest and back-barrier swale community: see below) or on limestone 
rock and rubble (4. 'Miro' woodland community: see below). These latter communities 
include the most disturbed areas on Henderson. They serve as  camp-sites to visiting 
parties on the north and northwest beaches, most coconuts grow here, and miro (Thespesia 
populnea) is frequently cut. The transition from this littoral terrace to the plateau is via a 
mosaic of steep slopes and cliff faces that  bear low-lying, dense, species-rich covers (5. 
Limestone buttress and cliff face community; and 6. Fern slopes community: see below). 
1. Strand ~ ionee r  and seaward beachridge community 
The beaches of Henderson are of two types: the long, relatively broad beaches of the 
northern and eastern shores and small pocket beaches, typified by the north-west beach 
and the eastern sections of the north beach. The pocket beaches are characteristically 
backed by a bevelled limestone ramp and flanked by low limestone outcrops (see Spencer 
and Paulay, this volume); they support few plants. The north beach can be divided into a 
lower foreshore dominated by beachrock and poorly-sorted sands and an upper, planar 
beach, 15 - 25m in width. At the western end of this beach the limestone cliffs come right 
down to the shore and only locally are incipient, small sand dunes present between the 
limestones and the beach sands. These low sand sheets are characterised by clumps of the 
grass Lepturus repens. In the central section of the north beach a beachridge fronts a broad 
embayment in the limestone cliffs (see Spencer and Paulay, this volume for north beach 
plan). The dominant colonist on the seaward face of this beachridge, a t  -3.0 - 4.5m above 
sea level, is Scaevola sericea (Plate 1) with Heliotropium anomalum and Pemphis acidula 
being locally present. 
Shrubs: Pemphis acidula 
Scaevola sericea var. tuamotuensis 
Herb: Heliotropium anomalum var. argenteum 
Creeper: Triumfetta procumbens 
Grass: Lepturus repens 
2. Beachridge crest and back-barrier swale community 
At the Pitcairner's campsite on the north beach, the dominant vegetation on the beachridge 
crest is coconut plantation. To the west of this locality the beachridge supports an extensive 
cover of Tournefortia argentea both as a bushy ground cover and as gnarled trees, 3 - 4m 
high. Tournefortia is an opportunistic species characte~istic of marginal 
ground (Fosberg 1953) and is restricted t o  the littoral vegetation on Henderso 
latter may be an understorey of Polypodium sp(p). 
The area between the beachridge crest and the base of the limestone cliffs, reaching -30m 
in width on the central north beach, is clearly a zone of transition of both micro-climate 
and substrate. Pemphis acidula , common along the seaward margin, becomes noticeably 
absent as this zone is traversed. In the moist, shaded localities a t  some distance from direct 
marine influence, Procris pedunculata and the endemic Peperomia hendersonensis are 
particularly characteristic of this shrub-dominated community. 
Trees: 
Shrubs: 
Cocos nucifera 
Pandanus tectorius 
Thespesia populnea 
Tournefortia argentea 
Guettarda speciosa 
Scaevola sericea var. tuamotuensis 
Timonius polygama 
Tournefortia argentea 
Herbs: Peperomia hendersonensis 
Procris pendunculata 
Creeper: Ipomoea macrantha 
Grass: Thuarea involuta 
Ferns: Asplenium nidus 
Polypodium sp(p). 
3. Limestone ~ la t form community 
The limestone platform environment is dominated a t  its seaward margin by dense, 
monospecific stands of Pemphis (Plates 2 and 3), in a band usually less than 5m wide, and 
locally festooned by orange-green strings of Gassytha filiformis. The 'Pemphis forest' is a 
characteristic and permanent community of rocky shores on Central Pacific atolls 
(Fosberg 1953), as well as on other uplifted islands (pers. obs.; S.Cooks, Niue). The creeper 
Triumfetta procumbens is also found on the seaward margin of this community. 
Tree: Cocos nucifera 
Tournefortia argentea 
Shrub: Pemphis acidula 
Creepers: Gassytha filiformis 
Triumfetta procumbens 
4. 'Miro' woodland communitv 
Inland from the Pemphis zone, trees become established on the last interglacial limestone 
unit. At the southern end of the north-west beach an arlicularly a t  the eastern end of the 
north beach the 3 - 5m high canopy is dominated by miro, Thespesia populnea, with an 
understorey of Bolypodtum sp(p). Gaps in the canopy and the presence of numerous logs on 
the limestone substrate attest to the management of this community by the Pitcairn 
Islanders who crop miro for wood carving. The Thespesia logs are surrounded by a thick 
litter layer of Pandanus leaves and Polypodium fronds. Under the densest miro canopy, 
near the foot of the limestone buttress, Peperomia hendersonensis appears and becomes an 
abundant ground cover. At the same location occasional Timonius polygama and Procris 
pendunculata give their first appearance. The large coconut grove on the northwest beach 
dominates the canopy of the seaward half of this community. 
Trees: 
Shrub: 
Cocos nucifera 
Cordia subcordata 
Guettarda speciosa 
Bandanus tectorius 
Thespesia populnea 
Tournefortia argentea 
Timonius polygama 
Herbs: Peperomia hendersonensis 
Procris ped uncul ata 
Grass:  Thuarea involuta 
Creeper: Cassytha filiformis 
Ferns:  Asplenium nidus 
Polypodium sp(p). 
5. Limestone buttress and cliff face community 
Although there are individual trees of Celtis sp., Pisonia grandis and, particularly a t  
higher levels, Pandanus tectorius, the steep limestone faces are dominated by a close 
ground cover. At lower levels this may consist of low Timonius (Plate 4) tangle .but a t  
greater heights the cliffs are characterised by creeping herbs. Particularly noticeable is the 
way in which Sesuvium portulacastrum covers the outer floor of the highest (20.2 - 21.5m; 
see Spencer and Paulay, this volume), deepest and most laterally extensive of the marine 
notches on the limestone buttresses of the north shore, an association clearly seen from the 
north beach (Plate 2). The change from a low shrub to a herb assemblage appears t o  be 
correlated with a change in substrate from poorly sorted, sandy coral rubble t o  solid 
limestone. 
Trees:  
Shrubs: 
Herbs:  
Creepers: 
Ferns:  
Celtis sp. 
Pandanus tectorius 
Pisonia grand is 
Thespesia populnea 
Eugenia rariflora 
Timonius polygama 
Townefortia ai-gepzkea 
Euphoi-Aia spari-naaaii 
eliotropium anomalum var. argeateum 
Lzpidium bidentatum 
Sesuvium portulacastrum 
Boerhavia tetrandra 
Cassytha filifoi-mis 
Ipomoea macrantha 
Asplenium nidus 
Nephrolepsis hirsutula 
Polypodium sp(p). 
6. Fern s l o ~ e s  community 
Above the vegetation communities of the immediate coastal fringe and in between the high 
angle cliffs and limestone buttresses are slopes of 25 - 30? in angle up to the cliff top. This 
topographic unit is dominated by extensive stands of the ferns Polypodium sp(p). and 
Nephrolepsis hirsutula. Alternating and mixed with this fern cover, especially on the 
lower parts of the slope, are thickets of Timonius , forming a dense canopy - 1.5m high, 
draped with the parasitic Cassytha , and with the occasional emergent Eugenia rariflora 
reaching 2m. 
Shrubs: Eugenia rariflora 
Pisonia grandis 
Timonius polygama 
Creeper: Cassytha filiformis 
Ferns: Nephrolepsis hirsutula 
Polypodium sp(p). 
B. LIMESTONE PLATEAU MARGIN AND ISLAND INTERIOR VEGETATION 
In the simplest terns ,  the plateau interior of Henderson Island supports a limestone forest 
of large individual trees with a canopy a t  5 - 8m and a wide variety of herbs and shrubs 
beneath that canopy, the most remarkable being the tall Bidens hendersonensis (Fosberg 
1984). However, the way in which different species combine varies considerably across the 
island's surface. Some of these differences seem to be controlled by local geology. The 
island's interior is underlain by either jagged, pinnacled exposures of limestone or by 
flatter depressions, with fields of corals or areas of fragmented coral sticks, thought to 
represent a former atoll lagoon floor (Spencer and Paulay, this volume). Some areas of 
limestone bedrock may have no forest cover (8. Pinnacle-pitted limestone community: see 
below) or a low, tangled scrub vegetation (9.Timonius scrub community: see below). 
Similarly, a thick litter layer and pocket soils have developed over some lagoonal deposits, 
producing a distinctive limestone woodland (10. Limestone glade woodland: see below). It 
seems likely, therefore, that local changes in geology will be reflected in changes in forest 
floristic composition. ereas on the northwest plateau there is an abrupt change from 
limestone island rim to lagoonal interior, on the northern pla au there is an alternation 
of bedrock exposures with lagoonal depressions (Spencer and aulay, this volume); these 
differences might be expected to be echoed in forest type. Superimposed on geological 
constraints is the possibility of micro-climatic variation across the island top. Broad 
differences between the seemingly wetter north-western plateau and the drier northern 
plateau have already been alluded to: perhaps these differences explain the greater 
abundance of Asplenium nidus and Nesoluma st-johnianum on the north-west plateau 
and the more frequent occurrence of Myrsine hosakae in the northern interior. Finally, 
there are clearly ecological gradients from island margin to plateau interior. The plateau 
edge is a transition zone from the littoral limestone cliff communities, and is the only area 
where Cordyline fruticosa, Scaevola sericea, Euphorbia sparrmannii, Caesalpinia major 
and Ipomoea macrantha were noted on the island top (7. Cliff top and plateau margin 
community: see below). Further inland, these gradients are reflected in the abundance of 
certain species; thus Bidens , Pisonia and Nesoluma become more abundant as  distance 
increases from the coasts whereas the opposite trend is exhibited by Pandanus  . The 
following list shows the variety of species found within the limestone interior forest; 
different combinations of these species yield a complex mosaic of forest types. The 
communities that follow describe those associations that stand out as recognisable units 
within the plateau vegetation. Except for patches of Timonius, no area of the interior 
plateau is dominated by one or a few species, but supports diverse communities. I t  should be 
noted that the following list indicates only those 22 species, from a total of 41 species, which 
are common across much of the interior island landscape. Unfortunately our record does 
not include the endemic tree Santalum hendersonense which S t  John and Philipson (1962) 
noted as being common on the plateau top. Opinion on Pitcairn (K. Brown pers.comm. 
1987), however, suggests that the species occurs only in localised clusters. 
Trees:  
Shrubs: 
Herbs: 
Creeper: 
Ferns:  
Celtis sp. 
Geniostoma hendersonense 
Guettarda speciosa 
Nesoluma s t johnianum 
Pandanus tectorius 
Pisonia grandis 
Alyxia sp. 
Bidens hendersonensis var. hendersonensis 
Canthium barbatum f. calcicola 
Canthium odoratum 
Cassia glanduligera 
Eugenia rariflora 
Glochidion pitcairnense 
lxora fragrans 
Timonius polygama 
Xylosma suaveolens var. haroldii 
Dianella intermedia 
Procris pendunculata 
Morinda umbellata var. forsteri 
Asplenium nidus 
Davallia solida 
Polypodium sp(p). 
The cliff top is characterized by a dense thicket vegetation in which Timonius, Ctkrzthiunz 
odoralum, Nephrolepis and Polypodium sp(p). are abundant (Plate 5). St. John and 
Philipson (1962; Plate 5 )  also show Xylosma suaveolens to be an important component of 
the cliff top community above the north-west beach; we concur with this observation. 
Particularly noticeable are large individuals of Pandanus ; their pyramidal forms often 
dominate the island skyline from the sea and give, perhaps, an impression of greater 
abundance than is actually the case (eg. Plate 4). 
Away from the immediate marginal cliffs, Eugenia begins to decline in abundance 
whereas Celtis sp., Ixora fragrans, Cassia glanduligera and Glochidion pitcairnense start  
to appear as  important constituents of the forest community on rocky substrates. At the 
north beach the presence of Cocos nucifera and Cordyline fruticosa a t  the plateau margin is 
clearly related to the trail leading into the island interior. Similarly, Caesalpinia major 
is only found in association with the north coast trail (curiously, the difficulties of passage 
produced by this species are documented by Fosberg e t  al. (1983) for Henderson yet the 
species was not collected by the Mangarevan expedition (St. John and Philipson 1962)). 
Trees: 
Shrubs: 
Shrubs: 
Herb: 
Creepers: 
Ferns: 
Cocos nucifera 
Celtis sp. 
Pandanus tectorius 
Pisonia grandis 
Canthiurn odoratum 
Cassia glanduligera 
Cordyline fruticosa 
Eugenia rariflora 
Glochidion pitcairnense 
Ixora fragrans 
Scaevola sericea var. tuamotuensis 
Timonius polygama 
Xylosma suaveolens var. haroldii 
Euphorbia sparrmannii 
Boerhavia tetrandra 
Caesalpinia major 
Cassytha filiformis 
Ipomoea macrantha 
Davallia solida 
Nephrolepsis hirsutula 
Polypodium sp(p). 
8. Pinnacle-~itted limestone communitv 
Inland from the north-west beach is an area of open limestone, with limestone pinnacles up 
to 2 m high (Plate 6; and well illustrated by Fosberg et al. 1983, Plates 11 and 12). The 
horrors of traversing this terrain are well described by St. John and Philipson (1962). 
Although we only saw a small, perhaps 50m diameter, area of this pinnacle-pitted 
limestone, both its unique landscape and unusual vegetation warrants its separation as a 
distinctive community. The fern Nephrolepsis hirsutula is scattered across the top of the 
pinnacles while Aspleniua nidus sits in th  allows between them. Several 
stokesii trees grow on this barren landscape, where this species was obSel-Ved 
both by the Mangarevan (Fosberg, pers.comm. 19 e 1987 expedition. 
Tree: Hernandia stokesii 
Shrub: Eugenia rariflora 
Ferns: Asplenium nidus 
Nephrolepsis hirsutula 
Polypodium sp(p). 
9. Timonius scrub communitv 
Locally, the limestone forest community may be replaced by a scrub vegetation dominated 
by monospecific thickets of Timonius . This comprises an almost inpenetrable low canopy 
up to 3m high with an intersecting mattress of brittle dead twigs and branches below. The 
10 
trees and shrubs which surround these patches are typical of the cliff top and plateau 
margin community (see above for species list). 
Shrub: Timonius polygama 
10. Limestone  lade woodland community 
The presence of pocket soils on the lagoonal deposits of the plateau is reflected in the 
development of a glade woodland with a more open canopy than that of the limestone forest. 
This community also often supports a lush fern understorey, largely composed of Davallia 
solida and Polypodium sp(p) but also with Procris and Morinda umbellata var. forsteri. 
Commonly found foraging through the litter layer in this community is the Henderson 
Island Rail, Porzana atra. The dominant tree species are Pisonia and Nesoluma with 
occasional Pandanus  and the relatively rare Myrsine . Alyxia sp. is often entangled 
throughout the canopy and parasitic Korthalsella spp. and epiphytic Pyrrosia serpens are 
ere breaks in the canopy occur, the main gap colonist is Senecio stokesii 
with Glochidion and Cassia invading a t  the margins. 
Trees: 
Shrubs: 
Shrubs: 
Creepers: 
Ferns: 
rsine kosakae 
Nesoluma st-johnianum 
Pandanus tectorius 
Pisonia grandis 
Canthium barbatum f. calcicola 
Canthium odoratum 
Cassia glanduligera 
Eugenia rariflora 
Glochidion pitcairnense 
Ixora fragrans 
Premna cf. serratifolia 
Xylosma suaveolens var. karoldii 
rthalsella platycaula var. vitiensis 
rthalsella rubescens 
Procris pedunculata 
Peperomia hendersonensis 
Senecio stokesii 
Alyxia sp. 
Morinda umbellata var. forsteri 
Asplenium nidus 
Davallia solida 
Polypodium sp(p). 
Pyrrosia serpens 
11. b o o n a l  patch reef communitv 
As well as  the coral heads and acroporid sticks within the lagoonal depressions, there are 
larger mounds of coral rubble within these depressions which we interpret a s  rather more 
extensive patch reefs. Where large, these mounds show a distinctive vegetation cover, 
dominated by Eugenia and low Pisonia in a bushy habit (Plate 8). 
Trees :  Guettarda speciosa 
Nesoluma st-johnianum 
Pandanus tectorius 
Shrubs: Eugenia rariflora 
Glochidion pitcairnense 
Ixora fragrans 
Pisonia grandis  
Xylosma suaveolens var. haroldii  
Creeper: Morinda umbellata var. forsteri 
Fe rn :  Polypodium sp(p). 
Remarkably, the  vegetation communites described above have been almost completely 
unaffected by human contact. Fosberg et  al. (1983) list only four adventive species: Cocos 
nucifera,  Cordyline fruticosa, Aleur i tes  moluccana  and A c h y r a n t h e s  a s p e r a  var. 
pubescens. To this list we add Setaria verticillata based on the collections made during the 
1987 expedition. Of these five species, Achyranthes and Aleurites have not been collected 
since 1912 and 1922 respectively. Coconut plantations, clearly associated with campsites, 
are restricted to the central sections of the north beach and the north-west beach. These trees 
have obviously matured since the observations of the Mangarevan Expedition when the 
coconuts of the north-west beach were described a s  "all young" (Fosberg et al. 1983, 18). On 
the plateau surface, coconuts are restricted to the trail inland; mature trees near the cliff top 
and recent plantings a t  intervals along the trail in the  interior. Gordyline is  similarly 
restricted to trail-side locations and is only found near the plateau margin on the north 
coast. Only a single example of the Setnrin grass, which is known from Pitcairn (Fosberg 
et  al., this volume), was seen a t  the north beach camp-site, and all of i t  was excavated. I t  
may have been a vei-y recent colonist.The lime and orange trees reported by 
and assumed to be a t  the north landing (St John and Philipson 1962) were not seen on the 
1987 expedition. We were not able to verify the presence or absence of introduced root crops 
a t  the north east  point. The cutting of Thespesia populnea by the Pitcairners is largely 
confined to the  low limestone platform near the  shore and does not result  in the  
disturbance of other vegetation communities. 
Although the  vegetation of Henderson Island i s  greatly enriched compared to 
neighbouring atolls, several typical atoll plants that  occur in the Eastern Tuamotus or even 
on neighbouring Oeno Atoll are absent on Henderson, e.g. Hedyotis romanzoffiensis, 
Sophora  tomentosa,  Calophyllum inophyllum, Barr ingtonia  as ia t ica  and Nesogenes 
euphrasioides. Although the absence of such littoral species may in part be due t o  isolation, 
the limited extent of beaches, the lack of much reef protection, and the encroachment of the 
abundant 'high island' vegetation on the littoral community may also be important. The 
poverty of the strand flora is  further reflected in our inability to find several previously 
reported strand plants. Of the 13 plant species that  we failed to relocate from Fosberg et  al.'s 
(1983) floristic list, 5 (Por tulaca  lu tea ,  Cappar i s  s a n d w i c h i a n a ,  S u r i a n a  mar i t ima .  
Lyciurn carolinense var. sandwicense, Firnbristylis cyrnosa) are predominantly littoral 
plants. The other species that  we did not relocate include 2 introduced plants (Achyranthes 
aspera var. pubescens and Aleurites rnoluccana) tha t  may have disappeared since 1934 
and Aspleniurn lobulaturn, Aspleniurn obtusaturn, Pittosporurn aborescens, Sesbania  
coccinea, Santalurn hendersonense and Meryta brachypoda. Several of these plants are  
obviously rare or localised; 8 of the 13 were also not collected by the Mangarevan 
Expedition. 
Nine species or varieties are presently recognised as  endemic to Henderson (Fosberg e t  al. 
1983, present volume): Peperornia hendersonensis, Celtis sp., Santalurn hendersonense, 
Xylosrna suaveolens var. h a r o l d i i ,  M y r s i n e  h o s a k a e ,  Nesolurna s t - john ianurn ,  
Geniostorna hendersonense, Alyxia sp. and Canthiurn barbaturn f.calcicola. All the  
endemics are primarily inland plants and, with the exception of Santalurn, which we did 
not find in 1987, all were noted to be common in the island interior. 
It  seems likely tha t  botanical collecting trips t o  Henderson Island will continue t o  be both 
infrequent and brief. Clearly, however, there would be value in attempting to visit the 
southern area of the island, not collected since Tait in 1912, and the eastern shores which 
must  be under-collected or possibly not even collected a t  all. I t  is certain t h a t  much 
remains to be learnt  about the vegetation communities of Henderson Island and i t s  
remarkable flora. 
We are grateful to the late George Nichols and the crew of the 'Rambler' for their 
hospitality and great willingness to transport u s  to and around Henderson Island. We 
thank Buck Moravec for help with trail making, Lawrence Schuster for collecting plant 
specimens and Ray Fosberg for identifying the collections. 
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Slightly 
Elevated 
4-8m 
Elevated Sligh ly 1 
Figure 1. Diagram of classification sf emerged reef surfaces (from 
Fosberg 198%). Henderson Island falls within category 
5.2 (Elevated 10-200m) 
Plate 1. Looking west along north beach from the landing. Scaevola 
sericea var. tuamotuensis on seaward slope of beachridge, 
Tournefortia argentea and Pandanus tectorius on beachridge 
crest. 
Plate 2. Limestone buttress, south-central north beach. Monospecific 
Pemphis acidula on low limestone platform behind beach. 
Sesuvium portulacastrum on notch floor (centre middle) of buttress. 
Plate Pemphis acidula on lower limestone unit replaced by fern slopes 
community on higher slopes, north-west beach. Notch floor of 
buttress (centre right) characterized by Sesuvium portulacastrum, 
Euphorbia sparrmannii and Lepidium bidentatum. 
Plate Looking north from end of north-west beach. Pemphis acidula, 
Timonius polygama and emergent Cocos nucifera. Skyline 
Pandanus tectorius is typical. 
Plate 5. Plateau margin scrub thicket vegetation. N. beach trail 
Plate 6. Pinnacle-pitted limestone, inland from north-west beach. 
Limestone forest in background. 
Plate 7. Limestone glade woodland community, N. beach trail. 
Pisorzia grandis and panda nu.^ tectorius with predominantly fern 
understorey.  
Plate 8. Lagoonal patch reef vegetation dominated by bushy Pisonin grnrzclis 
and Eugenia rariflora.