3 Reef community transitions during rapid sea-level
rise: establishing the thresholds of tolerance
Author’s Note: his chapter is based on a published manuscript1 co-authored with J. Webster, J. C. Braga, K. Sugihara, C. Wallace, Y. Iryu, D.
Potts, T. Done, G. Camoin and C. Seard. he co-authors jointly agreed upon the research objectives and approach of the study. he candidate was
responsible for developing methodologies and undertaking data collection related to the core logging, with the exception of the following: isolated
instances of Acropora and Montipora were provided by Dr. Wallace, Favid identiications were provided by Dr. Sugihara, and all thin section
algal identiications were provided by Dr. Braga. he candidate was responsible for all of the presented radiocarbon ages, including all stages
of sample preparation, from pre-treatment to graphitisation, at the ANSTO facilities (under the advisement of Geraldine Jacobsen). X-ray
difraction powders were prepared by the candidate and calcium carbonate mineralogy was calculated by the candidate under the advisement of
Dr. Gordon horogood (ANSTO). he candidate wrote all sections of the chapter, with the exception of the coralline algae assemblage descriptions
in the results and the interpretation of the coralline algae diversity. he assemblage characterisations and interpretations are the candidate’s,
though palaeo-water depths are a combination of the candidate’s coral assemblage interpretation and Prof. Braga’s coralline algae assemblage
interpretation. All igures are the candidate’s.
1
Abbey, E., Webster, J.M., Braga, J.C., Sugihara, K., Wallace, C., Iryu, Y., Potts, D., Done, T., Camoin, G.,
Seard, C., 2011. Variation in deglacial coralgal assemblages and their paleoenvironmental signiicance: IODP Expedition
310, “Tahiti Sea Level”. Global and Planetary Change 76, 1-15.
Portions of data from this chapter were collected for a previous degree undertaken by the candidate (Abbey, E., 2007. Coral reef response to abrupt
climate and sea-level change; evidence from Tahiti fossil reefs. BSc, Hons., James Cook University). Coral and algal observations from cores
M0009B/E, M0021A/B, M0023AB, M0024A and M0025B (i.e., cores from Tiarei except M0009D) were logged prior to the commencement
of the PhD candidature and interpreted within the honours thesis. During the PhD candidature, the previously mentioned cores were re-logged
for their framework percent, and cores M0007A, M0009D, M0015A/B, M0016A/B, M0017A and M0018A were logged by the candidate
and incorporated into the study. New data in the form of radiocarbon ages and X-ray difraction/mineralogy calculations, were performed solely
for the purpose of the PhD and undertaken by the candidate during the candidature. Due to the addition of the second site on Tahiti (Maraa),
which included several new coral and algal taxa and an additional ca. 200 thin section analyses performed by Prof. Braga, coralgal assemblages
and their interpretations have been signiicantly updated. he topic of the present chapter also addresses island-wide spatial variation which
was unaddressed in the honours thesis. Data collection, analyses and interpretations for this chapter constituted a considerable portion of the
candidature (approximately eight months), and as such this work forms a signiicant and original contribution to this thesis.
Chapter 3
Abstract
Fossil reefs are valuable recorders of palaeo-environmental changes during the last deglaciation,
and detailed characterizations of coralgal assemblages can improve understanding of the behavior
and impacts of sea-level rise. Drilling in 2005 by the Integrated Ocean Drilling Program (IODP)
Expedition 310 explored submerged ofshore reefs from three locations around Tahiti, French
Polynesia and provides the irst look at island-wide variability of coralgal assemblages during
deglacial sea-level rise. We present the irst detailed examination of coral and coralline algal
taxonomy and morphology from two sites on Tahiti (ofshore Tiarei and ofshore Maraa). Sixteen
cores ranging in depth from 122 m to 45 m below sea-level represent reef growth from 16 ka to ca.
8 ka (Camoin, G.F., Iryu, Y., McInroy, D.B. and the IODP Expedition 310 Scientists, 2007. IODP
Expedition 310 reconstructs sea level, climatic, and environmental changes in the South Paciic
during the last deglaciation. Scientiic Drilling, 5: 4-12). Twenty-six coral species, twelve coral
genera and twenty-eight coralline algal species were identiied from 565 m of core and over 400
thin sections. Based on these data, and in comparison with modern and fossil analogs, seven coral
and four algal assemblages have been identiied in the deglacial sequences in Tahiti, representing
a range of environments from less than 10 m to greater than 20-30 m water depth. Deglacial
reef initiation varied at sites based on the available substrate, and early colonizers suggest water
conditions at all sites were unfavourable to sensitive corals, such as Acropora, prior to ca. 12.5 ka.
Mainly shallow-water (<10-15 m) corals and coralline algal assemblages developed continuously
throughout both sites from 16 ka to ca. 8 ka, suggesting coralgal assemblage variation is more
inluenced by factors such as turbidity and water chemistry than sea-level rise alone.
3.1
Introduction
Coral reef systems are valuable recorders of environmental changes, as they can display speciic
and predictable zonation patterns related to depth or light attenuation and hydrodynamic energy
regimes (Rosen, 1971; Done, 1982; Faure and Laboute, 1984; Veron, 2000), and are highly
sensitive to variations in water chemistry and physical factors, such as temperature and turbidity
(Buddemeier and Hopley, 1988; Kleypas, 1996). Fossil coral reef systems can be preserved in the
rock record, thus providing detailed information about the past ambient conditions of a region. he
presence or absence of certain corals and coralline algae in the fossil record, in particular those with
known environmental sensitivities, are especially valuable for reconstructing palaeoenvironments.
Combined with U-series and 14C dating, fossil coral reefs have been used to reconstruct climate
59
Abbey 2011
conditions and sea-level rise during the last deglaciation in the Caribbean (Fairbanks, 1989; Bard
et al., 1990a) and the Indo-Paciic (Chappell and Polach, 1991; Edwards et al., 1993; Bard et al.,
1996).
Distinct drowned reef terraces constructed of mono-speciic shallow-water coral Acropora palmata
have been identiied of Barbados and used to constrain deglacial sea-levels, but the Indo-Paciic
lacks a similarly wide-spread inite coral sea-level indicator (Davies and Montaggioni, 1985).
I Instead, pioneering work lead by Pirazzoli and Montaggioni (1988) used coral assemblages
(especially Acropora robusta group) rather than monospeciic communities to constrain palaeowater depths to within ±6 m in French Polynesia (Scoin, 1981; Bard et al., 1996; Cabioch et al.,
1999a; Camoin et al., 2004). Using these modern comparisons, accurate palaeo-environmental
reconstructions can be made, which are important not only for sea-level studies, but also for
understanding how reefs and their component coralgal assemblages respond to a variety of
environmental perturbations.
Several periods of rapid climate and sea-level change have been recognized during the last
deglaciation through the identiication of punctuated reef growth sequences showing periods
of drowning and subsequent regeneration (Blanchon and Shaw, 1995; Montaggioni, 2005).
he timing of these reef drowning events is then used to develop a chronology for sea-level rise
behaviour. Using this method, at least two massive meltwater inputs contributing to accelerated
sea-level rise are thought to have occurred during the last deglaciation. A meltwater pulse around
13.8 to 14.7 ka was identiied in the Caribbean (MWP-1A by Fairbanks, 1989; Fairbanks et al.,
2005), the western-Paciic (Hanebuth et al., 2000) and central Paciic (Bard et al., 1996; Webster
et al., 2004) that resulted in a rise in sea-level of 15 m in less than 500 years, but evidence from
prior drilling in Tahiti remains controversial, as the reef record only extends to 13.8 ka (Bard et
al., 1996). A second, smaller meltwater pulse was also identiied between ca. 10-11 ka in Barbados
(Fairbanks, 1989; Bard et al., 1990b; MWP-1B of Fairbanks, 1990; Bard et al., 1996), the Huon
Peninsula (Chappell and Polach, 1991) and Mayotte Reef (Colonna et al., 1996),however, recent
investigations into previously undated cores from Tahiti reveal evidence to the contrary (Blanchon,
2010). he intervening period between these debated sea-level accelerations saw a brief return to
a near glacial climate state during the Younger Dryas (12.5 ka, Fairbanks, 1990).
While the search for reef growth hiatuses on Tahiti has received much attention, few detailed
studies of coralgal community variability in space and time during periods of growth and
60
Chapter 3
drowning have been undertaken. As the last deglaciation was a time of signiicant sea-level and
climate luctuations, it represents a prime period to observe how coral reefs respond to dramatic
environmental perturbations. In conjunction with the known sensitivities of the studied corals and
algae, spatial and temporal variability may ofer insight into the most inluential factors of reef
initiation, development and death.
0
0
18
0
149°40'
149°30'
0
149°20'
0
1
0
2
Hole1 M0009D
0
149°10'
0
4
1
Site M0019
Site M0020
0
Moorea
1
Faaa
6
Hole M0021B
1
0
Hole M0021A
Tiarei
Site M0009
Site M0021
Site M0023
Site M0024
Site M0025
17°30' S
0
2
Hole M0024A
Hole M0009E
Hole M0009B
149°50'W
0
2
Hole M0025B
Hole M0023B
"
Hole M0023A
0
100
200
"
400
Metres
Tiarei
14 24'15"
17 29'30"
Tahiti
17°40'
N
Maraa
Site M0007
Site M0015
Site M0016
Site M0017
Site M0018
"
17°50'
149°33'0"
Hole M0007A
0
5
10
0
100
149°32'45"
200
Maraa
Metres
20
km
Hole M0017A
0
4
1
0
0
2
1
Hole M0015A
Hole M0018A
Hole M0015B
0 8
1
Hole 1M0016A
Hole
M0016B
0 4
0
0
8
17°46'0"
2
0
2
0
6
0 1
6
Figure 3.1 Study site locale and locations of drilling in Tiarei and Maraa.
As a far ield site, removed from the glacio-isostatic inluence of ice sheet loading and unloading,
and also tectonically stable, Tahiti is an ideal location to study the inluence of deglacial sea-level
rise on coralgal communities. A series of drill holes (P6-P10) of the reefs ofshore Papeete Harbor
has revealed that reef growth was continuous and coralgal assemblages varied through time during
the last 13 ka (Scoin, 1981; Cabioch et al., 1999a; Blanchon, 2010), but the only evidence for
reef growth prior to this time comes from dredged material (15 ka in situ coral, Camoin et al.,
2006). For the irst time, drilling by the IODP in Sep-Oct 2005 has recovered cores from thirtyseven boreholes from three widely spaced sites that extend the reef record to 16 ka (Camoin et al.,
2007a).hese new records will allow for an unprecedented investigation of both the stratigraphic
and small-scale (metres) to large-scale (island-wide) spatial variations in coralgal assemblages on
61
Abbey 2011
Tahiti during deglacial sea-level rise.
he present study concerns sixteen continuous vertical drill holes at two sites on Tahiti. Here we
present a detailed analysis of the deglacial coralgal assemblages during the development of the
Tahiti reef. he primary aims of our study are: (1) to document the characteristics of the coral
and algal assemblages at the two sites, (2) to reconstruct their palaeoenvironmental setting, and
(3) to deine their stratigraphic and spatial variations and discuss their implications for palaeoenvironmental variation during deglacial sea-level rise.
3.2
Study Sites
he two sites studied lay ofshore Tiarei and Maraa, Tahiti, French Polynesia (Central Paciic
Ocean, Figure 3.1). Tahiti is a tropical intraplate volcanic island situated at 17°50 S and 149°20
W in the Society Archipelago. Subsidence rates deduced from the ages of subaerial lavas beneath
the Pleistocene reef range from 0.15 mm year-1 (Le Roy, 1994) to 0.25 mm year-1 (Bard et al.,
1996). Weather patterns are seasonal, with the austral summer months bringing heavy rain and
occasional cyclones, and the winter months being relatively drier and cooler. Rainfall on Tahiti
is variable by location; the west side of the island is the driest and receives an average of 1500
mm year-1, and the southern and eastern sides may receive up to 4000 mm year-1 (Williams,
1933; O’Leary et al., 2008; Bongaerts et al., 2011). Suspended sediments and nutrient lux in the
lagoon are also seasonally variable, where Secchi disk depth can be reduced by 50% in the wet
months (Gabrie and Salvat, 1985; Dupont, 1993). Dominant winds blow from the northeast or
the southeast and create strong swells on the eastern side of the island.
Tahiti’s modern reef consists of fringing and discontinuous barrier reefs. he outer reef slope is
made up of spurs and groves sloping seaward at 20°. Along the south and west coasts, the reef lat
is wide and separated from the fringing reef by only a very shallow lagoon, and on the north and
east coast the reef lat is very narrow and separated by wide lagoons locally reaching depths of 35
m (Williams, 1933; Dupont, 1993).
3.3
3.3.1
Methods
IODP Drilling operations and recovery
Transects of holes were drilled from three regions around Tahiti using the mission speciic
platform, the DP Hunter, ofshore Faa’a, Tiarei and Maraa (Harris and Whiteway), IODP Sites
TAH-01A, TAH-02A and TAH-03A respectively (Figure 3.1). Water depths at these locations
62
Chapter 3
range from 41.6 to 117.5 m. During drilling, the core barrel was advanced in 1.5 m increments,
and core depths were measured with ± 0.1 m accuracy (Inwood et al., 2008). Cores are 65 mm in
diameter and were recovered at depths ranging from 41.6 to 161.8 m. Average recovery exceeds
90% when primary cavities and macroporosity are considered (Inwood et al., 2008). Sixteen holes
were analysed for the purpose of this study. Paired cores are deined as those positioned within 5
to 20 m from one another, and cores may be separated by distances of up to 350 m at a site (Figure
3.1, e.g., Maraa). Diferences in the depths of Pleistocene substrates of sea loor drilling targets
can also vary by 25 to 30 m.
hree pairs (M0021A/B, M0023A/B, and M0024A/25B) and one trio (M0009B/D/E) of cores
have been examined from Tiarei. One pair was recovered from the inner ridge (M0023A/B)
and the remaining cores were recovered from the outer ridge. Together they form two transects;
a landward-seaward transect extends from the inner ridge to the outer ridge, and a NW-SE
trending transect spans 200 m parallel to shore (Figure 3.1). Seven holes from Maraa were
examined, including two pairs (M0015A/B and M0016A/B). Coring in Maraa reached the
Pleistocene basement at a variety of depths, between 107 and 123 metres below sea level (mbsl) in
the outermost holes (M0015A/B, M0016A/B, and M0018A) and between 85 and 95 mbsl in the
innermost holes (M0007A and M0017A).
3.3.2
Core logging and fossil identiication
A combination of petrographic thin sections, slabbed core material, and high-resolution digital
line-scan images of the archive half of core sections were used during logging. Drilling penetrated
two major lithologic units; an upper unit (Unit I) consisting of a deglacial package which is
underlain by a lower unit (Unit II), identiiable by visible diagenetic properties of the sediments
caused by subaerial exposure and meteoric diagenesis during sea-level lowstand (Camoin et al.,
2007b; Montreal Process Implementation Group for Australia, 2008; homas et al., 2009). All
cores investigated herein intersected the contact between Unit I and Unit II, but only detailed
logging of Unit I was carried out for this study. Cores were examined to identify corals, coralline
algae, and molluscs, as well as to characterize the distribution, morphology and context of the
biota. Coral growth forms were given quantitative deinitions as described in IODP Proceedings
(Camoin et al., 2007b).
In situ corals were distinguished from drilling disturbance or allochthonous rubble using a suite
of criteria established by previous drilling studies (Scoin, 1981; Lighty et al., 1982; Montaggioni
63
Abbey 2011
and Faure, 1997; Cabioch et al., 1999a; Cabioch et al., 1999b; Camoin et al., 2001; Camoin et al.,
2004; Le Roy et al., 2008). he reliability of these criteria can vary with growth form, but include
(1) orientation of well-preserved corallites, (2) orientation of acroporid, pocilloporid, and poritid
branches, (3) coral colonies capped by thick (few cm) coralline algal crusts, and (4) presence of
macroscopic and microscopic sediment geopetals in cavities and mollusc chambers and valves.
Coral and coralline algae observations were subdivided into 10 cm intervals, rounded to the
nearest 5 cm at the bottom of each core section. In order to calculate reef framework volume, each
10 cm length was given a value corresponding to an estimation of the ratio of coralgal material to
any surrounding microbialite. he thickest coralline algal crusts within each 10 cm interval were
recorded, and the occurrence of vermetid gastropods within the crusts was noted.
Corals were described to the lowest taxonomic level in consultation with taxonomic guides and by
comparisons to modern specimens (Veron and Pichon, 1976; Veron et al., 1977; Veron and Pichon,
1979, 1982; Veron and Wallace, 1984; Veron, 1986; Veron, 2000; Braithwaite and Camoin, 2011).
Using a comparison of the biozonation of the fossil corals’ modern counterparts, the palaeoenvironmental settings were reconstructed. Detailed taxonomic observations of the coralline algae
were undertaken using over 400 ultra-thin sections. Since all identiied coralline species are living
today in Tahiti and other areas of the Paciic Ocean, their present-day environmental distribution
(depth range) has also been used to interpret the palaeo-environmental settings of the in situ
coralgal frameworks. In all in situ samples the interpreted palaeo-water depth is the shallowest
depth range of the coralline species co-occurring in the sample. We have followed the depth
distribution of living corallines indicated by Cabioch et al.(1999b), Payri et al. (2000), and Littler
and Littler (2009).
3.3.3
Radiocarbon dating and X-ray difraction
Samples of coral and encrusting coralline algae were inspected under magniication and
mechanically cleaned with a dentil drill and then ultra sonically cleaned in Milli-RO water.
Samples were then submerged in 10% H2O2 for 24 hours to remove organic carbon. 500-1000
mg of each coral and coralline algae sample was etched with HCl to a minimum of 40% loss by
weight. Sub-samples of 12-20 mg were subsequently hydrolysed and graphitized. Radiocarbon
ages were measured by accelerator mass spectrometry (AMS) on the ANTARES facility installed
at ANSTO (Fink et al., 2004). AMS ages were converted to calendar years BP using CALIB Rev
5.0.1 (Stuiver and Reimer, 1993) using the marine calibration dataset- marine04.14c (Hughen et
64
Chapter 3
al., 2004) and a reservoir deviation of 82 ± 42 (ΔR).
Table 3.1 Coral taxa identiied from Maraa (m) and Tiarei (t).
Family ACROPORIDAE
Family FAVIIDAE
Acropora sp.mt
Favia sp.mt
Acropora aculeus?m
Favia pallida?t
Acropora cytheream?
Leptastrea sp.mt
Acropora gemmiferat
Leptastrea purpureat
Acropora secale?m
Leptastrea transversamt
Montipora sp.mt
Montastrea sp.mt
Montipora aequituberculatamt
Montastrea curtamt
Montipora tuberculosamt
Montipora verrucosamt
Family FUNGIIDAE
Montipora cf venosam
Fungia sp.t
Fungia danaet
Family AGARICIIDAE
Leptoseris sp..mt
Family POCILLOPORIDAE
Leptoseris explanatam?t
Pocillopora sp.mt
Leptoseris solidamt
Pocillopora damicornist
Pachyseris sp.mt
Pocillopora eydouximt
Pachyseris speciosamt
Pocilopora verrucosat
Pavona sp.mt
Pavona explanulatat
Family SIDERASTREIDAE
Pavona maldivensismt
Psammocora sp.mt
Pavona variansmt
Family PORITIDAE
Porites sp.mt
Porites lichen/rusmt
Porites lobatamt
Porites lobata/solidamt
Splits of each pre-treated coral sample were powdered for X-ray difraction (XRD) to quantify
contamination and possible carbonate recrystalization. he measurements were carried out using a
PANalytical X’Pert Pro Difractometer with Cu Kα radiation and XRD data were collected over a
65
Additional components
Assemblage 1
cA1
Massive and encrusting Montipora (e.g., M. aequituberculata, M. tuberculosa), Algae up to 3 cm thick, Tiarei
robust Pocillopora (e.g., P. eydouxi), branching Porites, and associated encrusting commonly with vermetid
Porites and Faviids (e.g., Montastrea curta).
gastropods.
Assemblage 2
cA2
Massive Porites, Montipora, associated branching Porites, Acropora, and Pocillopora. hin algal crusts.
Vermetid gastropods
uncommon.
All sites
Less than 25 m, turbid
Assemblage 3
cA3
Branching Porites (e.g., P. lichen/rus), Pocillopora, Pavona maldivensis, associated Algae commonly thick,
encrusting Porites, Montipora (e.g., M. tuberculosa, M. aequituberculata), and up to 4 cm. Vermetid
Faviids (e.g., L. transversa).
gastropods commonly
associated.
All sites
Less than 30 m
Assemblage 4
cA4
Tabular and rare branching Acropora (e.g., A. secale), branching and encrusting Algae up to 2 cm thick Maraa
Porites, Montipora (e.g., M. cf aequituberculata, M. venosa), Faviids (e.g., L. cf common.
transversa), Agariciids (e.g., P. varians), and associated Pocillopora.
Assemblage 5
cA5
Branching and encrusting Porites (e.g., P. lobata), Montipora (e.g., M.
aequituberculata, M. tuberculosa, M. verrucosa), Agariciids (e.g., Pavona maldivensis,
P. varians, rare Pachyseris speciosa), Faviids (e.g., L. transversa, M. curta). Occurs
with tabular Acropora (e.g., Acropora cytherea) and massive Porites in Maraa only.
hick algae is localized, All sites
reaching 4 cm. Vermetid
gastropods in the thickest
crusts.
Less than 20 m
Assemblage 6
cA6
Montipora (e.g., M. tuberculosa), Agariciids (e.g., P. varians, Pachyseris sp., Algae commonly thin
All sites
Leptoseris solida), Faviids (e.g., M. curta, L. transversa).
with localized thickening
up to 4 cm. Vermetid
gastropods uncommon.
Less than 30 m
Assemblage 7
cA7
Montipora (e.g., M. tuberculosa), Agariciids (e.g., P. varians, Pachyseris sp., Algae
is
Leptoseris solida), Faviids (e.g., M. curta, L. transversa).
laminated.
Generally deeper than
20 m or turbid
thin
Distribution
or All sites
Palaeo-environmental
interpretation
Less than 10 m, high
energy
Less than 10 m
66
Key components
standards with 0.1, 0.5, 2.0, 10.0 and 20.0% calcite were used for calibration.
Coral
assemblage
2θ range of 5° to 80°. Approximately 50 mg of powdered coral was used for each test and aragonite
Abbey 2011
Table 3.2 Coral assemblages and their paleoenvironmental interpretations. .
Chapter 3
Figure 3.2 Coral reef limestone showing principle components of (A) Assemblage 1 corals dominated by Montipora
(1) and Pocillopora (2); (B) Assemblage 2 corals dominated by massive Porites (1); (C) Assemblage 3 corals dominated
by branching corals (e.g., Porites (1) and Pocillopora) and very minor associated encrusting corals (e.g., Porites (2)); (D)
Assemblage 4 dominated by robust branching Acropora (1); (E) Assemblage 5 corals dominated by tabular Acropora
(1), branching corals (e.g., Pocillopora) (2), and encrusting and platy corals (e.g., Porites (3) and Agariciids (4)); (F)
Assemblage 6 corals dominated by encrusting (1) and branching (2) Porites, Montipora, Agariciids (3) and Faviids; (G)
Assemblage 7 corals dominated by Pachyseris speciosa, Pavona varians (1) and Montipora (2).
67
Abbey 2011
3.4
3.4.1
Results
Coral Taxonomy
Twenty-six species from twelve genera in seven scleractinian families were identiied from Tiarei
and Maraa (Table 3.1), but due to the nature of the material and the diiculty associated with
identifying corals to species level in cores, it is most meaningful to compare observations only to
the family or genus level.
All twelve identiied coral genera are present in Tiarei cores, but Porites and Montipora are very
dominant. Taxonomic distribution varies spatially at Tiarei, most notably for Acropora, which are
virtually absent from the outer ridge (M0009, M0021, M0024, M0025), but common on the inner
ridge (M0023). Maraa has similar species richness, only lacking the rare Fungia seen in Tiarei
cores, but a more even occurrence of coral genera. In addition to Porites and Montipora, Acropora
and Pocillopora are also very common genera at Maraa. Again, Acropora is not distributed evenly
across all holes at Maraa; it is common in all holes with the exception of M0016B and M0018A.
3.4.2
Coral assemblages and palaeo-environmental interpretation
In situ coralgal framework has been divided into ecological assemblages based on dominant
corals and associated secondary corals (Table 3.2, Figure 3.2). Coral growth form (morphology),
taxonomy, associated biota (e.g., coralline algae, vermetid gastropods), and in situ coralgal material
density were also taken into consideration in the deinition and characterization of each coral
assemblage. Palaeo-environmental interpretations are based on comparisons with analogous
modern and fossil Indo-Paciic reef communities and discussed below.
Based on this coral composition and comparison with modern reef zonation and ecology in the
Indo-Paciic, we identiied seven coral assemblages and their palaeoenvironments (Table 3.2).
1. Assemblage 1 (cA1) is dominated by branching (<2 cm) and robust branching (>2 cm)
Pocillopora (P. eydouxi), massive (>2 cm) and encrusting (<2 cm) Montipora (e.g., M.
aequituberculata, M. tuberculosa), branching and massive Porites, and associated encrusting
Porites and massive Faviids (e.g., Montastrea curta). Coralgal frameworks are dense and
cm-thick coralline algae is present locally (Figure 3.2A). In most of the Indo-Paciic, this
community can be found on modern windward reef crests, from the upper forereef to the
outer reef lat (Montaggioni, 2005). Fossil and modern robust branching assemblages can
be found in reef-edge environments in water depths less than 6 m on Tahiti (Pirazzoli and
68
Chapter 3
Montaggioni, 1988; Montaggioni et al., 1997; Sugihara et al., 2006) and Moorea (Bouchon,
1985).
2. Assemblage 2 (cA2) is characterized by massive Porites and minor Montipora. Massive
Leptastrea transversa, branching Porites, Acropora and Pocillopora are occasionally associated
with this assemblage (Figure 3.2B). Framework is very dense and algal crusts are often only
thin and localized, but can reach 1 cm maximum thickness. In modern reefs, Porites are
commonly found as colonizers where water conditions are poor (low salinity, Prager et al.,
1996; high sedimentation, Veron, 2000). Similar modern Indo-Paciic communities tend to
dominate sheltered environments on reef lats, patch reefs, and backreef zones from 0-25
m water depth (Scoin, 1981; Done, 1982; Bouchon, 1985; Veron, 1986; Cabioch et al.,
1999a).
3. Assemblage 3 (cA3) is dominated by branching corals, mainly Porites (e.g., P. lichen/rus)
and Pocillopora (P. eydouxi), some Pavona maldivensis, and rare encrusting corals (e.g.,
M. tuberculosa, M. aequituberculata, L. transversa, Pavona varians; Figure 3.2C). Coralgal
frameworks are dense and cm thick crusts of algae commonly form over branch tips.
Modern branching communities in the Indo-Paciic are commonly found on semi-exposed
to sheltered environments on the mid-forereef, inner reef lat, and backreef zones up to 20
m deep (Montaggioni, 2005). Similar modern branching assemblages on Moorea can be
found in less than 10 m water depth (Bouchon, 1985), but fossil assemblages of branching
Porites nigrescens on Tahiti occupy more variable water depths to a maximum of 30 m
(Cabioch et al., 1999a).
4. Assemblage 4 (cA4) is dominated by robust branching Acropora, commonly with 2 cm thick
algae on branch tips (Figure 3.2D). Robust Acropora are typically found in high-energy
environments on the reef crest and upper reef slope (Done, 1982; Montaggioni and Faure,
1997; Cabioch et al., 1999b). Robust branching communities (though primarily Pocillopora)
inhabit the modern reefs of Tahiti and Moorea in less than 6 m water depth (Bouchon,
1985; Sugihara et al., 2006). Robust fossil assemblages that dominate the Papeete cores
have been interpreted as indicative of similarly shallow palaeoenvironments in less than 10
m water, and perhaps less than 6 m (Pirazzoli and Montaggioni, 1988; Montaggioni and
Camoin, 1993; Montaggioni et al., 1997; Cabioch et al., 1999a; Cabioch et al., 1999b).
69
Abbey 2011
5. Assemblage 5 (cA5) is characterized primarily by abundant tabular or tabular-branching
Acropora (e.g., A. cytherea, A. secale), branching Porites, and Pocillopora (Figure 3.2E).
Encrusting corals are also common and diverse (e.g., M. cf aequituberculata, M. venosa, L. cf
transversa, P. varians). Corals and algae form relatively dense frameworks with algal crusts
reaching 4 cm thickness locally. Modern tabular-branching communities commonly occur
in semi-exposed or sheltered environments on the upper and mid-forereef, reef lat, and
backreef slope no deeper than 20 m, but are commonly between 2 and 15 m water depth in
Tahiti and the Indo-Paciic (Done, 1982; Montaggioni, 2005; Sugihara et al., 2006). his
fossil assemblage is likely to represent a lower-energy palaeo-environmental setting in 5-15
m water depth on Tahiti (Scoin, 1981; Cabioch et al., 1999a).
6. Assemblage 6 (cA6) is comprised of a very diverse suite of corals and growth forms.
Branching and encrusting Porites (e.g., P. lobata) and Montipora (e.g., M. aequituberculata,
M. tuberculosa, M. verrucosa) are common, as are Pavona (e.g., P. maldivensis, P. varians) and
Faviids (e.g., L. transversa, M. curta; Figure 3.2F). Pachyseris speciosa is present, but rare. Less
Table 3.3 Algal assemblages and their palaeo-environmental interpretation.
Algal
assemblage
Key components
Additional components
Assemblage 1
aA1
hick Hydrolithon
onkodes (locally
Mastophora species)
Hydrolithon gardineri, Hydrolithon murakoshii, Hydrolithon 10 m
munitum, Hydrolithon reinboldii, Pneophyllum conicum,
Neogoniolithon frutescens, Spongites sulawensis, Spongites
fruticulosus, Spongites sp., Lithophyllum cuneatum,
Lithophyllum insipidum, Lithophyllum kotschyanum,
Lithophyllum incrassatum, Lithophyllum prototypum,
Lithophyllum gr. pustulatum
Assemblage 2
aA2
hin H. onkodes, H.
gardineri, P. conicum
Hydrolithon gardineri, Hydrolithon murakoshii, Hydrolithon 20 m
munitum, Hydrolithon reinboldii, Pneophyllum conicum,
Neogoniolithon frutescens, Spongites sulawensis, Spongites
fruticulosus, Spongites sp., Lithophyllum cuneatum,
Lithophyllum insipidum, Lithophyllum kotschyanum,
Lithophyllum incrassatum, Lithophyllum prototypum,
Lithophyllum gr. pustulatum
Assemblage 3
aA3
Mesophyllum
erubescens (depth
range 15-30 m), L.
prototypum
Lt. prolifer, H.murakoshii, H. munitum, H. rupestre, L. 30 m
insipidum, L. incrassatum, L. gr. pustulatum
Assemblage 4
aA4
Mesophyllum
funafutiense,
Hydrolithon
breviclavium,
Lithoporella
H. reinboldii, L. gr. pustulatum, Lithothamnion sps., Greater than
Sporolithon sps.
20-25 m
70
Max depth
Chapter 3
dense frameworks are common, and algae ranges from millimetres to centimetres thick.
his assemblage is somewhat variable between sites, where in Maraa minor tabular Acropora
and massive Porites are also present. hese taxa have broad environmental distributions
and tolerate a wide range of hydrodynamic energy regimes. he relatively high number
of coral species present in this assemblage is typical of the high species richness found in
water depths of 10-20 m on the outer reef slope of Moorea (Bouchon, 1985), however,
A
C
B
ȝP
ȝP
ȝP
D
ȝP
Figure 3.3 (A) Sample 5B4 showing a thick plant of Hydrolithon onkodes with partly buried thallus of Lithophyllum
cuneatum characteristic of very shallow waters (<10 m, Assemblage 1). (B) Sample 18A (4) showing knobby plants of
Mesophyllum erubescens that typically extend down to 25 m (Assemblage 3). (C) Sample 18A3 (4) showing laminar,
terraced plants of Lithophyllum prototypum (also referred to as Titanoderma tessellatum) that mainly occur in the
shallower 25 m (Assemblage 3). (D) Sample 15B1 showing Mesophyllum funafutiense 1 forming frameworks of foliose
plants typical of deep water and shade assemblages (Assemblage 4).
analogous modern communities have not been identiied from Tahiti. Consequently, the
palaeo-environmental setting of this assemblage can only be constrained to semi-exposed
to well-protected environments in water depths less than 30 m.
71
Abbey 2011
7. Assemblage 7 (cA7) is dominated by encrusting corals. Montipora tuberculosa, P. varians, M.
curta, L. transversa, and well-developed colonies of P. speciosa are common (Figure 3.2G).
Leptoseris solida can also be observed. Associated coralline algae can range from thin and/or
laminated up to 4 cm thick. his assemblage can be found on the modern outer reef slope in
30 m water depth in Moorea (Bouchon, 1985) and Tahiti (Sugihara et al., 2006). However,
in modern Indo-Paciic reefs, encrusting corals dominate a variety of environments, ranging
from deep outer reef slopes in excess of 20 m water depth where irradiation is minimal,
to high-energy reef crests and slopes in less than 15 m water depth where water is turbid
(Montaggioni, 2005).
3.4.3
Coralline algal assemblages and palaeo-environmental interpretation
Coralline red algae are common components of deglacial reefs in the studied cores. Corallines are
observed growing on or intergrown with corals and other encrusting organisms in reef framework
(Figure 3.2A-G). Twenty-eight species of coralline algae have been identiied in all the studied
cores, but coralline species richness is not evenly distributed in the diferent sites and throughout
cores. Plants with very thin laminar thalli are commonly microtized, with no diagnostic characters
preserved and cannot usually be identiied. herefore, they have not been taken into account in
the species richness comparisons. All algal genera and species identiied in the cored sequences
are still living in French Polynesia and other Indo-Paciic reefs (Cabioch et al., 1999b; Finkl,
2009). hese living coralline algae species show depth-related habitat preferences and some of
them have relatively narrow depth ranges in their modern distribution. he depth ranges of four
identiied fossil coralline algae assemblages can be used independently from the corals to interpret
the palaeo-water depth of the studied reef framework deposits (Table 3.3).
1. Assemblage 1 (aA1) is characterized by centimetre thick plants of Hydrolithon onkodes
(Figure 3.3A) and extends to 10 m depth. hick crusts of this species are very common on
coral colonies both in present-day and previously cored deglacial reefs of Papeete (Scoin,
1981; Cabioch et al., 1999a). Other species, such as Hydrolithon gardineri, Lithophyllum
kotschyanum and Pneophyllum conicum (= Negoniolithon conicum) are also common in this
shallow water assemblage.
2. Assemblage 2 (aA2) is characterized by species such as H. gardineri, Hydrolithon munitum,
Hydrolithon reinboldii and P. conicum occurring with thin crusts of H. onkodes, which can
extend from 0-20 m (Figure 3.3B).
72
Table 3.4 Summary of coral and algal radiocarbon dating results and calibration. Ages are in years before 1950.
Corrected
error
Median
calibrated
age
Calibrated age
range
Material
15B2R1 57-65
OZM182
8,200
±60
±146
8,598
8,406 - 8,846
Coralline algae hin crusts** (2 mm)
N/A
18A1R1 16-22
OZM178
8,350
±60
±146
8,809
8,589 - 8,995
Coral
P. varians
<1%
L. solida
<1%
C error
Description
Calcite %
15A2RCC 12-14
OZM168
8,640
±70
±163
9,202
90,01 - 94,02
Coral
15A20R1 61-67
OZM169
10,740
±70
±163
11,994
11,632 - 12,354
Coralline algae hick crusts (1 cm)
17A18R1 44-58
OZM172
10,820
±80
±181
12,159
11,832 - 12,404
Coralline algae Very thick crusts (>1 cm) N/A
7A33R1 63-69
OZM183
11,480
±70
±163
12,937
12,841 - 13,081
Coralline algae Very thick crusts (>1 cm) N/A
17A21R1 16-19
OZM177
11,770
±70
±163
13,171
12,993 - 13,304
Coralline algae hick crusts (1 cm)
16A31R1 35-43
OZM173
12,410
±90
±199
13,787
135,49 - 140,17
Coralline algae Very thick crusts (>1 cm) N/A
15B37R1 57-63
OZM171
12,470
±80
±181
13,848
13,666 - 14,042
Coral
15A36R1 37-42
OZM170
12,580
±80
±181
13,948
13,765 - 14,143
Coralline algae Very thick crusts (>1 cm) N/A
16B17R1 16-23
OZM174
12,590
±80
±181
13,957
13,770 - 14,154
Coralline algae hick crusts (1 cm)
18A21R1 30-33
OZM179
12,730
±80
±181
14,128
13,860 - 14,605
Coral
P. rus(?)
<1%
16B23R1 65-70
OZM175
13,210
±90
±199
15,007
14,597 - 15,403
Coral
P. lobata
2-3%
P. lobata
N/A
N/A
<1%
N/A
Chapter 3
73
3. Assemblage 3 (aA3) is characterized by Lithophyllum prototypum (reported as Titanoderma
14
C age
tessellatum by other authors such as Cabioch et al., 1999b), knobby plants of Mesophyllum
14
erubescens, and Lithothamnion prolifer (Figure 3.3C). hese species mainly occur between
Lab code
15 and 30 m, but the latter can live in deeper waters, down to 40-50 m (Keats et al., 1996).
IODP code
Coral assemblages
65
70
11.1I
11.2H
75
12.4AI
12.6
80
Coralline algal assemblages
cA7, encrusting Pachyseris speciosa,
Leptoseris solida and Montipora. Thin coralline algal crusts.
cA6, encrusting and branching corals. Thick
and thin coralline algal crusts.
cA5, encrusting, branching, and tabular corals.
Thick and thin coralline algal crusts
cA3, branching Porites and robust
Pocillopora. Thick coralline algal crusts.
aA4, Mesophyllum funafutiense intergrown with laminar
corals, thin encrusting Lithoporella melobesioides.
aA3, knobby Mesophyllum erubescens, Lithophyllum
prototypum and Lithothamnion prolifer.
aA2, thin crusts of Hydrolithon onkodes with H. gardineri,
H. munitum, H. reinboldii, and Pneophyllum conicum.
cA2, massive Porites. Thin coralline algal crusts.
Coralgal framework percent (Grey, 0-100%) and thickness
of encrusting coralline algae (Red, 0-6cm).
cA1, robust Pocillopora and Montipora. Thick
and thin coralline algal crusts.
V
14.6
Lithology
Associated Vermetid gastropods
I
H
14.6
A
Coral-algal fragments and/or microbialite.
85
aA1, thick crusts of Hydrolithon onkodes.
14.6
14
C age of coral (ka BP), Inoue et al. 2010
14
C age of coral (ka BP), Heindel et al. 2009
U/Th age of coral (ka BP), Asami et al. 2009
Unit II, older Pleistocene reef
mbsl
90
95
Figure 3.4 Cores retrieved
from Tiarei: Stratigraphic
distribution of coral and algal
assemblages, algae thickness,
and
coralgal
framework
density. Coral assemblages are
deined by associated species/
genera/families, growth form
and framework density. Algae
and framework observations
are averaged in 10 cm intervals;
algae thickness is recorded as
the thickest crust in a given
interval, and
framework
values are the average of a 10
cm interval. See Tables 3.3
and 3.4 for complete coral and
algal assemblage descriptions.
100
105
23A
23B
Inner Ridge
110
14.2IA
14.5
14.8H
14.9I
15.1I
115
15.3I
120
125
21A
21B
9E
9D
9B
24A
25B
130
74
Abbey 2011
Outer Ridge
Chapter 3
4. Assemblage 4 (aA4) is characteristic of palaeoenvironments below 20-25 m, and is deined
by the lack of shallower coralline assemblages and the dominance of frameworks of foliose
plants of Mesophyllum funafutiense growing on or intergrown with laminar corals, and thin
encrusting plants of Lithoporella melobesioides, with occurrences of Hydrolithon breviclavium
and Lithothamnion species (Figure 3.3D).
3.4.4
Radiocarbon dating
Fourteen specimens were selected from Maraa for radiocarbon dating, including six corals
and eight crusts of coralline algae. X-Ray difraction analyses of coral specimens conirm very
low levels of calcite in all but the oldest sample (Table 3.4). he radiocarbon results conirm a
postglacial timing of reef development and are consistent with previously published radiometric
dating results from Tiarei (Figure 3.4).
3.4.5
Spatial, stratigraphic, and chronologic changes in coralgal assemblages
he purpose of surveying on both small scales (metres) and large scales (island-wide) is to
establish baseline variability. With an understanding of small scale variation, the signiicance
of large scale variation, or lack thereof, can be identiied. On Tahiti, closely and widely spaced
cores show a range of stratigraphic coralgal assemblage variability between them. Published U/h
and 14C chronology can be found in Asami et al. (2009, corals), Heindel et al. (2009, corals and
microbialites), Inoue et al. (2010, corals) and Westphal et al. (2009, microbialites). More detailed
chronology has been undertaken for sea-level reconstructions (Deschamp et al., in review), reef
accretion history (Camoin et al., in press) and microbialite development (Seard et al., 2011).
Details of 14C dating performed for this study can be found in Table 3.4.
3.4.5.1
3.4.5.2
Tiarei
Seaward core transect
Coring on the outer ridge reached the Pleistocene basement at ca. 119 mbsl (metres below sealevel) in four holes - M009D, M009B, M0024A, and M0025B, and the basement was reached
at ca. 111 mbsl in three holes - M009E, M0021A, and M0021B (Figure 3.4). he irst corals to
populate the basement substrate in every hole on the outer ridge, regardless of timing of initiation,
are Montipora (e.g., M. aequituberculata and M. tuberculosa), Porites and Pocillopora (e.g., P. eydouxi;
cA1). his assemblage has a stratigraphic thickness of 1 to 6 m with thick and thin coralline algal
crusts of H. onkodes and H. gardineri (algae Assemblage 1 and 2). All communities forming on the
ca. 119 mbsl substrate transition into extensive massive Porites communities (cA2) ranging from 2
75
Abbey 2011
to 10 m in stratigraphic thickness at ca. 118 mbsl and 15.3 ka. hick crusts of H. onkodes associated
with vermetid gastropods also characterize this stratigraphic interval.
No massive Porites communities (cA2) develop on the 111 mbsl basement substrate following
the initial coral assemblage. Instead, a dense framework of branching Porites (cA3) and thick and
thin crusts of H. onkodes (aA1 and aA2) extend for 5 m or more. At 115-110 mbsl and ca. 14.8
ka, massive Porites in the deeper holes are replaced by the same dense framework of branching
Porites as is seen in shallower holes. In all outer ridge holes, with the exception of M0009D where
a signiicant gap in recovery precludes the assessment of the presence or absence of Assemblage
5 in this stratigraphic interval, branching Porites (e.g., P. lichen/rus) continues and/or alternates
with massive Porites (e.g., P. lobata/solida). Both communities are succeeded by a diverse coral
assemblage of branching and encrusting Porites, Montipora, Agariciids,and Faviids (cA6) at depths
ranging from 110 to 100 mbsl in association with thick and thin crusts of H. onkodes (aA1). With
the exception of M0024A, cA6 is then replaced by the ultimate succession of encrusting and platy
corals (e.g., L. transversa, Pachyseris, Pavona; cA7). Corallines associated with this assemblage are
thin and laminar crusts of M. funafutiense and Lithoporella (aA4). Deeper holes M0009B/D/E and
M0025B transition into this inal assemblage 98 to 108 mbsl and development of this assemblage
is variable, from 1 to 4 m in thickness. In shallower holes (M0021A/B), the transition into cA7
occurs at ca. 85 mbsl and reef growth terminates at ca. 82 mbsl.
3.4.5.3
Landward hole transect
Holes M0023A and M0023B on the inner ridge reached the Pleistocene basement between 95
to 98 mbsl (Figure 3.4). he irst community to occupy the substrate is a dense framework of
branching Porites and Pocillopora (e.g., P. eydouxi; cA3) and up to 2 cm thick crusts of H. onkodes
with Mastophora (aA1) and associated vermetid gastropods. his assemblage is extensive, up to
15 m thick, and continues until ca. 81 mbsl. Tabular Acropora develops in M0023B (cA5) and
alternates with cA4. Acropora does not become dominant in M0023A, where instead a diverse
suite of branching Porites and encrusting Montipora and Agariciids (cA6) alternates with massive
Porites (Assemblage 2) ca. 12.6 ka. H. onkodes and Mastophora paciica (aA1 and aA2) are common
throughout both holes until ca. 73 mbsl. An encrusting and platy coral community (e.g., L.
transversa, P. varians; cA7) associated with M. funafutiense (aA4) develops in both holes at ca. 73
mbsl ca. 11.2 ka and growth continues until the tops of holes at ca. 67 mbsl.
76
Coral assemblages
40
45
50
Coralline algal assemblages
cA7, encrusting Pachyseris speciosa,
Leptoseris solida and Montipora. Thin coralline algal crusts.
cA6, encrusting and branching corals. Thick
and thin coralline algal crusts.
cA5, encrusting, branching, and tabular corals.
Thick and thin coralline algal crusts.
aA4, Mesophyllum funafutiense intergrown with laminar
corals, thin encrusting Lithoporella melobesioides.
aA3, knobby Mesophyllum erubescens, Lithophyllum
prototypum and Lithothamnion prolifer.
aA2, thin crusts of Hydrolithon onkodes with H. gardineri,
H. munitum, H. reinboldii, and Pneophyllum conicum.
cA4, robust branching Acropora.
aA1, thick crusts of Hydrolithon onkodes.
cA3, branching Porites and robust
Pocillopora. Thick coralline algal crusts.
55
Coralgal framework percent (Grey, 0-100%) and thickness
of encrusting coralline algae (Red, 0-6cm).
cA2, massive Porites. Thin coralline algal crusts.
60
5.86*
9.8I
cA1, robust Pocillopora and Montipora. Thick
and thin coralline algal crusts.
65
Lithology
Coral-algal fragments and/or microbialite.
70
V
Associated Vermetid gastropods
14.6*
14.6**
14.6H
14.6I
W
14.6
14
C age of coral (ka BP), this study
C age of coralline algae (ka BP), this study
C age of coral (ka BP), Heindel et al. 2009
C age of coral (ka BP), Inoue et al. 2010
14
C age of microbialite (ka BP), Westphal et al. 2009
14
14
14
Unit II, older Pleistocene reef
8.60**
9.20*
mbsl
75
80
Figure 3.5 Cores retrieved from
Maraa: Stratigraphic distribution
of coral and algal assemblages, algae
thickness, and coralgal framework
density. Coral assemblages are
deined by associated species/
genera/families, growth
form
and framework density. Algae
and framework observations are
averaged in 10 cm intervals; algae
thickness is recorded as the thickest
crust in a given interval, and
framework values are the average
of a 10 cm interval. See Tables 3.2
and 3.3 for complete coral and algal
assemblage descriptions.
12.2H
8.81*
12.9**
85
12.2**
90
12.0**
13.2**
95
7A
100
17A
Landward
105
13.9*
13.9**
13.4
110
13.8**
W
14.0**
115
14.1*
120
77
130
15A
15B
16A
Seaward
16B
18A
Chapter 3
15.0*
125
Abbey 2011
3.4.5.4
3.4.5.5
Maraa
M0016 and M0018
Massive P. lobata communities (cA2) initiated in three outermost holes (M0016A, M0016B, and
M0018A) on the basement substrate at ca. 120 mbsl ca. 15-14 ka (Figure 3.5). hese communities
are associated with thin crusts of H. onkodes typical of aA2 and persist through several metres of
core to 115 to 110 mbsl. At 115 mbsl massive Porites is succeeded by branching Porites and P.
maldivensis with associated M. cf verrucosa (cA3) in M0016A and M0018A, and branching and
encrusting Porites and Montipora with associated P. varians (cA6) in M0016B. hick and thin
crusts of H. onkodes (aA1 and aA2) and vermetid gastropods are common. cA3 and cA6 alternate
for 15 m through these outermost holes and algal assemblages aA1 and aA2 reach thicknesses up
to 6 cm.
At ca. 100 mbsl, growth of cA6 and algal assemblage aA2 terminate in M0016B without the
development of an encrusting community (i.e., cA6) or deep-water corallines (i.e., aA4). Branching
colonies of Porites, A. cytherea and P. maldivensis continue through M0016A and M0018A for
another 10 m. At ca. 90 mbsl, corals in M0016A and M0018A become dominated by encrusting
and platy forms of Montipora and P. varians (cA6 and cA7) with only minor branching corals.
Coralline algae crusts are thinner and Mesophyllum is dominant in M0016A, but H. onkodes
continues to be associated with the corals in cA7 until ca. 85 mbsl. At ca. 85 mbsl, Pachyseris, L.
solida and P. varians are dominant in both holes with associated M. curta, and thin crusts of M.
funafutiense and Lithoporella are common (aA4). Reef growth terminates in both holes at 81 mbsl
ca. 8.8 ka.
3.4.5.6
M0015
At ca. 110 mbsl and ca. 13.9 ka, reef growth is initiated in M0015A by branching Porites and
robust branching Pocillopora (cA3) with thick crusts of H. onkodes and Mastophora and in M0015B
by massive Porites (cA2) and thin crusts of H. onkodes (aA2; Figure 3.5). Massive P. lobata remains
dominant in M0015B from 108 to 106 mbsl, but then reverts to branching Porites and robust
branching Pocillopora, which continues with up to 4 cm thick crusts of H. onkodes in both M0015A
and M0015B to ca. 90 mbsl. A brief interval of tabular Acropora (cA5) interrupts this branching
Porites assemblage at ca. 97 mbsl in both holes. At ca. 90 mbsl and ca. 12.0 ka, coral growth
becomes dominated by tabular Acropora, branching Porites, robust Pocillopora (cA5) and crusts of
H. onkodes/H. gardineri and N. conicum up to 1 cm thick. Tabular Acropora extends continuously
through M0015A until ca. 80 mbsl, but is interrupted in short intervals in M0015B at ca. 87 and
78
Chapter 3
ca. 83 mbsl where it is replaced by branching and encrusting Porites and Montipora (cA6) and
massive Porites (cA2). Associated corallines within this interval include L. prolifer, M. funafutiense
and Lithoporella (aA3 and aA4). Tabular corals (cA5) resume with thick crusts of H. onkodes (aA1)
at ca. 81 mbsl in M0015B until ca. 79. At ca. 79 mbsl, corals become dominated by Leptoseris and
P. speciosa with P. varians, Montipora (cA7) and thin (1-2 mm) crusts of coralline algae dominated
by M. funafutiense and laminar Lithothamnion (aA4). Reef growth is terminated ca. 73 mbsl and
9.2-8.6 ka.
3.4.5.7
M0007 and M0017
Reef growth in the innermost holes, M0007A and M0017A, initiated on the Pleistocene substrates
ca. 85 and ca. 95 mbsl respectively (Figure 3.5). A community of massive M. curta, L. cf transversa
and branching Pocillopora and Porites (cA1) is the irst to colonize the basement in M0017A ca.
13.2 ka. Branching P. lichen/rus (cA3) alternates with massive Porites (cA2) and a brief interval
of tabular Acropora (cA5) until ca. 85 mbsl. Associated algae reach 2 cm thickness and consist of
H. onkodes, H. gardineri and Mastophora (aA1) with vermetid gastropods locally. Reef growth in
M0007A is initiated by robust Pocillopora (cA3) and associated with 2 cm thick crusts of coralline
algae and vermetid gastropods. In both innermost holes, corals transition to a tabular Acropora
dominated community with robust Pocillopora and branching Porites (cA5). A distinct community
of exclusively robust branching Acropora (cA4) develops from 82 to 78 mbsl (ca. 12.2 ka) and 77
to 73 mbsl (ca. 12.9 ka) in M0017A and M007A respectively, above which reef growth returns to
tabular and branching Acropora (A. secale) with branching Porites, Pocillopora and minor encrusting
corals (M. cf venosa, L. transversa, P. varians) (cA5). his community extends until ca. 70 mbsl
in hole M0017A, throughout which thin crusts of H. onkodes (aA2) overgrown by Mesophyllum,
Lithothamnion and Lithoporella develop. Corals transition into an encrusting assemblage of
Montipora and P. varians (cA7) with thin crusts of M. funafutiense, Lithothamnion and Lithoporella
(aA4) which develop until reef growth terminates at ca. 60 mbsl, ca. 5.9 ka. Tabular Acropora
develops in hole M0007A until 64.5 mbsl where corals transition over 1 m into massive Porites
(cA2) with L. prolifer and M. erubescens (aA3) and thin crusts of Mesophyllum and Lithoporella.
Massive Porites alternates with encrusting and branching Porites, Pocillopora, and Montipora (cA6)
until ca. 53 mbsl. hin coralline algal crusts of Mesophyllum and Lithothamnion (aA4) replace aA3,
and encrusting Porites, M. tuberculosa, P. varians and Leptastrea (cA7) replace cA6. In situ corals
and algae develop until ca. 45 mbsl, where they are replaced by 1 m of branching Porites and
Pocillopora rubble at the top of the hole.
79
Paleowater depth (m)
0
70
10
11.1
20 30+
0
10
75
20 30+
I
11.2
Coralline algal assemblages
aA4, Mesophyllum funafutiense intergrown with laminar
corals, thin encrusting Lithoporella melobesioides.
aA3, knobby Mesophyllum erubescens, Lithophyllum
prototypum and Lithothamnion prolifer.
cA7, encrusting Pachyseris speciosa,
Leptoseris solida and Montipora. Thin coralline algal crusts.
cA6, encrusting and branching corals. Thick
and thin coralline algal crusts.
cA5, encrusting, branching, and tabular corals.
Thick and thin coralline algal crusts
H
aA2, thin crusts of Hydrolithon onkodes with H. gardineri,
H. munitum, H. reinboldii, and Pneophyllum conicum.
aA1, thick crusts of Hydrolithon onkodes.
cA4, robust branching Acropora.
cA3, branching Porites and robust
Pocillopora. Thick coralline algal crusts.
A
12.4I
12.6
Lithology
cA2, massive Porites. Thin coralline algal crusts.
80
0
0
10
10
20
30+
Coral-algal fragments and/or microbialite.
cA1, robust Pocillopora and Montipora. Thick
and thin coralline algal crusts.
20 30+
85
14.6
I
14
C age of coral (ka BP), Inoue et al. 2010
H
14
C age of coral (ka BP), Heindel et al. 2009
14.6
A
14.6
Unit II, older Pleistocene reef
U/Th age of coral (ka BP), Asami et al. 2009
0
mbsl
90
95
0
10
0
23A
23B
Inner Ridge
10
20 30+
20 30+
100
105
Associated Vermetid gastropods
V
0
10
10
0
20 30+
20 30+
110
14.2IA
14.5
14.8IH
14.9
115
15.1
I
15.3
I
120
125
130
21A
21B
9E
9D
Outer Ridge
9B
24A
25B
10
20 30+
Figure 3.6 Interpreted palaeowater depth intervals in cores from
Tiarei. Water depths are based on
published accounts of fossil and
modern Indo-Paciic reefs.
Abbey 2011
80
Coral assemblages
65
Coral assemblages
Coralline algal assemblages
cA7, encrusting Pachyseris speciosa,
Leptoseris solida and Montipora. Thin coralline algal crusts.
cA6, encrusting and branching corals. Thick
and thin coralline algal crusts.
cA5, encrusting, branching, and tabular corals.
Thick and thin coralline algal crusts.
aA4, Mesophyllum funafutiense intergrown with laminar
corals, thin encrusting Lithoporella melobesioides.
aA3, knobby Mesophyllum erubescens, Lithophyllum
prototypum and Lithothamnion prolifer.
aA2, thin crusts of Hydrolithon onkodes with H. gardineri,
H. munitum, H. reinboldii, and Pneophyllum conicum.
50
cA4, robust branching Acropora.
aA1, thick crusts of Hydrolithon onkodes.
55
cA3, branching Porites and robust
Pocillopora. Thick coralline algal crusts.
40
Paleowater depth (m)
0
10
20
30+
45
0
10
20
30+
Coralgal framework percent (Grey, 0-100%) and thickness
of encrusting coralline algae (Red, 0-6cm).
cA2, massive Porites. Thin coralline algal crusts.
60
9.8I
V
cA1, robust Pocillopora and Montipora. Thick
and thin coralline algal crusts.
5.86*
Associated Vermetid gastropods
14
14.6*
14.6**
H
14.6
I
14.6
14.6W
Lithology
65
Figure 3.7 Interpreted palaeo-water
depth intervals in cores from Maraa.
Water depths are based on published
accounts of fossil and modern IndoPaciic reefs.
C age of coral (ka BP), this study
C age of coralline algae (ka BP), this study
C age of coral (ka BP), Heindel et al. 2009
14
C age of coral (ka BP), Inoue et al. 2010
14
C age of microbialite (ka BP), Westphal et al. 2009
14
14
Coral-algal fragments and/or microbialite.
Unit II, older Pleistocene reef
70
0
10
20
30+
0
10
20
30+
8.60**
9.20*
mbsl
75
80
0
12.2H
10
20
30+
0
10
20
30+
0
10
20
30+
8.81*
12.9**
12.2**
85
90
12.0**
13.2**
95
7A
100
17A
Landward
105
13.9**
13.9*
13.4
110
13.8**
W
14.0**
115
14.1*
120
15.0*
125
15A
15B
16A
Seaward
16B
18A
81
Chapter 3
130
Abbey 2011
3.5
3.5.1
Discussion
Integration of coralline and coral interpretations
In most cases, coralline assemblage palaeo-environmental interpretation is consistent with the
associated coral assemblage palaeo-environmental interpretation (e.g., thick crusts of shallowwater H. onkodes [aA1] are associated with shallow-water robust branching Acropora [cA4], and
deep-water L. melobesioides and M. funafutiense [aA4] are associated with deep-water P. speciosa and
Leptoseris [cA7]; Figure 3.6, 3.7). However, algal species typical of deeper assemblages may occur
with those characteristic of shallower depths in the same sample. In these instances, the maximum
depth range of the shallowest coralline present deines coralline assemblages and their palaeoenvironmental signiicance. In samples from the studied holes, species typical of the deepestwater assemblage (aA4), such as M. funafutiense and L. melobesioides, can appear overgrowing
species characteristic of aA1-3 or encrusting the same coral branch on a diferent side, usually
immediately predating microbial crusts. As light penetration is one of the major controlling
factors in coralline distribution (Adey, 1979, 1986), the presence of crevices, caves and cavities
inluence species distribution in a similar manner to water depth. Shade habitats are dominated
by the same corallines as those living in open deep environments. hese species can be found at
the same depth as those exclusive to shallow water but in darker habitats. Similarly, shallow-water
species can be overgrown by shade species when the framework substrate in which they grew
becomes overshadowed by new coral growth. herefore, only the algal assemblage indicative of
the shallowest range for the palaeo-water depth interpretation is relevant to the overall coralgal
palaeo-environmental interpretation.
3.5.2
Coralgal assemblage variations in space
Maraa and Tiarei coral assemblages show distinct patterns in spatial distribution that appear to
be controlled by the depth and nature of the Pleistocene basement and proximity to the island.
Massive Porites are common in outer cores in both Tiarei (e.g., M0024A/25B; Figure 3.4) and
Maraa (e.g., M0015A/B and M0016A/B; Figure 3.5) where they form thick sections, yet are
rare and/or less developed in inner cores. Porites species, especially domal forms, tend to be very
hardy and resistant to low temperature, low salinity, high terrigenous input and reduced water
circulation (Marshall and Orr, 1931; Manton, 1935; Lambeck and Nakada, 1990; Schlöder and
D’Croz, 2004; Sheppard et al., 2010; Webster et al., 2010). Porites are often found at the base of
cores retrieved from the Great Barrier Reef, where it is interpreted as indicating a lag in initial
colonization due to locally adverse conditions (Davies and Hopley, 1983; Toscano and Macintyre,
82
Chapter 3
2003). Inimical conditions on the outer edge of the reef may have been caused by the resuspension
of sediments during the early stages of sea-level rise, creating an environment too harsh for more
sensitive genera, such as Acropora (van Woesik and Done, 1996; Pandoli et al., 1999). Low salinity
and poor water quality may have also been exacerbated at Tiarei where the island’s largest river
Table 3.5 Algal distribution relative to coral assemblage and site.
Acropora interval (branching +
tabular), Maraa
Branching Porites interval, Maraa
Branching encrusting interval, Tiarei
(coeval to Acropora in Maraa)
Hydolithon breviclavium
H. gardineri
H. breviclavium
Hydolithon gardineri
H. murakoshii
H. gardineri
Hydolithon murakoshii
H. onkodes
H. murakoshii
Hydolithon munitum
Hydorlithon rupestre
H. onkodes
Hydolithon onkodes
Lithoporella sp.
H. reinboldii
Lithoporella sp.
Mastophora paciica
M. paciica
Mastophora sp.
Neogoniolithon sp.
Lithoporella sp.
Neogoniolithon fosliei
P. conicum
P. conicum
Neogoniolithon frutescens
Spongites sulawensis
Spongites sp.
Pneophyllum conicum
Lithophyllum acrocamptum
L. acrocamptum
laminar Spongites sp.
L. cuneatum
L. cuneatum
Lithophyllum acrocamptum (= L.
incrassatum)
L. insipidum
L. insipidum
Lithophyllum cuneatum
L. gr. kotschyanum
L. gr. pustulatum
Lithophyllum insipidum
L. prototypum
L. prolifer
Lithophyllum gr. kotschyanum
L. gr. pustulatum
laminar Lithothamnion sp.
Lithophyllum prototypum
L. prolifer
Mesophyllum sp.
Lithophyllum gr. pustulatum
laminar Lithothamnion sp.
Lithothamnion prolifer
M. erubescens
laminar Lithothamnion sp.
M. funafutiense
Mesophyllum erubescens
Mesophyllum funafutiense
Sporolithon sp.
Total=22
Total=19
Total=16
and drainage basin (Papenoo R.) is responsible for the removal of 24.6x10-2 km3 kyr-1 of debris
- more than ten times the erosion rate of drainage basins near Maraa (Rougerie et al., 1992).
Fossilized microbialites that encase the corals from the last deglaciation contain more terrestrial
volcanoclastic grains at Tiarei than Maraa, suggesting this is also the trend historically (Camoin et
al., 2007a; Westphal et al., 2009). he reduced efect of river discharge in Maraa is apparent by the
frequency of tabular and branching Acropora (cA5) in cores (e.g., M0007A, M0017A, M0015A/B;
Figure 3.5) and may also play an important role in the diferential diversity observed between the
north-eastern and south-western sides of the island.
83
Abbey 2011
he total species richness of coralline algae in the deglacial reefs in Tahiti, twenty-eight species,
resembles the highest records of present-day reefs in the Paciic and Indian oceans. his number
only refers to coralline species with thalli thicker than 20 μm (see Results 3.3). Adey et al. (1982)
reported twenty-seven species in the Hawaiian Islands (sampling down to 85 m); Verheij (2010)
found twenty species in the upper 65 m in the Spermonde Archipelago in Indonesia; Iryu et al.
(1995) identiied nineteen species (sampling down to 50m) in the Ryukyu Islands; and South &
Skelton (1976) and N’Yeurt et al. (2003) reported twenty-one and seventeen species, respectively,
from the Fiji Islands with no indication of sampling depth limit. he reported species numbers
in present-day reef areas are patently afected by taxonomic procedures and sampling depth (and
probably the surveyed area) and, thus, other accounts record substantially lower species richness.
here is a markedly higher coralline algal diversity in the Acropora-dominated palaeoenvironments
in the deglacial reefs in Tahiti. A total of twenty-three species can be identiied in samples within
the encrusting coral of assemblages cA4 and cA5 in Maraa, while only sixteen species occur in
coeval reef framework in Tiarei (Table 3.5). In a similar pattern, only twenty coralline species
have been found in the reef framework dominated by branching Porites (cA3), which developed in
Maraa inner sites before the dominance of Acropora.
Abundance of crustose corallines in the Great Barrier Reef strongly depends on sediment inlux
and water clarity (Amini et al., 2004). Similarly, in Mediterranean Messinian reefs, species
richness is much higher in reefs facing the open oceans than in reefs in intermontane basins
afected by river discharge of terrigenous sediment (Davies et al., 1988). he high species richness
of corallines in Maraa observed to be associated with the low-tolerance Acropora assemblage (cA5)
in cores supports the notion that these algae were sensitive to the poor water quality of Tiarei
during deglaciation.
3.5.3
Coralgal assemblage variations in time
Coralgal assemblage variations occur as vertical transitions from cA1 to cA7 and aA1 to aA4. Reverse
transitions occur, but only between cA2 to cA6 and aA1 and aA2. Based on our understanding
of the modern analogs of the coralgal assemblages, these community transitions within a core
may represent the response of reef growth to changing palaeo-environmental conditions (e.g.,
sea-level rise puts communities at greater depth leading to dominance of depth-tolerant coralgal
assemblages), but vertical assemblage transitions may also be produced by ecological succession
and vertical reef accretion, or lateral growth during sea-level still stands (backstepping and/or
84
Chapter 3
progradation, i.e., Walther’s Law).
Individual assemblages form extensive vertical intervals within cores at all sites, suggesting long
periods of stable palaeo-environmental conditions on Tahiti. For example, branching Porites (cA3)
develops through more than 12 m of nearly uninterrupted core recovery in M0023A (Figure 3.6).
his is consistent with previous observations of continuously shallow reef assemblages spanning
11 ka to present in Papeete Harbor (Scoin, 1981).
he depth range of Assemblage aA3 partly overlaps those of aA2 and aA4, but adds a certain
degree of resolution to the palaeo-depth interpretation, which cannot be attained with the
species characteristic of the other assemblages. Its identiication in Maraa probably relects a
higher development of deeper reef-framework facies before the drowning of the reef in this area
compared to Tiarei.
3.5.4
Palaeo-environmental variations during the last deglaciation
he ecological characteristics of deglacial reefs on Tahiti are variable based on the initial depth of
the Pleistocene basement, the local hydrodynamic energy regime and local water quality – these
factors are discussed below in the context of reef initiation, growth and death.
3.5.4.1
Deglacial reef initiation
he initial communities to occupy the Pleistocene basement were variable both between sites
and within sites due to a range of optimum to sub optimum substrates. Shallow water and/
or high-energy coralgal assemblages (cA1 and cA3, aA1 and aA2) formed on most basement
substrates in Tiarei (Figure 3.6) and also in the inner, upslope substrates in Maraa (Figure 3.7), yet
intermediate depth and lower-energy massive Porites (cA2, aA2) formed on the outer substrates
in Maraa. his discrepancy in palaeo-water depth of 5 to 10 m between the pioneer communities
suggests that while deglacial reef initiation took place rapidly and in shallow palaeo-water depths
in Tiarei and in the inner Maraa holes, reef initiation occurred with some delay and therefore in
deeper palaeo-water depths in the outer Maraa holes. We argue that the nature of the Pleistocene
basement substrate may have inluenced this variable composition of the initial colonizing
coralgal assemblages between sites. In cores where branching corals (cA1, cA3) are the pioneer
communities (all Tiarei sites and Maraa sites M0007A, M0015A/B, M0017A), the substrates
are mainly composed of coralgal bindstone, coral framework or large coral debris. hese substrate
types appear to be ideal for the development of the high-energy and shallow coralgal assemblages
85
Abbey 2011
on Tahiti’s windward margin and shallow communities on Maraa’s inner leeward margin, but
unfavourable substrates of loose sand and rudstones may have retarded reef initiation in the outer
Maraa holes.
3.5.4.2
Deglacial reef growth
Following reef initiation on Tahiti, most coral assemblages between ca. 120 and ca. 110 mbsl
developed in somewhat deeper conditions as indicated by the prevalence of massive Porites (cA2)
and scarcer algae crusts (aA2). A shallowing-upwards sequence begins at ca. 110 mbsl with the
development of extensive branching communities (cA3).
he alternating pattern of branching (cA3 and cA4), tabular (cA5) and branching-encrusting
corals (cA6) between ca. 110 mbsl and the bottoms of the drowning sequence suggests that palaeoenvironmental conditions (turbidity, energy, salinity) may have luctuated near the tolerance limits
of the diferent coral assemblages. However, where associated algae have been identiied, palaeowater depths can be constrained to no deeper than 20 m, and often less than 10 m (Figure 3.6,
3.7). hese shallow- to intermediate-depth (0-20 m) reefs are variable in cores, accreting up to
10 m or more in some places to a maximum height of ca. 80-85 mbsl on Tiarei’s outer ridge and
Maraa’s outer holes.
he consistent appearance of Acropora within assemblages (especially sites M0007A, M0017A,
M0015A/B) and the increased coralline species richness from ca. 90 mbsl and ca. 12.5 ka to
the tops of cores could indicate improving water quality through time. Records of palaeoclimate
variability, particularly precipitation, are scarce in the central subtropical Paciic Ocean. However,
data from the main Hawaiian Islands indicate that climate may have varied considerably during
the early deglacial (Last Glacial Maximum to 10 ka), especially precipitation ( Johnson and Searle,
1984). Deglacial pollen records from Oahu indicate a dramatic increase in rainfall (ca. 200%)
beginning ca. 17 ka that was sustained until ca. 13 ka before returning to present levels after this
time. Similarly high rainfall on Tahiti during this interval may have reduced salinity and increased
turbidity, leading to the observed reduction in species richness.
he appearance of Acropora at 12.5 ka seems to be consistent with that seen in the Papeete cores,
however, a brief period of Acropora growth took place at an earlier interval as well, around 13.75
ka (Scoin, 1981; Bard et al., 1996; Cabioch et al., 1999a). he timing of the Acropora appearance
is coincident with or subsequent to local oceanographic and atmospheric changes, but it is
86
Chapter 3
unclear if these changes had a direct relationship with the shift in the coral communities. Recent
palaeoclimate work on Tahiti corals suggests that from 12.7 to 9.8 ka (Inoue et al., 2010) water
temperatures were likely 2-4 °C cooler than modern and 1-2 °C cooler than 14.2-13 ka (Cohen,
2004; Asami et al., 2009; Inoue et al., 2010). his indicates that cooler water temperatures did
not hinder profuse Acropora growth in Tahiti, which was coincident with minimum recorded SST
values. Data from Inoue et al. (2010) also suggest higher variability and slightly higher average
values of nutrient content of Tahiti waters from 12.7 to 9.8 ka. Such variations did not afect the
persistent development of Acropora after ca. 12.5 ka.
3.5.4.3
Deglacial reef death
Deep-water coralgal communities (cA7, aA4) replace shallow assemblages in Tiarei at the tops
of cores ca. 11 ka on the inner ridge, though the timing on the outer ridge is unknown (Figure
3.6). Some algal transitions suggest the deepening was abrupt, most notably in M0021A and B
where shallow H. onkodes and Mastophora (aA1) occur at ca. 85 mbsl, immediately prior to deepwater coralgal assemblages (cA7 with aA4). In Maraa, deep-water assemblages begin forming at
the tops of cores between 85-80 mbsl in outer cores (cA7 with aA3 and aA4), and 70-55 mbsl in
inner cores (cA7 with aA4). Two Maraa cores (M0007A and M0016A) show a stratigraphically
extended transition from shallow (<10m) to intermediate (15-30 m) to deep (>20 m), suggesting
the change in palaeo-water depth occurred over a somewhat longer time period than is indicated
in Tiarei cores (Figure 3.7). his discrepancy in palaeo-water depth signals may also be attributed
to variable hydrodynamic and oceanographic conditions between the south-western and northeastern sides of the island.
3.6
Conclusions
Based on a detailed examination of the stratigraphic and spatial coralgal assemblage variation in
Tiarei and Maraa, and in comparison with previously published coralline algae records, we draw
the following conclusions:
1. Seven coral assemblages and four algal assemblages are present in the fossil reefs of Tahiti.
In comparison with analogous modern and fossil assemblages, their palaeo-environmental
settings can be identiied and represent shallow upper reef slope (<10 m), intermediate (1020 or 15-30 m) and deep forereef slope (>20-30 m).
2. Reef initiation was variable across sites and community composition was dependent upon
87
Abbey 2011
the available substrate, those composed of reef framework and large rubble being the most
optimum for rapid colonization.
3. he low abundance of Acropora in Tiarei and in the outer cores of Maraa suggests that
early conditions were unsuitable for sensitive reef builders on Tahiti, especially in Tiarei due
to the inluence of the Papenoo River. However, conditions were suiciently improved by
13-12 ka for Acropora to thrive and coralline algae to diversify, which may be explained by
reduced runof related to a transition into a drier climate on the island.
4. Reef response was characterised by incremental transitions between the assemblages,
with corals dominating throughout all cored intervals. he persistence of shallowwater and intermediate-depth coralgal assemblages indicates that the fossil barrier reef
developed near sea-level for much of the last deglaciation. his suggests that variations in
coralgal assemblages developing from 15 ka to 12 ka may be more strongly inluenced by
environmental factors associated with sea-level rise (e.g., turbidity, water chemistry), rather
than simply its deepening efects.
5. In all cases in Tahiti’s submerged terraces, reef growth was terminated and cores are capped
by distinctly deep-water coralgal assemblages, characteristic of deep reef growth and
imminent drowning. Whether or not this drowning took place contemporaneously across
all sites will be determined as more detailed chronology is presented.
3.7
Acknowledgements
his research used samples and data provided by the Integrated Ocean Drilling Program (IODP).
We wish to acknowledge the Expedition 310 Scientists, as well as Bremen Core Repository
members for support and collaboration during ofshore/onshore parties. We would like to thank
the support of ANSTO, including Geraldine Jacobsen and technicians for assistance with AMS,
and Gordon horogood for support with XRD analyses. Funding was provided to E.A. by the
School of Earth and Environmental Sciences at James Cook University, the School of Geosciences
at the University of Sydney, the Australian Institute of Marine Science in a partnership with James
Cook University (AIMS@JCU), the Australian Institute for Nuclear Science and Engineering
(AINSE) and the Australian Nuclear Science and Technology Organisation (ANSTO). J.M.W.
was provided support from James Cook University as part of a New Staf Development Grant
and by the University of Sydney. Financial support was issued to Y.I. in part by grants-in-aid for
88
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scientiic research, Japan Society for the Promotion of Science (18340163).
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Abbey 2011
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