E-ISSN : 2541-5794  
P-ISSN : 2503-216X  

Journal of Geoscience,  

Engineering, Environment, and Technology 
Vol 6 No 2 2021 

 

 
Widiatama et al./ JGEET Vol 6 No 2/2021  86 

 

RESEARCH ARTICLE 
 

Calcareous Nanofossil of Post-Gondwana Sequence in Southern 

Banda Arc, Indonesia 

Angga Jati Widiatama1*, Lauti Dwita Santy2, Rikza Nur Faqih An Nahar1, Zulfiah3, Winda 

Eka Mandiri Puteri3, Adrianus Damanik3, Rubiyanto Kapid3 
1Geological Engineering, Institut Teknologi Sumatera, South Lampung, 35365, Indonesia. 

2Geological Survey Center, Geological Agency, Ministry of Energy and Mineral Resources, Bandung, 40122, Indonesia. 
3 Geological Engineering, Institut Teknologi Bandung, Bandung, 40132, Indonesia. 

 

* Corresponding author : angga.widiatama@gl.itera.ac.id 

Tel.:+62-856-0629-2290 

Received: Jan 23, 2021; Accepted: May 24, 2021. 

DOI: 10.25299/jgeet.2021.6.2.6287 

 
Abstract 

The presence of calcareous nannofossils in samples of the Post-Gondwana sequences (Kolbano and Viqueque sequence) gives guidance 
about the relative age of the study area located in the Outer Banda Arc, namely Timor, Rote, and Sawu Island. The study was carried out on 

six traverses, Timor Island traverse (Baun and Camplong), Rote Island traverse (Termanu and Central Rote), and Sawu Island traverses (West 

Sawu and East Sawu). There is 29 outcrop sample prepared using the smear slide method and observed using a polarizing microscope with 
1000x magnification. The results of the study showed the presence of Cretaceous, Paleogene, and Neogen-Quarternary calcareous nannofossil. 

There are 82 species from 14 families identified in the post-Gondwana sequence. The results showed that the assemblage of calcareous 

nannofossil in Cretaceous characterized by the presence of Watznaueria fasciata, Watznaueria cynthae, Cyclagelosphaera brezae, Orastrum 
campanensis, and Micula concava. The assemblage of Paleogene calcareous nannofossil characterized by the presence of Coccolithus staurion, 

Chiasmolithus solitus, Discoaster minimus, Tawelus (?) magnicrassus, Chiasmolithus bidens, Prinsius africanus, Cyclicargolithus luminus, 

Spenolithus elongatus, Reticulofenestra umbilica, Cruciplacolithus vanheckae, and Helicospharea seminulum, and the assemblage of Neogene 
calcareous nannofossil characterized by the presence of Reticulofenestra pseudoumbilica, Discoaster quinqueramus, Helicosphaera princei, 

and Discoaster pansus. Quarternary calcareous nannofossil characterized by the presence of Ponthospaera indooceanica. 

 
Keywords: Calcareous Nannofossil, Kolbano Sequence, Banda Arc 

 

 

  

1. Introduction  

Timor, Rote, and Sawu Island are located in the outer 

Banda Arc formed by the collision between the edges of the 

Australian continent and volcanic Banda Arc (M.G, 2004; 

Villeneuve et al., 2004). Timor Island and its surrounding 

area litotectically divided into five major groups (Fig. 1); 

(1) Gondwana sequences, Permian to Jurassic,  containing 

siliciclastic rocks deposited in the intracratonic basin, (2) 

Kolbano sequence containing siliciclastic rock and pelagic 

carbonate from late Jurassic to Neogene, (3) Banda terrain 

which is part of Asia that has been uplifted due to collision 

during Late Neogen. (4) Bobonaro Melange contains 

melange with blocks in clay, broken formation, and mud 

domes formed during the collision in the late Neogen, (5) 

Viqueque sequence which is synorogenic deposits which 

are relatively undeformed (Barber et al., 1977; Carter et al., 

1976; Harris et al., 1998; M.G, 2004; Villeneuve et al., 

2004). Kolbano sequence contains siliciclastic and pelagic 

carbonate consisted of the Nakfunu, Menu, Ofu, and 

Batuputih Formation. While the Viqueque sequence 

consists of the Viqueque Formation and Quarternary 

deposits. 

The Nakfunu Formation (Sawyer, 2018; Suwitodirjo, 

1996) is identical to the Wai Bua Formation in Timor Leste 

(Audley-Charles, 1968) that the lithology consists of chert, 

claystone, calcilutite, shale, calcarenite, wackestone, and 

packstone. One of Nakfunu Formation characteristics is the 

consistency of layer thickness which ranges from 3 to 30 

cm with sharp contact, flat to wavy. Shale units can be thin 

or massive layers, black with iron and manganese nodules. 

Sedimentary structures are rarely found in the Nakfunu 

Formation except for laminates. The Nakfunu Formation is 

deposited during marine transgression of Early Cretaceous 

in the distal continental rise or abyssal near or below the 

CCD (Sawyer, 2018).  

Sawyer et al. (2018) described Menu Formation 

consisting of Cretaceous rocks from Early to Late 

Cretaceous which have lithological characteristics in the 

form of red-pink to white calcilutite limestone layers. Some 

layers are pelecypods wackestone, layered between 6 to 60 

cm, the layer is sharp, there are also 1-2 cm red chert layers 

with an intensive joint. Menu Formation in Rote Island was 

exposed in several areas including Baa, Termanu, and 

Papela. 

The dominant lithology of Ofu Formation is white to 

pink massive limestone concoidal-subconcoidal fractures 

and looks shiny like porcelain on a fresh surface. There are 

laminates and intensive pressure solutions resulted in 

calcite veins in stylolites and fractures. Updated 

biostratigraphy from existing formations and distinguished 

three mapped units, Boti, Borolalu, and Oeleu members. 

The lithology consists of pelecypods-foraminifera 

wackestone; quartz packstone or foraminifera packstone; 

and turbidite conglomerates layered with angular fragments 

from Menu Formation or Ofu Formation. The age of this 



 
Widiatama et al./ JGEET Vol 6 No 2/2021 87 

 

unit is Lutetian phase in the Middle Eocene to the Early 

Pliocene (Sawyer, 2018). 

The Plio-Pleistocene series is aimed for syn-orogenic 

sediments known as Viqueque Sequence [8] or the 

Batuputih Formation (Sawyer, 2018; Suwitodirjo, 1996). 

This includes the equivalent of Viqueque, Batuputih, and 

Noele Formation in West Timor. The lithology of Batuputih 

Formation mainly consists of white massive calcilutite or 

chalky limestone with light grey marl and often with plant 

fragments. This unit is soft to hard and the layer is less 

visible. The tuffaceous layer is very rare outside the type 

location even though vitric glass fragments are often found. 

Coarse bioclastic and clastic allogens are found in the 

interlocking parts with Noele Formation. 

Viqueque Formation consists of coarsening upward 

from chalky limestone and calcilutite to sandstones covered 

by Quaternary gravel and reef limestones. The Viqueque 

Formation appears in the Central Basin in west and south of 

the Kolbano unit that was imbricated. The Noele Formation 

shows lithological variations reflected rapidly uplift and 

topographic variations in depositional environments. The 

lithology includes marl, carbonate claystone, tuffaceous 

marl, tuffaceous calcilutite, white-yellow glass tuffs, 

biocalcarenite, siltstone, sandy limestone, dark grey marl, 

and sandstone. As for differences with Batuputih 

Formation, calcilutite and chalky limestone are rarely 

found. 

 
Fig 1. Stratigraphy column of research area from various author  

2. Material and Method 

The objective of this study is identify calcareous 

nannofossil in post-Gondwana sequences (Kolbano and 

Viqueque sequence) and to determine the relative age based 

on calcareous nannofossil in islands around southern Outer 

Banda Arc. Field data collection carried out in the survey 

activities of the Sawu basin included three islands, Timor, 

Rote, and Sawu. The research conduct by the Geological 

Survey Center, Geological Agency, Ministry of Energy, 

and Mineral Resources in 2014. The research data including 

six traverses (Fig. 2) Timor Island Traverse (Baun and 

Camplong), Rote Island Traverse (Termanu and Central 

Rote), and Sawu Island Traverse (West Sawu and East 

Sawu). Data collection includes stratigraphic 

measurements, descriptions of megascopic rocks, 

microscopic descriptions, and paleontology of calcareous 

fossils. 

There are 29 calcareous nanofossil samples prepared by 

the smear slide method and observed using a polarizing 

microscope with 1000x magnification. The age 

determination of Cenozoic calcareous nannofossil based on 

Martini’s zone (Martini, 1970) while the Mesozoic zone 

based on Bown and Cooper zonation (Bown and Cooper, 

1998). 

 
Fig. 2 Map of research area (A) Timor Island Traverse, (B) Rote Island Traverse, and (C) Sawu Island Traverse 



 
88  Widiatama et al./ JGEET Vol 6 No 2/2021   
 

3. Geology research area 

3.1 Timor Island 

There are two observation points of Camplong 

Traverse, 14AJW06, and 14AJW07 (figure 2A). The 

outcrop is on Trans Timor road near Mina River bridge with 

a length of 50 meters and a height of 20 meters. Lithology 

consists of a layering of tuffaceous limestone, chalky 

limestone, foraminifera grainstone, marl, and 

conglomerates. The measured section column is shown in 

figure 4A. The lower part of the outcrop consists of light 

white tuffaceous-chalky limestone layering, having 

intensive joint, 20-30 layer thickness, medium compacting 

with parallel lamination. The age is not older than 

Burdigalian (NN4) to Tortonian (NN 10), which 

characterized by the first appearance of the Reticulofenestra 

pseudoumbilica until the first appearance of Discoaster 

quinqueramus. The middle section consists of chalky 

limestone turning into intercalation of foraminifera 

grainstone-marl with an erosive layer contact (figure 3A). 

White foraminifera grainstone has medium compacting, 

bioclastic components, insitu planktonic foraminifera, and 

rework foraminifera, bivalves, juvenile Mollusca, 

tuffaceous, with plagioclase and quartz as additional 

components. Marl dominant forms of carbonate mud with 

planktonic foraminifera as the main bioclastic. Marl and the 

foraminifera grainstone have erosional contact. 

 

Fig. 3  Post-Gondwana sequence outcrop (A) Intercalation of 

foraminifera grainstone and marl, (B) Amonite limestone, (C) 

Calcilutite and chert intercalation, (D) Trace fossils of Chondrites 
and Planolites in calcilutite, (E) Neogene orange calcilutite in 

Rote Island, (f) Paleogene calcilutite in Sawu Island, (G) Layer of 

foraminifera grainstone with flutecast at the lower part of the 
layer, and (H) Calcilutite with fissile structure. 

Based on calcareous nannofossil foraminifera 

grainstone is Tortonian-Messinian (NN 11) characterized 

by the presence of Discoaster quinqueramus. The upper 

part of the outcrop is an unconformity between foraminifera 

grainstone -marl intercalation cut by conglomerates with 

Quarternary matrix.  Based on nannofossil on the matrix 

shown NN20 zone or younger which characterized by the 

first appearance of Ponthospaera indooceanica. 

There are three observation points of Baun Traverse, 

14LS138, 14LS143, and 14LS145 (figure 2A) located in 

Bihati River, Baun is composed of broken formation of 

ammonite limestone, calcilutite, foraminifera grainstone, 

and basalt. The measured section columns are shown in 

figures 4A and 4B. Ammonite limestone (figure 3B) is 

reddish-white, poorly sorted, high compaction, consists of 

Ammonite sp., Crinoid sp., Halobia sp., and Atomodesma 

sp. a distinctive characteristics of Gondwana sequences of 

Permo-Triassic rocks that have a fault contact with a post-

Gondwana sequence. The Kolbano sequence consists of 

pale pinkish calcilutite and pale white calcilutite with 

parallel lamination and firm layer contact. Late Cretaceous 

nannofossil zone from the Santonian-Campanian (UC 11-

UC 15)  characterized by first the appearance of the 

Orastrum campanensis and Micula concava in the lower 

part of the section until the last appearance of Orastrum 

campanensis in the upper part of measured stratigraphy 

section. In the upper reaches of Bihati River also found 

well-lamination of white foraminifera grainstone, consist of 

20-30 layer thickness, medium compacting with parallel 

lamination. Burdigalian-Tortonian age (NN 4-NN 10) 

characterized by the first appearance of Reticulofenestra 

pseudoumbilica appearance until the first appearance 

Discoaster quinqueramus. These units are unconformity 

overlap of ammonite limestone and calcilutite with fault 

contact. 

 3.2 Rote Island 

Termanu traverse consists of three observation points, 

14AJW18, 14AJW19, and 14AJW20 in Tanjung Termanu 

(figure 2B). The measured section column is shown in 

figure 4D. Outcrops consist of calcilutite, chert, and marl 

with radiolaria as the dominant bioclastic component. 

Limestone is relatively thickening upward, while the chert 

is relatively thinning upward (figure 3C). Based on 

calcareous nannofossil in the lower part of the Tanjung 

Termanu section, the age shows Early Cretaceous between 

Berriasian and Valanginian (NC2 - NC3) is marked by the 

first appearance of Cyclagelosphaera brezae, Watznaueria 

fasciata, and Watznaueria cynthae until the last appearance 

of Cyclagelosphaera brezae. In the central part of the 

Termanu traverse (14AJW20) above the intersection of 

calcilutite, chert, and marl, the chert layer tends to become 

more dominant calcilutite and marl, parallel lamination, 

consist of ichnofossil such as Chondrites, Planolites, and 

Zoophycos (figure 3D). The age of rocks is Early 

Cretaceous, Hauterivian to Aptian (NC5 - NC7) based on 

the last appearance of Cyclagelosphaera brezae until the 

last appearance of Watznaueria fasciata. The upper part of 

the Termanu traverse is Late Cretaceous from Albian to 

Coniacian (NC 8-UC 10)  marked by calcilutite 

characteristic changes of color from pink to orange. The 

lower part of this zone is marked by the first appearance of 

Watznaueria fasciata, the upper part is marked by the first 

appearance of Orastrum campanensis and Micula concava. 

Central Rote Traverse (figure 2B) located in Central 

Rote (14AJW16, 14LS130, and 14LS133) to Papela Beach 

(14AJW12). The outcrop on Papela Beach is characterized 

by calcirudite limestone with unoriented Mollusca shell 

fragment as the main component and associated with 

manganese boulder and quartz sandstones. The outcrop 

consists of a broken formation, surrounded by the scaly clay 

mélange Bobonaro. The presence of  Watznaueria fasciata 



 
Widiatama et al./ JGEET Vol 6 No 2/2021 89 

 

indicates Early Cretaceous between Berriasian and Aptian 

(NC2-NC7). Outcrops at the observation point 14LS130, 

14LS133, and 14AJW16 can be divided into four zones. 

The lower part (zone 1) consists of red to orange 

foraminifera grainstone, well layered, 10-20 cm layer 

thickness, medium compacting, fissile structure, and 

parallel lamination, Burdigali-Tortonian age (NN4 - NN 

10) marked by the first appearance of the Reticulofenestra 

pseudoumbilica until the first appearance of Discoaster 

quinqueramus. The middle zone (zone 2) consists a layer of 

red to orange calcite limestone (figure 3E), with dominant 

foraminifera bioclastic component. The age shows 

Tortonian-Messinian age (NN 11) characterized by the first 

appearance of Helicosphera princei and Discoaster 

quinqueramus until the last appearance of the Discoaster 

quinqueramus. Conformable grayish-white grainstone 

foraminifera (zone 3) overlay zone 2, interspersed with 

layers of tuffaceous lapilli limestone and plant fragments, 

with medium compacting, the age indicated Messinian-

Zanclean (NN 12-NN 15) marked by the first appearance of 

Discoaster pansus until the last appearance of the 

Discoaster pansus. The upper part (zone 4) is foraminifera 

limestone with poorly lamination, medium compaction, 

overlay with foraminifera grainstone. The aged are 

Pliocene-Pleistocene (NN16 - NN21) characterized by the 

last appearance of the Discoaster pansus until the last 

appearance of Dictyococcites productus and Helicosphaera 

princei. The measured section column is shown in figure 

4C. 

 

Fig. 4  Measured stratigraphic correlation and biozonation of calcareous nannofossil in Timor Island (A and B), Rote Island (C and D), and 

Sawu Island (E). 

3.3 Sawu Island 

West Sawu traverse (figure 2C) consists of four 

observation points (14SH103, 14SH104, 14SH108, and 

14SH121). The West Sawu traverse consists of the 

foraminifera grainstone at the lower part that gradually 

becomes calcilutite at the top. Foraminifera grainstone is 

white, dominated by planktonic foraminifera, with minor 

benthonic foraminifera, erosional contact at some layer, 

graded bedding, flute cast, forming channel geometry, and 

lateral thinning layer. The aged are Thanetian (NP9) tagged 

by the first appearance of Coccolithus staurion and 

Chiasmolithus solitus to Ypresian (NP11) that labeled by 

the last appearance of Discoaster minimus and Tawelus (?) 

magnicrassus. It is also indicated by presence of 

foraminifera Globigerinatheka sp. As Paleogene marker. 

Foraminifera grainstone gradually changed to red calcilutite 

with parallel lamination, 5-15 cm layer thickness. 

Petrographically, calcilutite is a foraminifera wackestone to 

foraminifera mudstone. The age is from Yalcian (NP11) to 

Lutetian (NP15) marked by the first appearance of 

Chiasmolithus bidens until the last appearance of 

Coccolithus staurion and Cyclicargolithus luminus. The 

measured section column is shown in figure 4E. 

East Sawu Traverse (figure 2C) consists of three 

observation points (14LS110, 14LS112, and 14LS113). 

The East Sawu traverse consists of foraminifera grainstone 

at the lower part gradually becomes calcilutite at the top 

with implied chert (figure 3F). Foraminifera grainstone 

characterized by an erosive contact with layer below it, 

layered 15 cm in thickness, graded bedding, parallel 

lamination, flute cast (figure 3G), and forming a channel 

geometry in lateral. Foraminifera grainstone is Danian 

(NP2), which is tagged by the presence of Prinsius 

africanus and also the presence of foraminifera 

Globigerinatheka sp. as a marker of Paleogene. 



 
90  Widiatama et al./ JGEET Vol 6 No 2/2021   
 

Foraminifera on grainstone originates from foraminifera in 

situ and rework deposited. On top of foraminifera 

grainstone gradually turns into red calcilutite, the thin layer 

of 5-10 cm, with parallel lamination and scaly structures 

(figure 3H). Based on the petrographic observations of 

calcilutite composed foraminifera wackestone to 

foraminifera mudstone. Calcilutite indicated Ypersian 

(NP14) to Lutetian (NP15) based on the presence of 

Spenolithus elongatus. In the East Sawu travers, limestone 

characterized by the first appearance of the Reticulofenestra 

umbilica and the last appearance of Cruciplacolithus 

vanheckae, Chiasmolithus solitus, and Helicosphaera 

seminulum indicated age of Middle Eocene (Lutetian to 

Bartonian/NP16), that overlapped with chert layer with 

bioclastic component like bivalve shells and radiolaria. 

4. Discussion 

Correlations of measured section columns of Timor, 

Rote, and Sawu showed in figure 4. The Southern Outer 

Banda Arc consist of 20 zones of calcareous nanofossil 

biostratigraphy (figure 5). Gondwana and post-Gondwana 

sequences are characterized by break-up unconformity that 

occurs in the Early Cretaceous (Baumgartner, 1993). 

Calcareous nanofossil of Cretaceous Kolbano sequences 

consisted of four families and 17 species (Table 1). 

The Watznaueriaceae family has the most species 

diversity with twelve species, Holococcoliths with four 

species, Family Biscutaceae with one species, and 

Polycyclolithaceae with only species. Menu Formation 

aged Early Cretaceous, NC2-NC3 zone with the first 

appearance of Cyclagelosphaera brezae, Watznaueria 

fasciata, and Watznaueria cynthae in Berriasian to the last 

appearance of Cyclagelosphaera brezae in Valanginian. 

Late Cretaceous (Santonian/UC11) Menu Formation is 

characterized by the first appearance of Orastrum 

campanensis and Micula concava. Late Cretaceous 

nannofossil dominated by the Calculites genus. Cretaceous 

nanofossil showed in figure 6. 

 

Fig. 5  Biostratigraphy chart of calcareous nannofossil Post-Gondwana sequence in the Banda Arc. 



 
Widiatama et al./ JGEET Vol 6 No 2/2021 91 

 

TABLE 1. DIVERSITY OF CRETACEOUS CALCAREOUS 

NANOFOSSIL 

No Calcareous nanofossil No Calcareous nanofossil 

  Family Biscutaceae 8 Cy. deflandrei  

1 Discorhabdus ignotus 9 Cy. margerelii 

  Family Holococcoliths  10 
Watznaueria 

barnesiae 

2 Aspigolithus parcus 11 Wz. biporta  
3 Calculites obscurcus 12 Wz. britannica  

4 Calculites ovalis 13 Wz. cynthae 

5 Orastrum campanensis 14 Wz. fasciata 

  
Family 

Polycyclolithaceae 
15 Wz. fossacincta 

6 Micula concava 16 Wz. manivitiae 
  Family Watznaueriaceae 17 Wz. ovata 

7 
Cyclagelosphaera 

Brezae 
  

 

 

Fig. 6  Cretaceous calcareous nannofossil, scale bar 5 μm.: 

(1) Aspigolithus parcus; (2) Calculites obscurcus; (3) Calculites 

ovalis; (4) Cy. Brezae; (5) Cy. deflandrei; (6) Cy. margerelii; (7) 
Discorhabdus ignotus; (8) Micula concava; (9) Orastrum 

campanensis; (10) Wz. barnesiae; (11) Wz. biporta; (12) Wz. 

britannica; (13) Wz. cynthae; (14) Wz. fasciata; (15) Wz. 
fossacincta; (16) Wz.  manivitiae; (17) Wz. manivitiae; (18) 

Wz.ovata.  

The Paleocene to Miocene sediment of the Kolbano 

sequence is grouped in the Ofu Formation, in the form of 

a graded foraminifera grainstone into calcilutite. 

Paleogene Calcareous nannofossil of Kolbano sequence 

consisted of eight families and 31 species (Table 2). 

Coccolithaceae family has fifteen species, 

Noelaerhabdaceae as many as three species, 

Sphenolithaceae has three species, Prinsiaceae composes 

three species, Pontosphaeraceae as many as two species, 

Watznaueriaceae consist of two species, Discoasteraceae 

has two species, and Helicosphaeraceae as many as one 

species. Prinsius africanus is an index fossil of the Danian 

(NP2). The beginning of the Eocene started by the 

appearance of Chiasmolithus bidens (Ypresian / N11). 

Eocene nannofossils dominated by Coccolithus, 

Chiasmolitus, and Reticulofenestra genus. The upper limit 

of the Eocene (Eocene-Oligocene transition) marked by 

the last appearance of Ericsonia orbis and 

Cruciplacolithus edwardsii. Paleogene nannofossil 

selected showed in figure 7. 

TABLE 2. DIVERSITY OF PALEOGENE CALCAREOUS NANOFOSSIL 

No Calcareous nanofossil No 
Calcareous 
nanofossil 

Family Coccolithaceae Family Helicosphaeraceae 

1 Chiasmolithus bidens  19 H. seminulum 

2 Ch. consuetus  Family Pontosphaeraceae 
3 Ch. nitidus 20 P. cf. Scisurra 

4 Ch. solitus  21 P. diamorphosus  

5 Coccolithus formosus Family Sphenolithaceae 

6 Co. hulliae  22 

Spenolithus cf. 

spiniger 

7 Co. pauxillus  23 S. radians 
8 Co. pelagicus 24 S.  Elongatus 

9 Co. staurion Family Watznaueriaceae 

10 
Cruciplacolithus 
edwardsii  25 Cy. reinhardtii  

11 Cr. primus  26 Cy. luminis  

12 Cr. tenuis  Family Prinsiaceae 
13 Cr. vanheckae 27 Prinsius africanus  

14 Ericsonia orbis  28 P. tenuiculum  

15 E. subpertusa  29 
Toweius 
magnicrassus 

Family Noelaerhabdaceae Family Discoasteraceae 

16 
Reticulofenestra cf. 
ornata 30 Discoaster minimus  

17 R. dictyoda 31 D. barbadiensis 
18 R. umbilica   

 

Fig. 7 Paleogene calcareous nannofossil in Sawu Island: (1) Ch. 

bidens; (2) Ch. solitus; (3) Co. formosus; (4) Co. hulliae; (5) Co. 

staurion; (6) Cr. edwardsii; (7) Cy. luminis; (8) D. barbadiensis; 

(9) D. minimus; (10) E. orbis; (11) H. seminulum; (12) Prinsius 
africanus; (13) R.umbilica; (14) S. elongatus; and (15) 

Tawelus(?) magnicrassus. Scale bar 5 μm. 

The Ofu Formation of Kolbano sequence continued 

until Miocene, that lithology predominantly contained the 

foraminifera grainstone with the insertion of calcilutite and 

tuff layers overlay by Viqueque Sequence which age is 

Quarternary. Neogene-Quarternary calcareous nannofossil 

in the study area consisted of eight families and 33 species 

(Table 3). The Discoasteraceae family has the most 

species diversity with twelve species, Noelaerhabdaceae 

with ten species, Calcidiscaceae with three species, 

Helicosphaeraceae with two species, Sphenolithaceae 

with two species, Coccolithaceae with two species, 

Pontosphaeraceae with one species, and Nannolith 

families inc sed with one species. The first appearance of 

the Reticulofenestra pseudoumbilica becomes the lower 

boundary of the Miocene age. Miocene nannofossils are 



 
92  Widiatama et al./ JGEET Vol 6 No 2/2021   
 

dominated by Discoaster, Coccolithus, Sphenolithus, and 

Reticulofenestra genus. The upper Miocene-Pliocene 

boundary was marked by the first appearance of the 

Discoaster pansus. Quarternary sediment is marked by the 

appearance of Ponthospaera indooceanica. Quarternary 

nanofossil is dominated by the genus Gephyrocapsa. 

Neogene-Quarternary nannofossil selected is shown in 

figure 8. 

Integration of sedimentology and paleontology data 

provides a comprehensive understanding of depositional 

environments. The calcilutite and chert show that the 

similarity of the constituent bioclastic in the form of 

radiolaria showing the relationship between the Menu 

Formation which is calcilutite dominant and the Nakfunu 

Formation containing hemipelagic siliciclastic rocks. The 

similarity of the dominant radiolaria bioclastic component 

indicates depositional environment is in the upwelling area 

(Bak, 2007; De Wever et al., 2014, 1994). Upwelling areas 

provide three conditions that increase the chances of 

preservation of silica-rich sediment deposits; (1) high 

nutrition in the upwelling area results in greater 

productivity of phytoplankton causing silica saturation due 

to the high productivity of radiolarian-rich deposits, (2) 

increasing the rate of organic material production below 

the upwelling zone implying a lower ratio of carbonate 

shelled organisms, (3) high organic components 

preventing dissolution of silica (De Wever, 1989; De 

Wever et al., 1994; 2014) 

The correlation among the Central Rote traverse in the 

form of pelagic Mollusca deposited as turbidite carbonates 

turned into calcilutite supported by radiolarian on the 

Termanu traverse indicated a change of depositional facies 

from slope to the basin floor. Pelagic carbonate deposition 

continues until the Late Cretaceous is shown to be similar 

in thickness to the calcilutite facies. 

TABLE 3. DIVERSITY OF NEOGENE-QUARTERNARY CALCAREOUS 

NANOFOSSIL 

No Calcareous nanofossil No Calcareous nanofossil 

Family Discoasteraceae 20 Dy. antarcticus  

1 

Discoaster 

asymetricus  
21 R. minuta 

2 D. berggrenii 22 R. pseudoumbilicus 

3 D. broweri Family Calcidiscaceae 

4 D. challengeri 23 Calcidiscus leptoporus 
5 D. deflandrei 24 Hayaster sp. 

6 
D. hamatus 25 

Umbilicosphaera 

rotula 
7 D. neohamatus Family Coccolithaceae 

8 D. neorectus  26 Coccolithus pelagicus 

9 D. pansus  27 Ericsonia cava 
10 D. pentaradiatus  Family Helicosphaeraceae 

11 D. quinqueramus 28 Helicosphaera princei 

12 D. variabilis 29 H. kamptneri 
Family Noelaerhabdaceae Family Sphenolithaceae 

13 
Dictyococcites 

productus 
30 Sphenolithus abies 

14 
Gephyrocapsa 

ericsonii 31 
S. neoabies 

15 Gy. oceanica Family Pontosphaeraceae 
16 Gy. carribeanica 32 P. indooceanica 

17 
Reticulofenestra 
producta 

Nannolith families inc sed 

18 R. pseudoumbilicus 33 Florisphaera profunda  

19 
Dictyococcites 
productus   

 

Sedimentary rock of the Ofu Formation in the 

Paleocene to Eocene show a change in pink and white. The 

character of the red limestone is identical to the 

widespread Oceanic Red Bed (ORB) deposit known as the 

low latency facies type in the Tethys Sea  (Cai et al., 2012; 

Hu et al., 2005; SCOTT et al., 2009). Red limestone 

caused by the presence of iron (Fe2+/Fe3+). According to 

Cai et al. (Cai et al., 2012, 2009, 2008) an authigenic 

hematite formed in calcite crystals is it not only on the 

surface of the rock but also throughout the limestone. The 

typical characteristic sediment of Ofu Formation is 

indicated by the repetition of the deposition sequence in 

the form of a foraminifera grainstone to calcilutite. 

Foraminifera grainstone deposited with a turbidite 

mechanism when decreasing the sea level, while calcilutite 

deposited during rising sea level to the maximum sea level. 

The sedimentary rocks of the Ofu Formation in the 

Miocene-Pliocene consist of a pink foraminifera 

grainstone that graded into white at the top. The 

dominance of the planktonic foraminifera indicates a more 

depositional environment towards the basin. The 

intersection of the foraminifera grainstone and marl 

indicates turbidity current control. The tuff and lapili 

components indicate the presence of explosive volcanism 

which become the source of volcaniclastic rocks originate 

from the Banda Arc. 

 

Fig. 8  Neogene-Quarternary calcareous nannofossil in Timor 

Island, bar 5 μm.: (1) C. leptoporus; (2) Hayaster sp.; (3) 

Umbilicosphaera rotula; (4) Co. pelagicus; (5) Helicosphaera 

kamptneri; (6) H. princei; (7) Dy. productus; (8) Gy. ericsonii; 

(9) Gy. oceanica; (10) R. producta; (11) R. pseudoumbilicus; 

(12) S. abies; (13) S. neoabies; (14) D. berggrenii; (15) D. 

neorectus; (16) D. broweri; (17) D. challengeri; (18) D. 

quinqueramus; (19) D. variabilis; (20) D. deflandrei; (21) D. 

neohamatus. Scale  

 

Fig. 9  Depositional environment model of post-Gondwana 

sequence in research area. 



 
Widiatama et al./ JGEET Vol 6 No 2/2021 93 

 

Pliocene-Quarternary rocks are deposits of the 

Viqueque sequences that form synorogenic in the collision 

between Banda Arc and Australian passive margin. Matrix 

supported Conglomerates indicate formation due to mass 

flow. The depositional environment model of the study 

area is illustrated in figure 9. 

5. Conclusion 

Calcareous nannofossil of Kolbano sequence 

identified 82 species from 14 families consist of 

Cretaceous, Paleogene, and Neogen age. The Cretaceous 

calcareous nannofossil assemblage consists of 18 species 

(Table 1) dominated by the Watznaueria and 

Cyclagelosphaera genus. The oldest index nanofossil in 

the Kolbano sequence is Berriasian based on the first 

appearance of Cy. brezae. The Paleogene calcareous 

nannofossil assemblage consists of 31 species (Table 2) 

dominated by Pontosphaera, Cruciplacolithus, 

Chiasmolithus, and Coccolithus genus with index 

nannofossil is Prinsius africanus, Danian (NP2). The 

beginning of the Eocene started with the appearance of 

Chiasmolithus bidens (Ypresian/NP11) and dominated by 

Coccolithus, Chiasmolitus, and Reticulofenestra genus. 

The Neogene-Quarternary calcareous nannofossil 

assemblage consists of 33 species (Table 3) dominated by 

Discoaster, Coccolithus, Sphenolithus, Reticulofenestra, 

and Gepyrocapsa genus. R. pseudoumbilica becomes the 

marker of Early Miocene (NN4-NN10), NN11 zone 

marked by the existence of D. quinqueramus and D. 

berggrenii. Quarternary (NN19 zone) characterized by the 

first appearance of P. indooceanica. 

Acknowledgements 

We like to thank the Geological Agency, the 

Indonesian Ministry of Energy and Mineral Resources for 

lending data, all members of the 2014 Sawu Basin Team 

who have helped in data collection, and all parties who 

have made suggestions to make this paper better. 

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