j. Natn. Sci. Coun. Sri Lanka 1985 13(2) : 213 - 226 

GEOLOGICAL SETTING AROUND THE HEADS OF THE 

TRINCOMALEE CANYON, SRI LANKA 

N. P. WIJAYANANDA 
Oceanography Unit, National Aquatic Resources Agency, Colombo 15, Sri Lanka. 

(Date of receipt : 0 9  October 1985)  
(Date of acceptance : 30 January 1986) 

Abstract : Detailed geologicd mapping was undertaken in the land around the heads 
of the Trincomalee Canyon, in an attempt t o  determine its probable origin. This 
Canyon is in alignment with the Mahaweli shear zone. I t  has the trend similar t o  the 
general strike of the country rocks and has three principal heads, one a t  the Trinco- 
malee inner harbour and two at the Koddiyar Bay. The head at  the inner harbour and 
the one south east of the bay probably follow a fracture zone. The River Mahaweli 
has played a major role in forming the two main heads and the sub-heads a t  the 
Koddiyar Bay. The survey reveals that the shape of the Canyon heads are controlled 
by the geology of the area. 

1. Introduction 

In 1908, Somerville first noted several deep and narrow notches in the 
submarine plateau off the east coast of Sri ~anka . '  The Trincornalee 
harbour is in one of these and during the two World Wars this harbour 
was of immense interest as it was found to  be an extraordinarily deep 
canyon. Several workers studied it at different times215 * 69'7 and 
confirmed it to be a large submarine canyon. 

~ h e ?  canyon has three main heads and these heads have cut into 
the land. Tbe Trincomalee inner harbour is in one and Koddiyar Bay is 
in the other two heads (Figures 2,5 and 6). Thus, since the land 
surrounds all these heads, this situation was found to be ideal to study 
the geology around the canyon heads. A detailed geological mapping 
programme was carried out in the area around the heads of the Trinco- 
malee Canyon and an attempt was made t o  find whether the develop- 
ment of the canyon heads are geologically controlled. 

Geological mapping was undertaken using air photographs 
including mosaics from the Survey Department of Sri Lanka. Air 
photos (scale 1:20,000 - 1984 air surveys) mosaics (scale '2 inches = 
1 mile' - 1956) were available for the entire area. All geological data 
were transferred to the mosaics for the preparation of the final geolo- 
gical map of the area. 



214 N. P. Wijayananda 

This work was carried out as a part of the Trincomalee Canyon study 
programme conducted by the National Aquatic Resources Agency. 

2. Physiography 

The Trincomalee Canyon has a length of 4.0 + km with an average slope of 
about 1/18 or 3' . The volume of the canyon was computed as the material 
missing from the continental margin and is approximately 1000 km3. The 
general trend of the canyon axis is north east - south west. 

Three principal heads were identified, two at the Koddiyar Bay and 
one at the inner harbour (Figure 2). The narrow outer shelf trough formed 
by the headward bifurcation of the main canyon axis forms the head at the 
Trincomalee inner harbour. The other bifurcations form two heads at the 
Koddiyar Bay. 

The axis of the main head at the Koddiyar Bay trends north-east for 
about 6 km with a slope of 117 or 8' and at a depth of 600 m. i t  bends 90' 
to north-west for a distance of about 3 km with a gentle slope of 1/30 and 
again turns 90' back to north-east at a depth of 700 m (Figure 2). The axis 
again runs north-east for about six km at a slope of about 4' or 1/15 and 
then turns north-north-east at a depth of 1500 m. As it goes further on the 
continental slope the canyon turns gradually to north-east, and thereafter 
broadens and debounches on the continental rise at a depth of about 3400m. 
The two other heads of the canyon project landwards and trend in a north 
west-south east direction and are only 50 m deep. 

3. General Geology 

More than 90% of the island of Sri Lanka is underlain by Precambrian meta- 
sedimentary rocks which are grouped into two major lithological zones - the 
Highland Series and the Vijayan Series (Figure 1). Within the Highland Series 
a subdivision of the south-west group has been identified.3 The Vijayan 
Series is geographically divided into the Eastern and Western Vijayan. 

The Highland Series is composed, predominantly of granulite facies 
rocks. the main rock types being charnockites and their variants, quartzites, 
marbies and varieties of metasedimentary gneisses. The Vijayan Series 
consists of hornblende biotite gneisses, migmatites, granites and granitic 
gneisses of the arnphibolite facies. The south-west group is characterized by 
calc-gneisses, calc-granulites, wollastonite-bearing calciphyres and cordierite- 
bearing gneisses with sillimanite. 



Geological setting arouiad the Heads o f  the Trincomalee Canyon 215 

. . 

Figure 1. Outline geological map of Sri Lanka showing the study areas (shaded and 
cross-hatched) 

H.S. - Highland Series 
W.V.S. -. Western Vijayan Series 
E.V.S. - Eastern Vijayan Series 
S.W.G. - South West Group 



N. P. Wijayananda 

Figure 2. Bathymetric chart (in metres) of the  ~ r i n c o m a l e e  Canyon. Shaded area of  
Figure 1 (Stewart e t  al. 1964b). 



G c o l o ~ i c a l  sctting around tlze Heads o f  t h e  Trinconaalee Canyon 21 7 

Figure 3 .  Transverse profiles of the ~r incorna lee  Canyon. Profiles oriented t o  face 
down Canyon. For location see Figure 2. Vertical exageration x 5.8. Depth in 
metres. 



N. P. Wijayananda 



Geological setting around the Heads of the ~rincornalee Canyon 

The area studied falls under the Highland Series group of rocks 
(Figure 1) and is covered by the one inch t o  one mile Trincomalee topopa- 
phic sheet. Quartzite is the most prominent rock in the area and is also the 
most resistive rock type to  weathering. All the ridges in the inner harbour are 
composed of quartzites and most of the bays have formed in between these 
bands. Charnockite is the interbanded rock with the quartzite. Though 
charnockite is a more resistive rock in the interior of the island, at the 
harbour area, chamockite has eroded faster than the quartzite. Most of the 
bays as Nicholson's Cove, Malay Cove, Minden Cove, Deadman's Cove are 
formed due to the quicker erosion of the charnockites. The southeast of 
Koddiyar Bay is mainly chamockite. Three prominent bands of impure 
marbles were found in the area. One band lies in the valley bottom of the 
Petroleum Corporation Upper Tank Farm area and runs below the China Bay 
railway station into the Inner harbour at Harden Point, This marble band is 
in alignment with the sharp demarcated Yard Cove, but no exposures were 
seen beyond Harden Point. Though no outcrops were found in the south 
west extension of this marble band,morphologically it is evident that the 
band runs into the Thambalagam Bay, between the 177 and 177% mile posts 
of the railway line. Remnants of another similar band is found at Marble 
Beach in the south-east valley of the Diamond Hill ridge. The other 
prominent marble band was south east end of the study area near the 
Ullackalie lagoon (Figure 5). 

Thin elongated patches of marble are also found at several places. 
They are located as follows: (a) near the sea, down the south-east slope of 
the ridge at the Ceylon Fishery Harbour Corporation (Cod Bay) new circuit 
bungalow, (b) near the junction of the turn to  the China Bay from the 
Trincomalee - Dambulla road, and (c) a few metres thick patch at the south- 
west bay of the Periyakulam ridge. 

A pink feldspar granulitic gneiss is present north of the inner harbour. 
This is a very prominent rock in the north of the study area, but is not found 
around the harbour. This granulitic gneiss has charnockitic and basic layers 
interbanded and is migrnatitic at certain places.. These features are well 
exposed at the quarries between the 108 and 109 mile posts of the 
Anuradhapura - Trincomalee road. Four prominent garnet-biotite-gneiss 
bands were present, two in the north west and two in the south east of the 
study area. The shape of the land north of Sampur (Figure 5) and the garnet- 
biotite-gneiss and chamockite lithology clearly shows that the differential 
weathering and erosion has contributed to the form of it. The garnet-biotite- 
gneiss band near Ullakulam (Figure 5) is not  traceable due to  the lack of 
fresh outcrops and at some leached outcrops i t  is difficult to  distinguish 
garnet-biotite-gneiss and chamockite. A coarse grained scapolite-diopside 
rock is found at the old quarry near the Ceylon Fishery Harbour Corpora- 
tion, Cod Bay circuit bungalow. Several fine grained porphyritic basalt dykes 
were ohserved near this coarse grained rock and they are closer to  the 



N. P. Wijayananda 

Figure 5. Geology of the area around t h e  Trincomalee Canyon heads. 



Geological setting around the Heads of the Trir,comalee Canyon 221 

Sri Lanka Port Authority jetty. Similar dykes of few metres thick have also 
been observed in the north coast of the Great Sober Island. A traceable 
anorthosite band is present at the south end of the study area near Ullackalie 
Lagoon (Figure 5 ) .  The area covering from Mutur to Tambalagam Bay is the 
Mahaweli flood plain and is the land next to the two canyon heads at 
Koddiyar Bay.'This area is covered with recent alluvial deposits (Figure 5 ) .  

4. Structure 

The aerial photographs of the area covering the coastal belt from Seruwila up 
to Nilaweli on the scale of 1:20,000 and 1:40,000 were'studied for the 
preliminary structural investigations. The mega-scale structures observed in 
the air photo interpretation were confirmed in the field mapping, and a few 
more medium to small scale structures were identified. The area is charac- 
terized by south-westerly plunging antiforms, a synform and steeply dipping 
basin ( "arena ") . 

The two ridges at the Navy premises on either side of the Nicholson's 
Cove are limbs of the southernmost antiform with the axis running right 
across the Dutch Point. This is an assymetrical antiform. The axis of the 
adjoining synform falls across the Great Sober Island and the Trincomalee 
town. The nose of it is closer to the Fort Fredrick. The axis of the other 
antiform is through China Bay. A steeply dipping basin ("arena") is found 
north west of the area. The pink feldspar granulitic gneiss, the core rock of 
this "arena" dips almost vertically. The above structural features do not 
show much influence on the formation of the canyon. Two major faults are 
located across the two small bays at the Cod Bay. One runs across Palaiyuttu 
and, displaces the quartzite ridge north of it. The other fault is through 
Tekiluttu and displaces the same ridge at another location. These faults have 
directly influenced the opening up of Cod Bay (Figure 6). 

The south east part of the area is of uniform dip at an average 50' 
north west. Minor flexures were seen in abundance at most of the large 
outcrops (Figure 5 ) .  

5. Discussion 

With the limited data available it is rather difficult to draw definite conclu- 
sions on the genesis of the Trincomalee Canyon. It  is, however, evident that 
several factors have contributed to its formation. If the 100 m contour line is 
considered as the sea level during the ice age (17,000 years ago), the 
landward end of the Trincomalee Canyon would have been very simple at 
that time, with only one principal head. 



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Geological setting around the Heads of the Trincomc!':e Canyon 223 

Several small canyons are also found in the continental shelf of 
Sri Lanka. Some of these are located off the main river valleys but only at 
Trincomalee do the canyon heads come within 600 ft of the shore.6 Uppu 
Aru which is in the flood plane of the Mahaweli River has its mouth where 
the head of the canyon begins (Figure 2). I t  is reasonable to assume that 
during the ice age the Mahaweli waters moved into the canyon through Uppu 
Aru and it is interesting to note that even at present these two rivers are 
~ o n n e c t e d . ~  

vithanage8 has reported that the geological mapping of the eastern 
section of the Polonnaruwa sheet (near Gallella) shows that the Mahaweli 
lineament follows a N-S shear zone along a calc-gneiss band and probably 
continues N-E to Trincomalee where a series of deep submarine canyons 
have been located. vithanage9 observed that the River Mahaweli and the 
Trincomalee Canyon are in the Mahaweli Shear zone. The Mahaweli shear 
zone could therefore be a contributing factor to the formation of the 
Trincomalee canyon. Except for the principal axial head of the canyon, all 
the other heads lie above the 100 m contour line. The formation of the inner 
harbour head and the second head at the Koddiyar B-ay have undoubtedly 
developed after the ice age. 

Bush and ~ u s h ~  suggest the sharp bend of the canyon in Koddiyar 
Bay could be due to a fault zone. Such a fault zone could also have given rise 
to the inner harbour head and the second head in Koddiyar Bay. During the 
ice age the inner harbour area may have had the normal ridge valley topo- 
graphy as we find in the present day land. With the rise in the sea level the 
inner harbour area has got submerged gradually and the present bays have 
opened up rapidly due to wave and current actions. All the ridges around the 
inner harbour are made up of quartzites and the valleys are charnockites, 
marble and gneisses. The present day bays have formed in valleys of the ice 
age and are due mainly to differential erosion. The probable fault suggested 
by Bush and ~ u s h ~  falls across the Cod Bay. Two other faults have also been 
identified which cut across Cod Bay and northwest openings of the Cod Bay 
are due to these faults. 

The inner harbour opens up in two directions and the carving parallel 
to the general trend of the area is due to differential erosion and that oblique 
to the trend line is along fracture planes. These forms have developed due to 
the structure and lithology of the area around the inner harbour. 

It  has been observed that another canyon head is developing at the 
mouth of the Mahaweli River (Figure 2). Taking into consideration that the 
Mahaweli was connected to Uppu ~ r n ~  during the Ice Age and recently 
changed its position, it is evident that the river has played a major role in the 
formation of the small canyon head at its present mouth. This shows that , 

the Mahaweli River also has influenced the form and the development of the 
canyon. 



224 N. P. Wijayananda 

6. Conclusions 

The recent geological mapping done in the land around the Trincomalee 
Canyon shows that the form of the inner harbour head is structurally and 
lithologically controlled. The River Mahaweli has played a major role in the 
formation of the principal axial head of the canyon. Another axial head is 
developing at the mouth of the present Mahaweli River. As suggested by 
Bush and ~ u s h ~  it is possible that the sharp bend in the canyon valley, inner 
harbour head and the second head at the Koddiyar Bay is due to  a probable 
fault zone. 

Acknowledgements 

Dr. W. S. Wickramaratne helped by mapping a part of the study area. Messrs. 
S. R. Amaratunge and Danton Silva assisted in the field. The Director, 
Geological Survey Department of Sri Lanka made their unpublished Trinco- 
malee and Nilaveli reconnaisance geological maps available for this study. 
Grateful thanks are due to Dr. M. M. J. W. Herath for his valuable sugges- 
tions. This paper is published with the kind permission of the Chairman of 
the National Aquatic Resources Agency, Colombo. 

References 

1. ADAMS, F. D. (1929 a). The geology of Ceylon, Can. J. Res. 5,425-465. 

2. BUSH, S. A. & BUSH, P. A. (1969),Trincomalee and associated canyons, Ceylon 
Deep-sea Research, 16 : ,655-660, 

3. , COORAY, P. G. (1978).Geology of Sri Lanka Precambrian. In: P. Nalaya (Editor),. 
.Proc. 3rd Reg. Conf: on Geol, and Miner Resources of S.E. Asia. Asian Inst. of . 

Technology, Bangkok, Thailand, 701-710. 

4. FERNANDO, A. D. N. (1982-83). Geomorphology and the hydraulic civilization 
of Sri Lanta. In: I. T.C. Journal 1982-83, special issue honouring Herman Th 
Verstappen. P.T.C., publications, Enschede, The Netherlands, 356-361. 

5.  SHEPARD, F. P. .i1963). Submarine canyons, In: The Sea .M.N.  Hill, ed. Wiley, 
New York, 480-506. 

6. SHEPARD, F. P. & DILL, R. F. (1966).Submarine canyons and other sea valleys,: 
Rand Mc Nally & Co., Chicago, 203-206. 



Geological setting around the Heads of  the Trincomalee Canyon 225 

7. STEWART, H. B. Jr., SHEPARD, F. P. & DIETL, R. S. (1964).Submarine canyons 
off eastern Ceylon. Abs. Ann. meeting, Geol. soc. Am., 197. 

8. VITANAGE, P. W. (1972). Post Precambrian uplifts and regional neotectonic 
movements in Ceylon, 24th I.G.C., Sec.3. 

9. VITANAGE, P. W. (1985). The Geology, structure and tectonics of Sri Lanka and 
South India. Recent Advances in the Geology of Sri Lanka. CIFEG occasional 
publication No. 6 (1985). Paris, France, 5 - 15. 


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