Effect of Tsunami in the Ilmenite Population: An Examination through X-Ray Diffraction, Scanning Electron Microscopy and Inductively Coupled Plasma Atomic Emission

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Journal of Minerals & Materials Characterization & Engineering, Vol. 9, No.11, pp.1007-1026, 201 0

1007

Effect of Tsunami in the Ilmenite Population: An Examination through X-Ray

Diffraction, Scanning Electron Microscopy and Inductively Coupled Plasma

Atomic Emission

Babu Nallusamy1*, Si ni r ani Babu1, M. Sundararajan2, P. Seralathan1, R. Bhima Rao3 &

P.N. Mohan Das2

1Cochin University of Science and Technology, Kerala, India.

2National Institute for Interdisciplinary Science and Technology (CSIR), Trivandrum, India

3 Institute of Minerals and Materials Technology, Bhubaneswar, Orissa, India

*Corresponding Author: geobns@gmail.com

ABSTRACT

Kerala state in the SW part of Indian subcontinent hosts one of the best beach placer deposits in

the world. The near shore deposit is ~140Mt and is very rich in heavy minerals, often up to 70%,

and ilmenite forms its chief constituent. The seasonal enrichment of this deposit takes place

through monsoonal activity and the recent tsunami (24 December 2004) had significantly

contributed its share. Mineralogical and chemical variation of the surface (pre- and post-

tsunamigenic) as well as subsurface ilmenites (4-5m depth) of this deposit has been investigated.

SEM examination on ilmenites of pre-tsunamigenic period conveys that the micromorphology

represents mostly of mechanical activities rather than chemical and solution activities. Both

post-tsunamigenic and subsurface ilmenites were influenced dominantly by solution and

chemical alteration. The pre-tsunamigenic (surficial) ilmenite grains consist only of rutile as an

altered product with a small FeO – Fe2O3 ratio. However, the presence of considerable altered

products such as rutile and pseudorutile in the post-tsunamigenic and subsurface ilmenite

indicates that the ilmenite alteration is in an advanced state. Regarding trace element

composition, it was found that Al, Mg, Na, Ca, Cd, Co, K, Sr and Pb have higher contents in

both core and post-tsunamigenic ilmenite than the pre-tsunamigenic ilmenite. These elements

play an important role in understanding the behavior of the minerals during beneficiation and

further processing. The relative lesser content of such elements in the onshore pre-tsunamigenic

ilmenite grains reveals that the chemical leaching has not been active compared to the ilmenite

concentrates from the shallow sea that have been brought by the tsunami and also to that have

been deposited earlier and now seen underneath up to a depth of ~5m.

1008 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

1. INTRODUCTION

The tsunami struck the southern Kerala coast at 11.30 a m and the central Kerala coast by 12. 30

pm on 26 December 2004. The tsunami run ups resulted in 172 casualties and an estimated loss

of property worth Rs.1358.6 crores. Eyewitnesses conveyed that three waves have struck the

low lying coastal plains sequentially and resulted in considerable damages. The impacts of

tsunami mineralo -granulometic evaluation of beach placers of Kerala state have already been

studied [1]. The effect of tsunami on sediments as well as floral and faunal assemblages have

been reported elsewhere [2-9]. Occurrences of higher concentrations of economical heavy

minerals (placers) in the coastal zone have created interest for exploration and exploitation of

these marine mineral resources in many parts of the world [10-16]. Study of mono-mineralic

analysis such as ilmenite, sillimanite, zircon, garnet and rutile has been considered more

informative than the analysis of bulk sediments for understanding the geologic-geochemical

characteristics [17]. Of these, the geochemistry of ilmenite holds an important role in the

assessment of its quality since ilmenite has high demand in several industries. Further, ilmenite is

identified as an object for provenance search by varietals method [18-19]. The major ilmenite

reserves in India are at Chavara, Manavalakurichy and Chatrapur. India stands first in terms of

ilmenite reserves which are estimated to be 348Mt out of which 150 Mt were processable. This

paper reports the effect of tsunami in the ilmenite population using XRD, SEM-EDX and ICP-

AES.

2. GEOLOGIC SETTING OF THE STUDY AREA

The modern black sand placer of the Thottappally – Kayamkulam (Fig.1) barrier island, with an

average width of about 250 m between the lagoon to the east and Laccadive sea to the west,

extends for about 20 km and at least 2 – 5 km width towards inland. The foreshore slopes at a

low angle seaward (4-10°) and the direction of longshore current remains in general, northerly in

this segment [20]. Sporadic occurrence of a clay horizon having organic matter with peat is

observed from 2.5 to 4 m depth, where heavy mineral concentration becomes less significant.

The hinterland area consists of crystalline rocks of Archeaen age, sedimentary rocks of Tertiary

period and laterite capping on crystalline and sedimentary rocks belonging to Recent to sub-

Recent. Climate in Kerala experiences a humid tropical with alternate wet and dry seasons. The

temperatures vary from 22 to 35oC and the highest temperatures fall during March to May and

the lowest in December and January. Humidity in Kerala varies from 79-84% in the morning’s

hours to 73-77% in the evenings. As far as annual rainfall concerned, Kerala receives 200-300

cm during the southwest monsoon i.e June – September and the northeast monsoon (October-

December) yields about 50 cm rainfall. The longshore sediment transport largely depends on the

wave approach and also on the near shore topography. In general, along the west coast, the

breaker angles w ere generally 5-10o during pre- and post-monsoon seasons and during monsoon

they changed to 160 – 170o thus indicating a reversal in the direction of the longshore current

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1009

[21]. The breaker height in the Chavara coast ranges from 0.3 – 0.5 m during pre-monsoon

season; during monsoon and post-monsoon, it varies from 1.0-2.0m [20]. Groins at mouth bar of

Kayamkulam bar also play a significant role in concentratio n of black sand deposits in the study

area.

3. MATERIALS AND METHODS

Along the Thottappally - Kayamkulam barrier island representative surficial sediment (pre-

tsunami and post tsunami event) samples were collected from the berm using a scooper up to a

depth 30 cm and four core samples following cable tool method up to 5 m depth in 2004 and

2005 respectively. The samples were initially washed and dried and repr esentative samples were

treated with 1:10 HCl, 30% by volume H2O2 and SnCl2 to remove carbonates, organic matter and

ferruginous coatings respectively. The samples were then sieved at a +GF+ DIN 4188 sieve

shaker for 15 minutes at half Phi interval [22]. Magnetite was separated from the heavy mineral

fractions by a hand magnet. Magnetic (ilmenite) and non-magnetic fractions were separated

using Frantz Isodynamic separator. Forward slope of 15° and a slide tilt of 12° at 0.5 Amp, 0.4

Amp and 0.15 Amp were to separate ilmenite mineral.

X-ray diffraction using Philips (X’pert pro) powder diffractometer, (2°/min from 20° to 60°)

were carried out on ilmenite to understand mineral alteration. The pure ilmenite samples were

mounted on carbon adhesive tape and imaged using Jeol-JSM 5600 LV field emission scanning

electron microscope and analysed with a EDAX light element energy dispersive X-ray

spectrometer using a 20 kV electron accelerating voltage. Images of the various samples were

also collected at 5 kV in order to obtain high-resolution surface characteristics of the mineral

grains. The EDAX composition of selected grains was determined at 10 kV. Powdered ilmenite

was brought into solution by fusion with KHSO4 and dissolution in hot dilute H2SO4. Titanium

was determined by reducing titanium (IV) to titanium (III) using aluminum metal and titrating it

against standard ferric ammonium sulphate [23]. The total iron was estimated by stannous

chloride reduction-K2Cr2O7 titration method. The content of FeO in the ilmenite was analy sed by

treating the powdered ilmenite with HF-H2SO 4 mixture and titrating it with standard K2Cr2O7

[24]. The trace elemental composition studies are carried out using ICP-AES (IRIS INTREPID II

XSP MODEL, Thermo Electron Corporation make).

1010 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

Figure 1 Location and sampling point in the study area

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1011

4. RESULTS AND DISCUSSIO N

Altogether nineteen samples have been analysed for different major, minor and trace elements

contents (Table 1, 2), of which eight samples (3, 10, 13, 22, 28, 34 and 39) were collected before

the tsunami and three samples (3T, 13T and 39T) after the tsunami. Four samples each were

collected from the sub-surface layers, below and above water table respectively (Table 2). Above

water table and below water table samples belong to those samples collected from sub-surface

(Core).

4.1 XRD Analysis

X-ray diffraction pattern of the ilmenite concentrate of Thottappally – Kayamkulam shows the

presence of ilmenite (50%) and rutile (50%) peaks in the pre-tsunami samples (Fig 2a), while in

the core and post-tsunamic it shows ilmenite (20 and 41%), rutile (25 and 16%), pseudorutile and

pseudobrookite (55 and 50%) peaks (Fig. 2b-d). This means that the grains are apparently more

altered in the core and post-tsunamic samples, which could be due to the sporadic burial under

reducing conditions in water-logged soils would provide the ideal environment for such

alteration to occur and mixing of shelf sediments with the onshore sands. The shelf of the Kerala

coast may host older sediments and possibly more altered or the shelf sediments could have been

subjected to intense weathering due to sub aqueous conditions.

4.2 SEM Analysis

Micromorphological studies of ilmenite pre-tsunami (Fig. 3 a-e), post-tsunamic and core (Figs.

4a-f and 5a-j) from the study area by SEM depict the development of a number of different

micro features on the ilmenite grain which support the XRD evidences. From these features one

could understand th e physical and chemical energy gradient, surface and sub-surface dissolutio n

process, and post depositional diagenitic modifications [25-26]. The surface textures of quartz

grains used in order to achieve an understanding of the post-depositional or diagenitic history of

the sediments [27]. Pre-tsunamic ilmenite grains exhibits subrounded shape along with impact

‘V” marks and deep pits are seen resulting from mechanical collision and later from solution

activity. Mechanical feature like V-shaped pits suggest that grains are formed by grain to grain

collision in an aquatic medium [28-29]. Crescentic structures and pits are produced by solution

activity. Due to long residence time this type of features might have developed on the grains.

Sets of grooves oriented at different angles developed over the grains clearly indicate the

solution activity process (Fig. 3a-e). More precipitation corroded features ar e visible in the pos t-

tsunamic and core ilmenite grains (Fig. 4a-f and Fig. 5f, h and j) which were presumably

developed due to the chemical activity and solution activities prevailed over the grain surface

which replaced the ilmenite by pesudorutile and rutile. It is clear that core and post-tsunamic

ilmenite grains have undergone extensive weathering and alteration than surface ilmenite which

1012 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

supports XRD and wet chemical analysis results. Similar features have been observed in non-

opaques along the east coast of India [30]. Undulatory wavy surfaces formed due to solution

effect and removals of blocks were also observed on tsunami and core ilmenite grains (Fig.4 e, f

and 5a-e, g and j). The post-tsunamic sediments might have been transported from the shelf

region of Kerala Coast where sporadic burial under reducing conditions in water-logged soils

would provide the ideal environment for such alteration to occur or partly formed due to the

reworking of deeper onshore sediments that were lying below the water table.

Table 1 Major Elemental Distribution in Beach Ilmenite of Thottappally-Kayamkulam Deposit

S.No. TiO2 FeO Fe2O3 T.IronTi/Ti+Fe Alt.Stage

Surface (pre-

tsunami)

3 60.83 8.96 24.81 24.320.60 PR

4 64.20 8.94 26.75 25.660.58 HI

6 64.66 9.11 26.52 25.630.58 HI

10 61.83 8.88 25.92 25.030.58 HI

13 60.48 8.47 26.16 24.880.59 HI

18 63.58 9.20 26.66 25.800.58 HI

22 61.66 9.05 26.66 25.680.59 HI

24 61.45 9.22 26.56 25.750.57 HI

28 61.10 9.12 24.79 24.430.58 HI

30 63.69 8.74 25.75 24.800.59 HI

34 64.10 8.79 28.27 26.600.57 HI

39 62.13 9.03 25.15 24.610.60 PR

CORE

AWT 1c2 63.07 6.71 25.57 23.100.62 PR

2c2 63.56 7.55 25.46 23.680.62 PR

3c2 62.94 6.72 27.39 24.380.61 PR

4c2 64.40 7.87 25.69 24.090.62 PR

BWT 1c4 63.67 7.85 25.33 23.820.61 PR

2c4 62.06 6.92 27.31 24.480.62 PR

3c5 63.79 6.74 25.92 23.370.62 PR

4c6 66.08 9.28 24.36 24.250.62 PR

Surface (post-

tsunami)

3T 62.86 7.81 25.28 23.470.61 PR

13T 62.45 7.32 25.82 23.750.61 PR

39T 62.01 6.75 27.84 24.720.60 PR

PR - Pseudo Rutile

HI - Hydrated Ilmenite

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1013

Surface (pre-tsunami) Core Surface (post-

tsunami )

Sub-Surface Above

Water Table Sub-Surface Below

Water Table

Elements 3 10 13 18 222834391c22c23c2 4c21c42c43c54c63T13T39T

Al 0.49 0.619 0.5 0.545 0.470.8960.2360.590.8590.5090.446 0.3321.3041.0970.4460.9550.780.50.63

Mg 0.49 0.239 0.46 0.654 0.490.3720.1450.470.6350.2380.221 0.1631.3680.4390.2130.440.490.520.55

Mn 0.37 0.141 0.35 0.402 0.360.3040.0920.350.2830.1170.121 0.1580.1370.3440.2140.3450.350.390.4

Na 0.014 0.15 0.042 0.158 0.0810.5010.1930.2760.2540.1380.484 0.2390.3140.6930.0780.4830.2980.1270.083

ppm

Ca 249.4 384.1 206 1686 513.7299.3845.4104.423621132234.1 259.234991024236.31019207.8591.61084

Cd 0.7 2.7 1 3.2 1.20.100.7403.1 0026.56.115.10.90.90.9

Co 60.4 298 61.9 672.2 62.1618.311662.2602.8197274.3 260.4185.7671.2431.5697.263.170.569.2

Cr 812.8 264.7 851.2 601.3 750.1729.2118.7833.9631.1173.3246.7 293.7243.8668.9538.9888.31067863.1922.9

Cu 309 0 309.3 0 274.700307.5000 0000 296.8332.8323.6

K 0 218 19.7 594.2 24.786.1245.44.9144.7139.976.2 142.6556.6303.879.6192.71331.522

Li 2.8 0 3.6 0 2.1002.2000 0000.303.52.92.8

Ni 18.8 0 21.2 0 17.411.7017.8000 00039.116.418.218.4

Sr 23.1 0 23.2 0 26.60020.2022.319 25.160.9049.887.124.327.639.7

Zn 192.2 40.2 189.1 0 190.3115.30176.3132.300 00166.50192.6187.7282202.1

P 518.7 147.8 457.9 99 34127.117.6421.1451.5121.999.7 121.7304247.2147.6211.5529.3340.5407.5

Pb 0 1072 0 2240 074218.40137 123.2 282.5 181.5 206.871493205010000

1014 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

20 25 30 35 40 45 50 55 60

Counts

ο 2 Theta

Fig. 2a X- Ray diffractrograms of representative ilmenite shows the presence of

ilmenite and r u til e in the pre-tsuna mi surf ace ilmenite.

20 25 30 3540 45 50 5560

Counts

ο 2 Theta

IL R

RPR

Fig. 2b X-Ray diffractrograms of representative ilmenite Above Water Table

(Core) shows the presence of pesudorutile, ilmenite and rutile

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1015

20 25 30 35 40 455055 60

Counts

ο 2 Theta

IL R

Fig. 2c X-Ray diffractrograms of representative ilmenite Below Water Table

(Core) shows the presence of pesudorutile , ilmenite and rutile

20 25 30 35 40 45 50 55 60

Counts

ο 2 Theta

Fig. 2 d X- Ray diffractrograms of representative ilmenite shows the presence of

ilmenite, rutile, pesudorutile, pesudobrookite in the post-tsunami samples.

(Legend: IL = Ilmenite, R= Rutile, PR= Pseudorutile and PB= Pseudobrookite)

1016 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

Fig. 3 a-e Scanning electron microscopic view of ilmenite grains separated from

pre-tsunami samples.

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1017

Fig. 4 a-f Scanning electron microscopic view of ilmenite grains separated from post-

tsunami samples. Note the intensity changes in the post-tsunami samples.

4.3 Chemical Analyses

4.3.1Wet chemical analysis

Major elemental compositions of the ilmenite samples of pre-tsunami, post-tsunamic and drill

core sediments analysed by wet chemical method [24] are summarized in Table I. Alteration

stages of ilmenite under weathering also studied [31]. Abundance of TiO2 in the pre-tsunami

ilmenite sediments are relatively high, range from 60.48 to 64.1 % (av. 62.48 %) and in core

ilmenites concentrations average 63.70%, ranging from 62.94 to 66.08 %. On average the

tsunami ilmenite contains 62.44% TiO2, ranging from 62.01-62.86 %. FeO and Fe2O3

concentrations in the pre-tsunami ilmenites range from 8.47 to 9.22 and 24.79 to 28.27 % with

averages of 8.96 and 26.16 %, respectively. The range of FeO and Fe2O3 in the core ilmenite

show 6.71 to 9.28 and 24.36 to 27.39 % with averages of 7.46 and 25.88 %, respectively. The

1018 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

contents of FeO and Fe2O3 in post-tsunamic ilmenite range from 6.75 to 7.81 and 25.28 to

27.84% (av. 7.29 and 26.31%). It was observed that the enrichment of TiO2 in the core and post-

tsunamic ilmenite might have undergone deep weathering and alteration more than the pre-

tsunami ilmenites. Core ilmenites and post-tsunamic ilmenite show pseudorutile alteration phase

(Table 1), whereas most of pre-tsunami ilmenites show only hydrated ilmenite phase. A higher

amount of TiO2 present in ilmenites of pre-tsunami, tsunami and core is ascribable to higher

presence of rutile and pseudo-rutile exsolved phases. The above observations were supported by

XRD and SEM examination (Fig. 2a-d and Fig. 3a-c , 4a-f and 5a-j) Dissolution and / or

oxidation of iron from ilmenite in natural water or in acidic water lead to an enrichment of

titanium and other elements in th e residuu m, which may be the main cause for ilmenite alteration

[32]. The higher amount of TiO2 may be ascribed to repeated cycles of burial and exhu mation of

sediments along beaches and streams and river banks during transport [33]. This would keep

ilmenite under condition s well-suited to th e re moval of iron for considerable lengths of time. The

main reason for such a high alteration below ground water levels (core ilmenites) is due to the

low Eh, high pH and high SO4 content in the ground waters of the study area [34] and

complexing with organic acids under such reducing conditions would further enhance the

solubility of iron [35]. Humic acids as a collection of organic acids resulting from the

decomposition of vegetation [36]. Thus both of these leaching agents would be present in near

surface zones and no doubt contribute to weathering. Organic matter enrichments were found in

the core sediments during procurement of sampling in the study area. Hence, the extent of

alteration of ilmenite depends not only on the geological history of the deposits but also the

intensity of subsurface chemical leaching the deposits underwent in a low energy, sub surface

condition.

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1019

Fig . 5 a- j Scanning electron microscopic view of ilmenite (Core samples)

a b

g h

1020 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

4.3.2 Minor and trace element concentration

Major, minor and trace element concentration were analysed using ICPAES method. These

elements are important in the modern mineralogical panorama, as they provide witness for the

provenance of mineral suite, the alteration patterns and trend of minerals and the quality of raw

mineral ores before industrial processing. Ilmenite trace element variation is dependent on its

paragenesis [37-38]. The surf ace pre-tsunami, core (AWT and BWT) and surface post -tsunamic

ilmenite samples in the present study were analysed (Table 2) for seventeen minor and trace

elements, namely, Fe, Al, Mg, Mn, Na, Ca, Cd, Co, Cr, Cu, K, Li, Ni, Sr, Zn, P and Pb. These

elements were selected based on their relevance in the delineation of weathering history and

parentage.

Figure 6a-f shows behavioral pattern of each element determined in ilmenite collected from

beach sands i.e., surface pre-tsunamic,core (AWT and BWT) and surface post-tsunamic. It was

observed that elements like Al, Mg, Na, Ca, Cd, Co, K, Sr and Pb have higher contents in

ilmenite from core ilmenite. i.e., ilmenite from below water table than the ilmenite from above

water table, pre- and post-tsunamic ilmenite which supports dissolution and / or oxidation of iron

from ilmenite in natural water or in acidic water leading to an enrichment of titanium and other

elements in the residuum. This may be the main cause for ilmenite alteration [32] and the

alteration products could be due to the exogenic processes that operated on these ilmenites after

their release from the parent rocks [39]. The higher contents present in core ilmenite (BWT) is

ascribed to the local concentration of such elements.

The assay data in Table 2 and Fig. 6 show strong positive correlations (r>0.85) were observed

between the concentrations of Fe and Cr, Ni and Zn and between Mn and Mg and Cr and Mn,

and also between Cu and Li, Ni, Sr and Zn and positive concentration of element pairs Li-Ni, Li-

Sr, Li-Zn and Li-P, Ni-Sr, Ni-Zn and Ni-P, and Cd-Pb and Sr-Zn and Sr-P in the surface ilmenite

(pre-tsunami) concentrates. Mg and Al concentrations are generally high at beaches where also

Cr and Fe concentrations are the highest, although there is no significant positive correlation

between Al-Mg where as a strong positive correlation exists between Cr-Fe in the pre-tsunami

ilmenites. Negative or poor relationships for Zn and K suggest a differing control for these

elements.

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1021

Fig. 6a-f Comparisons of minor and trace element distrinbution in beach ilmenite of

Thotappally-Kayamkulam deposit.

3101318222834391c2 2c23c2 4c2 1c42c4 3c5 4c63T13T39T

Stations

Mn & Na

0.2

0.4

0.6

0.8

3101318222834391c22c2 3c2 4c2 1c42c4 3c5 4c63T13T39T

Sta tions

Al & M g

0. 5

1. 5

310 13 1822 28 34391c22c23c24c21c42c43c54c63T13T39T

Stations

1022 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

Fig. 6a-f conti…

Ca, Cr & Pb

1000

2000

3000

4000

5000

6000

7000

8000

3101318222834391c2 2c23c2 4c2 1c4 2c4 3c5 4c63T13T39T

Stations

ppm

3101318222834391c22c2 3c2 4c21c42c4 3c54c63T13T 39T

Stat ions

ppm

P , Zn, Co & K

100

200

300

400

500

600

700

800

3101318222834391c2 2c2 3c24c21c42c4 3c54c63T13T39T

Stations

ppm

Vol.9, No.11 Effect of Tsunami in the Ilmenite Population 1023

Non-significant correlations for Al, Mg, Mn, Na, Cd and Co reflect a different source or

difference in substitution of other cations in the ilmenite structure during crystallization.The

substitution of other cations in the ilmenite s tructure is contr olled by several factors including the

temperature of cry stallization, oxygen fugacity, the amount of suitable cations available, and the

size, charge, and electronegativity of those cations relative to iron and titanium during

crystallization [40]. High element concentrations but with much lower value belong to drill core

ilmenites also evident from the correlation coefficient. Very strong and positive correlations

exist among the concentrations of elements pairs Al-Fe, Mn-Fe, Cd–Fe, Zn-Fe, Mg-Al, K-Al,

Cd-Mn, Co-Mn, Cr-Mn, Zn-Mn, Co-Cd, Pb-Cd, Zn-Cr and Pb-Zn. Negative concentration of

element pairs Al-K, Mn-Na, Mn-Li, Cr-K and Li-Sr and positive concentration of element pairs

Mg-Ca, Na-Li and Cr-Pb were found in tsunami ilmenites. Over all high concentration of TiO2,

Fe, Mg, Al, Cr, Ni, Zn and Mn recorded in beach sediments from the surface, core as well as

post-tsunamic ilmenites are in good agreement with composition of Khondalites and Charnokitic

rocks which are w idely distributed on coastal hinter land [41] (Soman, 1985)

5. CONCLUSION

Titanium enrichment, predominately through removal of iron, is widespread among ilmenite

populations of post-tsunamic and core samples than pre-tsunami ones. The pre-tsunamigenic

(surficial) ilmenite grains consist only of rutile as an altered product with a small FeO-Fe2O3

ratio. However, the presence of considerable altered products such as rutile and pseudorutile in

the post-tsunamigenic and subsurface ilmenite indicates that the ilmenite alteration is in an

advanced state. Chemical alteration of ilmenite predominates over mechanical abrasion as

exemplified by the SEM investigation in the post-tsunamic as well sub-as surface (core)

sediments than pre-tsunami (surface) ilmenites. Regarding trace element data, it was found that

Al, Mg, Na, Ca, Cd, Co, K, Sr and Pb have higher contents in both core and post-tsunamigenic

ilmenite than the pre-tsunamigenic. The relative lesser content of such elements in the onshore

pre-tsunamigenic ilmenite grains reveals that the chemical leaching has been less active

compared to the ilmenite concentrates from the shallow sea that have been brought by the

tsunami and also to that have been deposited earlier and now seen underneath up to a depth of

~5m.

ACKNOWLEDGEMENT

We acknowledge CSIR New Delhi for funding and Director NIIST, Thiruvanthapuram, for

extending Laboratory Facilities. First author’s due thanks to the organizer of ICAM 2008, which

was held at Brisbane, Australia for given opportunity to present this paper in the international

congress on Applied Mineralogy. Special thanks due to Dr. D.S. Suresh Babu, Scientist, Center

for Earth Sciences Studies, Kerala, India for fine tuning the manuscript.

1024 B. Nallusamy, S. Babu, M. Sundararajan, P. Seralathan, R. B. Rao, P.N.M. Das Vol.9, No.11

REFERENCES

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