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Water SA

versão On-line ISSN 1816-7950
versão impressa ISSN 0378-4738

Water SA vol.43 no.1 Pretoria Jan. 2017

http://dx.doi.org/10.4314/wsa.v43i1.03 

Metal concentrations in intertidal water and surface sediment along the west coast of the Cape Peninsula, Cape Town, South Africa

 

 

C SparksI, *; J OdendaalII; R SnymanI

IDepartment of Conservation and Marine Sciences, Cape Peninsula University of Technology, PO Box 652, Cape Town, 8000, South Africa
IIDepartment of Environmental and Occupational Studies, Cape Peninsula University of Technology, PO Box 652, Cape Town, South Africa

 

 


ABSTRACT

The concentrations of metals in intertidal water and surface sediment were measured at Scarborough, Hout Bay, Green Point, Milnerton and Bloubergstrand in Cape Town, South Africa, between Autumn 2010 and Autumn 2011. In terms of Pollution Load Index (PLI) of metals in the sediment, the sites were ranked in the following order: Bloubergstrand > Hout Bay > Green Point > Milnerton > Scarborough. Seasonally, metal loads were highest in Autumn 2011 and lowest in Autumn 2010. The higher metal concentrations reported in sediment suggested that both localised anthropogenic and natural weathering were the sources of metals recorded. Surprisingly, metal concentrations were similar to those reported in 1985 for the same sites, suggesting that the intertidal environment in Cape Town has not been increasingly contaminated with metals. The findings provide a baseline of metal concentrations that can be used for further research in the region.

Keywords: metals, intertidal water, sediment, contamination factor, pollution load index, Cape Town


 

 

INTRODUCTION

The effects of contaminants on organisms are often not evident until changes in the ecosystem have taken place. One way of determining whether compounds are likely to be having deleterious effects is to measure concentrations in the environment, which can serve as an early warning of potential contaminant threats. This can be accomplished by having a monitoring system that measures the level and types of chemical compounds prevalent in a system. Metals are elements that occur naturally in the environment and are considered ideal targets for monitoring pollution in sentinel organisms (Clark et al., 1992). Sources of metal contamination are anthropogenic, due to agricultural activity, industrial efforts and an increase in urbanisation. Metals such as Cd, Cu, Ni, Pb and Zn tend to accumulate in aquatic environments due to their chemical characteristics (Clark et al., 1992; Ankley et al., 1996), in particular in surface sediment (Sarki et al., 1995).

Surface sediment can be considered to be a heterogeneous combination of particles of dissimilar compounds (such as detritus, inorganic particles, organic matter, plankton bacteria, etc.). These compounds in turn comprise inorganic and organic components (Martin et al., 1987). According to El-Sammak and Aboul-Kassim (1999), analysing surface sediments can indicate the prevailing quality of a system and the pollution history of a particular area. The indication of quality obtained, however, is not a permanent one, as metals are not necessarily fixed by the surface sediment but may be recycled via both biological and chemical mechanisms. According to Salomons and Forstner (1984), fixation and recycling can happen within the surface sediments as well as between surface sediment and the water column.

Certain metals in surface sediments are vital for the ecological functioning of aquatic biota (e.g. Mn and Cu) (Unlu et al., 2008). The majority of metals (such as Cu, Sn, Al and Cd) enter the marine environment via natural pathways such as erosion (Clark et al., 1992). Deleterious amounts of anthropogenic metals in the surface sediment can bioaccumulate within the organisms, which in turn can negatively impact functioning of the ecosystem. Generally, concentrations of metals in the surface sediment are used as indicators of the health of that ecosystem (Ünlü et al., 2008). Prevalence of metals in surface sediments is considered a better indicator than water given the continual flux of the aqueous part of the ecosystem (Sarki et al., 1995).

Marine pollution has detrimental effects on marine ecosystems and is increasingly becoming of great concern to most countries. Metals accumulate over time and can pose threats to the condition of the water column and health of benthic marine organisms. It is therefore important to monitor both the surface sediment and aqueous environment, as these form sinks for pollutants. Because of their chemical characteristics, elevated concentrations of metals in the water column can accumulate in the surface sediment which in turn can result in toxic environments for organisms inhabiting benthic areas (Salomons and Forstner, 1984).

There is limited published data about metal concentrations in coastal water and surface sediment in Cape Town. A review of metal concentrations in southern African coastal waters by Hennig (1985) indicated that the region's coastal waters and sediment, when compared to other regions at the time, did not have higher concentrations of metals (in both water and sediment), and it was suggested that the southern African coastline was not polluted. The objective of this study was to investigate the concentrations of metals in the intertidal water and surface sediments along the west coast of the Cape Peninsula, Cape Town, to determine metal concentrations in intertidal waters and surface sediments.

 

MATERIALS AND METHODS

Study area

Sampling took place at 5 sites on the west coast of the Cape Peninsula, South Africa: Scarborough (34°11'S, 18°17'E), Hout Bay (34°02'S, 18°21'E), Green Point (33°54'S, 18°23'E), Milnerton (33°53'S, 18°28'E) and Bloubergstrand (33°48'S, 18°27'E) (Fig. 1). The shoreline along the Cape Peninsula is dominated by rocky shores interspersed with pocket beaches of sand or mixed sand and rock. The geomorphology is comprised mainly the Malmesbury rock group with granite underlying most of the western part of the Peninsula (Glass, 1981).

 

 

The area falls within a Mediterranean-type climatic region, typified by winter rainfall from successional cold fronts from the west and dry south-easterly winds during the summer. The annual mean temperature in the region is 17°C (range ± 10°C) (Shannon, 1985). Because it is in a winter rainfall region, the area receives the bulk of its annual precipitation (500-700 mm) from April to August (Shannon, 1985).

Scarborough was the southern-most sampling site, situated in a coastal conservation village. The town is approximately 10 km north of the Cape Point Nature Reserve. Hout Bay is a U-shaped bay approximately 2.5 km long and 2 km wide (Fricke et al., 1979). A commercial fishing harbour, boat maintenance and fish processing facilities are situated on the western side of the bay. The Green Point site is situated at the northern most end of the Sea Point promenade and is a popular recreational area in Cape Town. The Milnerton site is situated close to an outfall pipe and within a couple of kilometres of the port of Cape Town. Bloubergstrand is an urbanised area with a rocky shoreline situated approximately 20 km north of Cape Town.

Fieldwork

Temperature and pH were measured in the shallow surf zone at each sampling site using a Hanna Hi 9810 portable pH/EC/ TDS meter. Samples were collected seasonally during Autumn 2010, Winter 2010, Spring 2010, Summer 2010 and Autumn 2011 at spring low tide, with sampling always commencing at the southern-most site (Scarborough). Water and surface sediment samples (n = 7 at each site) were collected for metal analysis and were frozen at -20°C until analysis.

Metal analysis

Metal analysis was done according to the method of Odendaal and Reinecke (1999). Frozen sediment samples were defrosted and oven-dried for 48 h at 60°C. Ground sediment aliquots (± 0.2 g) and defrosted water samples (5 mL) were digested using 10 mL of nitric acid (HNO3). Samples were then heated to 40°C in a Grant UBD heating block for 1 h, and thereafter to 120°C for 3 h. The digestates were allowed to cool, filtered through Whatman No. 6 filter paper, and then through 0.45 µm membrane micro-filter (Millipore) using a syringe. Thereafter, 5 mL digestates were placed in plastic centrifuge tubes; 10 mL distilled water was added and the tubes stored in a refrigerator until further analysis.

A blank accompanied all samples during analysis. The concentrations of Mn, Fe, Cu, Zn, Cd and Pb were analysed in 7 replicates at the Central Analytical Facilities laboratory at the University of Stellenbosch. General principles of US EPA method 6020A were used in setting up quality control protocols during an lysis and reporting of data. An Agilent 7700x ICP-MS with Octopole Reaction System was used for metal analysis. All metal concentrations were within 2% relative standard deviation (RSD) of the certified concentrations. Concentrations of metals are presented as ng·g-1 dry weight for sediments and as mg·L-1 for water.

Statistical analysis

All calculations and data analysis were done using STATISTICA software (V10; Statsoft, Inc). Results are presented as means and standard deviations (± SD). One-way ANOVA was used to determine significant seasonal and spatial differences in mean metal concentrations in sediment and water samples. The data were tested for normality and homogeneity of variance using Kolmogorov-Smirnoff and Levene's tests, respectively, prior to post-hoc comparisons. Data that did not meet the requirements were log10 transformed. Post-hoc comparisons were made using the Tukey Honest Significant Difference (HSD) test to identify statistically significant data (p < 0.05). Spearman Rank correlations were used to determine relationships between metal concentrations in water and sediment at both spatial and temporal levels.

To quantify the magnitude of contamination by metals in sediment, the Contamination Factor (CF) was determined. The CF indicates the factor by which background concentrations are exceeded at a site and is calculated as follows (El-Sammak and Aboul-Kassim, 1999):

The Pollution Load Index (PLI) was used to determine the contamination loads of metals at the sites using the equation of El-Sammakand Aboul-Kassim(1999):

Accordingto El-Sammak and Aboul-Kassim (1999), a PLI > 1.2 suggests that metal contamination loads are high and PLI < 1.2 that they are not high.

 

RESULTS

Intertidal water temperatures ranged between 14.4 and 18.6°C. The mean temperature for the study period was 15.7 (± 1.3°C). The lowest mean temperatures were recorded during Winter 2010(15.2°C),followed bySpring2010(15.3°C).Thehigh-est temperatures (16.4°C) were in Autumn 2010 and Autumn 2011.Within seasons, there werenosignificantdifferencesin temperature between sites (p > 0.05). The pH ranged between 7.4and8.1, witha meanof7.7.Formostsites,thepHincreased fromAutumn2010toWinter2010 andthen decreasedduring Summer 2010 (except for Hout Bay). Within seasons, there were no significant differences in pH between the sites (p > 0.05).

Metals in intertidal water

The mean Fe concentration in intertidal water was 3.28 mg·L-1 (Table 1). Fe concentrations were lowest (< 0.3 mg·L-1) at Scarborough, Hout Bay and Green Point, with the highest concentrations recorded during Winter 2010 at Milnerton (4.17 mg·L-1) and Bloubergstrand (69.53 mg·L-1). Mean concentrations for other metals were generally very low or below detection limits (see Table 1).

Metals in sediment

The mean Fe concentration in sediment was 835.68 ± 1 249.36 μg·g-1 (Table 2), with the highest concentrations recorded at Green Point during Summer 2010. Seasonally, mean Fe concentrations were lowest during Autumn 2010 at Scarborough and highest in Summer 2010 at Green Point. Significant differences in sediment Fe concentrations were recorded between Scarborough and Milnerton (p < 0.05) as well as between Autumn 2010, Spring 2010 and Summer 2010. Mean sediment Mn concentration was 9.25 (± 9.19) Hg·g-1, with the highest concentrations recorded at Green Point during Summer 2010. There were no significant differences in sediment Mn concentration between sites, but there were significant differences seasonally. Mean Cu concentration in sediment for all sites was 2.57 (± 2.89) µg·g-1, with the highest concentrations at Hout Bay in Spring 2010 and no significant differences between seasons. Highest Zn concentration was recorded at Bloubergstrand during Winter 2010, with a mean concentration of 14.30 (± 50.55) µg·g-1. Only Bloubergstrand had significantly higher Zn concentrations (p < 0.05). Values for Cd were the lowest of all the metals (0.31 ± 1.19 µg·g-1). The mean Pb concentration in sediment was 1.89 ± (1.88 µg·g-1), with the highest concentrations recorded at Green Point during Summer 2010. There were no significant differences in Pb concentrations between sites but significant differences were observed between seasons.

Correlations between water and sediment concentrations

There were no statistically significant correlations between sediment and water samples when all of the metal data were combined (Table 3). However, there was a strong positive correlation (r > 0.9) between sediment and water Cd concentrations during Autumn 2010. Weak positive correlations were recorded for Zn and Pb during Summer 2010 as well as for Zn and Cd during Autumn2011.Therewasavery weak significant positive correlation (r < 0.6) between water and sediment concentrations for Pb at Scarborough, Fe, Mn and Pb at Hout Bay, Fe and Cd at Green Point, as well as Fe, Cu and Cd at Bloubergstrand (p < 0.05). There were no significant correlations between water and sediment metal concentrations at Milnerton, and Bloubergstrand had significant weak negative correlations between sediment and water Fe concentrations.

Contamination factors and pollution load indices

The CFwascalculated foreach metaland categorised per season and site. The calculations were based on background concentra-tionspreviouslyreported byHennig (1985)or using unpub-lisheddata fromtheDepartmentofEnvironmental Affairs for each site (Table 4). Per season, CF was lowest in Autumn 2011 (1.75) and highest during Winter 2010 (19.78) (Table 5). During Autumn 2010, Scarborough had the lowest CF for all metals combined. The order of mean seasonal CFs from highest to lowest was: Winter 2010 > Summer 2010 > Spring 2010

> Autumn 2010 > Autumn 2011. On a spatial scale, the CFs ordered from highest to lowest were: Bloubergstrand (34.44) > Hout Bay (6.24) > Green Point (2.34) > Milnerton (1.03) > Scarborough (0.854).

 

DISCUSSION

Metals have the ability to induce detrimental effects in marine organisms when present at elevated concentrations (Kennish, 1997), with consequences for ecological functioning. Since the marine environment off Cape Town has ecological and economic value, knowledge about this coastal area is pertinent and could influence environmental management strategies. Metal concentrations in sediment were compared to the sediment quality guidelines for the Benguela Current Large Marine Ecosystem (BCLME) in southern Africa (Taljaard, 2006). The guidelines for the BCLME are as follows: Cd: 0.68 µg·g-1, Cu: 18.7 µg·g-1, Pb: 30.2 µg·g-1 and Zn: 124 µg·g-1. None of the metal concentrations at the sites were above the guidelines suggested by Taljaard (2006), apart from Zn at Bloubergstrand during Winter 2010 (198.71 µg·g-1).

Fe has the potential to occur in high concentrations in the natural environment, stemming from natural sources (Giarratano et al., 2010). According to Rebelo (2011), vegetation in Cape Town is strongly tied to geological composition and has been used to determine vegetation types. Fynbos is rich in Fe (up to 1 136 |g·g-1 in proteoid fynbos communities) (Mustart and Cowling, 1993) and a natural source is considered the major contributor to the Fe concentrations recorded for this study. Similarly, Giarratano et al. (2010) noted that Fe concentrations from their study must have been from natural origins as there would not have been a human activity that could have caused such levels of metal input to the system.

According to Hennig (1985), in 1979 Fe concentrations in coastal waters along the west coast of the Cape Peninsula were 15 mg·L-1 at Green Point and Milnerton during winter, with lower concentrations during spring (< 4.5 mg·L-1). Quick and Roberts (1992) reported Fe concentrations of 22.8 mg·L-1 in surface water at Milnerton and 6.78 mg·L-1 at Green Point. In the present study, the Fe concentration in surface waters was low (mean = 3.28 mg·L-1), with elevated concentrations recorded at Bloubergstrand during Winter 2010. The elevated Fe concentrations at Bloubergstrand could be as a result of currents carrying Fe from Milnerton towards Bloubergstrand (Quick and Roberts, 1992). In the present study, Fe concentrations in sediment were higher than concentrations recorded by Hennig (1985) for Hout Bay, Green Point and Bloubergstrand. At Green Point, Fe was 23% higher than that recorded by Hennig (1985) for the same site.

Mn is an essential micronutrient for plants and animals (Wright and Welbourn, 2002). In aquatic ecosystems, Mn does not occur naturally as a metal but is found in various salts and minerals, frequently in association with Fe compounds (Duffus, 1980; Wright and Welbourn, 2002). Industrial discharges also account for elevated concentrations of Mn in receiving waters (Duffus, 1980; Hutzinger, 1980; Wright and Welbourn, 2002). According to Hennig (1985) the maximum surface water Mn concentration in Table Bay was 1.8 mg·L-1. None of the sites sampled in the present study had Mn concentrations greater than 1 mg·L-1. Sediment Mn concentrations recorded in the present study are similar to those reported by Hennig (1985).

Cu occurs naturally in seawater and its concentrations range between 0.03 and 0.38 mg·L-1 (average of 0.25 mg·L-1), with concentrations as high as 2 mg·L-1 occurring in the marine environment (Riley and Chester, 1983). According to Hennig (1985) the average Cu concentration in South African coastal waters in 1979 was 0.899 mg·L-1, which was higher than the average recorded in the present study (0.01 mg·L-1). According to Riley and Skirrow (1975) seawater can retain a maximum of 50 mg·L-1 of Cu and the concentrations are influenced by riverine sources or shelf surface sediments. The anthropogenic sources of Cu include metal-plating operations, jewellery and ornamental industries, electrical wiring industries, electronic industries, and antifouling paints (WHO, 1982). From the present study, higher sediment Cu concentrations were recorded in Spring 2010 and could be indicative of anthropogenic sources of Cu, in particular at Hout Bay and Green Point. Hout Bay is close to a harbour with shipyard maintenance activity which could have contributed to the higher concentrations of Cu at that site.

According to Riley and Chester (1983), the average concentration of Zn in marine water is 5 mg·L-1. The average Zn concentration in South African surface marine waters in 1985 was 6.59 mg·L-1 (Hennig, 1985). The mean Zn concentration in surface waters recorded during the present study was 0.11 mg·L-1, well below the average reported for South Africa by Hennig (1985). Anthropogenic sources of Zn include waste from brass and Zn metal works, waste from yarn, fibre, paint, dye and battery production, steel galvanisation, production of stainless steel tableware, and paper manufacturing (WHO 1982). Some of these industrial activities are prevalent in the Paarden Island industrial area and are therefore possible sources of elevated Zn concentrations in water at Milnerton. Given that the elevated Zn concentrations were recorded in winter (rainfall season), surface runoff of Zn from industrial activities in the surrounding area could have provided a source of Zn at Bloubergstrand. According to Quick and Roberts (1992), there are two current systems in Table Bay, one in the central bay and the other a bimodal longshore current system. Depending on the wind direction the current circulates in either a clockwise or anti-clockwise direction.

Current measurements by Quick and Roberts (1992) indicated that the anti-clockwise (northerly) current is driven by southerly winds and subsequently the predominant surface current was in a northerly direction (Van Leperen, 1971). The northward movement of current may result in a northward movement of metals released at Milnerton and could be the cause of elevated metal concentrations (in particular Zn) at Bloubergstrand, given the topography and bathymetry (Shannon, 1985) of the area.

Cd occurs in the environment as a result of natural weathering and erosion by rivers; this Cd is then transported to coastal waters where the average concentration in seawater is 0.1 mg·L-1 or less and between 30 and 1 000 µg·g-1 in marine surface sediments (WHO, 1992). The average concentration of Cd in South African surface marine waters in 1979 was 0.108 mg -1 and < 0.1 µg·g-1 dry weight for sediment (Hennig, 1985). According to WHO (1992), anthropogenic sources of Cd include waste from manufacturing protective plating for steel, and stabilisers for PVCs. The relatively high Cd concentrations in sediment at Bloubergstrand could have arisen from surface runoff in the adjacent area as Bloubergstrand has been an area where housing development has increased in recent years.

Pb is not considered an essential element (Hutzinger, 1980) but does occur in the marine environment due to natural sources from weathering of rocks and forest fires (Riley and Chester, 1983), which may also be a source in Cape Town coastal waters. The results of the present study indicate that Pb concentrations in surface waters and sediments were generally lower than that recorded by Hennig (1985).

When comparing metal concentrations in surface waters and sediment along the west coast of the Cape Peninsula to those reported by Hennig (1985), it is apparent that metal concentrations have not increased as would have been expected given the rapid rate of industrial development and urbanisation in the Western Cape. The lack of increased anthropogenic input of metals into the environment is evident in the low contamination factor values recorded for the study period, as shown in Table 6.

The mean PLI's reported here are lower than those reported by El-Sammak and Aboul-Kassim (1999), where an average of 1.28 was recorded for all of the sites they sampled. The mean PLI recorded for the five sites was 0.98, and for the five seasons sampled was 1.00. El-Sammak and Aboul-Kassim (1999) reported that sites that had a PLI > 1.2 were considered to be affected by pollutants. Given that neither site nor season PLI values were higher than 1.2, it is suggested that none of the sites sampled were negatively affected by exposure to metals and can thus not be considered contaminated based on PLI values.

 

CONCLUSION

The results of the present study provide information about the concentrations of metals in surface seawater and sediment along the western coastline of the Cape Peninsula, Cape Town. Metal concentrations at the sites sampled have not increased over the past 30 years when compared to the findings of Hennig (1985). Furthermore, the metal concentrations sampled were lower than those for other industrialised coastal cities (Acton, 2011), suggesting that Cape Town intertidal waters and sediments were not contaminated by metals. The CF and PLI analyses suggested that Scarborough was least influenced by metals whereas Bloubergstrand was most influenced by metals, in particular as a result of Zn levels in the sediment. Seasonally, PLI was lowest during Autumn 2010 and highest during Autumn 2011. Information from the present study can be used as baseline data, together with that reported by Hennig (1985), for future monitoring of metal concentrations in Cape Town, South Africa.

 

ACKNOWLEDGEMENTS

The authors would like to thank the Cape Peninsula University of Technology (University Research Funding) for funding this project. We would also like to express sincere thanks to the Departmental Technician, Michelle Slabber, for technical support during field surveys and laboratory work.

 

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Received 18 June 2015
Accepted in revised form 16 November 2016

 

 

* To whom all correspondence should be addressed. S +27 21 460-3766; e-mail: sparksc@cput.ac.za

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