SQU Journal for Science, 2020, 25(1), 17-25  DOI:10.24200/squjs.vol25iss1pp17-25 

Sultan Qaboos University  

17 

 

Distribution of Nutrient Salts and 
Chlorophyll-a in Surface Water along the Gulf 
of Aden and Arabian Sea Coast, Yemen 

Ibrahim A. Al-Akhaly*, Nabil A. Al-Shwafi and Shehab A. Al-Kabsh 

Faculty of Petroleum and Natural Resources, Sana’a University, Yemen.                               
*Email: ibnalakhaly@hotmail.com 

ABSTRACT:The distribution of inorganic nutrient salts (ammonium, nitrite, nitrate, phosphate and silicate) and 

phytoplankton chlorophyll-a (Chl-a) were investigated in the Gulf of Aden and along the Arabian Sea coast, Yemen. 

Seventy two surface water samples were collected during cruises in August 2014 and January 2015. The sampled area 

extends from As Suqayyah in the west of the Gulf of Aden to Hawf in the east. The study showed that the average 

values of nutrient salts (μg/l) in waters collected in August 2014 and January 2015 were 0.83 and 0.60, 10.98 and 

10.03, 16.41 and 14.73, 10.36 and 8.76, and 29.72 and 22.67 for ammonium, nitrite, nitrate, phosphate and silicate, 

respectively. The average values of Chl-a (mg/m
3
) in August 2014 and January 2015 were 0.26 and 0.21, respectively. 

The results showed that nitrate levels were very high but those of ammonium very low. This may reflect the oxidation 

of ammonia to nitrite and then nitrate, leading to a very favorable ratio of ammonia and nitrate values. The low levels 

of dissolved inorganic nitrogen (DIN)compounds, (ammonium, nitrite, and nitrate), phosphate, silicate and Chl-a 

indicated that the southern coast of Yemen is not in a eutrophic condition. The highest nutrient salt values were in the 

eastern part of the study area, and may have resulted from water originating from the Indian Ocean and upwelling. 

Statistical analysis to seek correlations between nutrient salts and Chl-a show very good to excellent correlation, which 

may be due toconstant coastal environment. 

 

Keywords:Arabian Sea; Gulf of Aden; Nutrient salts; Chlorophyll-a; Yemen. 

، اليمنبحر العربوخليج عدن لساحل في المياه السطحية  أ-والكلوروفيل ةالمغذيلمحا  األ توزيع  

 إبراهيم األكحلي، نبيل الشوافي و شهاب الكبش

وبحر أ للعوالق النباتية في ساحل خليج عدن -وكلورفيل ،النتريت، الفوسفات، السليكات(األمونيا )تم دراسة توزيع األمالح المغذية غير المعضوية  :صلخمال

، وتمتد منطقة جمع العينات من ساحل السقية 7102ويناير  7102عينة من المياه السطحية خالل رحالت بحرية في أغسطس  27في اليمن، تم جمع   العرب

عينات المياه غرب خليج عدن إلى ساحل حوف بمحافظة المهرة في الشرق. وأظهرت هذه الدراسة أن متوسط قيم األمالح المغذية )ميكروجرام/لتر( في 

 ،األمونيالـ  2..77و 70.27، .2..و .01.0، 02.20و 20..0، 01.10و .01.0، 1..1و 0..1كانت  7102ويناير  7102التي جمعها في أغسطس 

أ )ملغ/م-النترات، الفوسفات والسليكات على التوالي، ومتوسط قيم الكلورفيلو النتريت
0

على التوالي.  1.70و  .7كانت  7102ويناير  7102( في أغسطس 

يا إلى النتريت ثم كما أظهرت النتائج أن قيم النترات مرتفعة، لكن قيم األمونيا منخفضة مقارنة بالظروف البيئية الطبيعية. وهذا ربما يعكس أكسدة األمون

روجين غير العضوية الذائبة )األمونيا، النتريت النترات، مما أظهر عالقة جيدة جداً بين قيم األمونيا والنترات. وتشير المستويات المنخفضة لمركبات النيت

، وبالتالي فالمياه السطحية في ساحل خليج إغناء بالمغذياتأ إلى أن الساحل الجنوبي لليمن ليس في ظروف -والنترات( والفوسفات والسليكات والكلورفيل

جزء الشرقي من منطقة الدراسة، وقد يكون هذا ناتج عن المياه التي عدن وبحر العرب في ظروف بيئية طبيعية. وكانت أعلى قيم لألمالح المغذية في ال

أ ارتباطاً جيداً جداً إلى ممتازاً بينهما، وقد يكون بسبب -مصدرها المحيط الهندي وعملية الرفع، وأظهر التحليل اإلحصائي بين األمالح المغذية والكلورفيل

 البيئة الساحلية المستقرة. 

 

 .أ، اليمن-بحر العرب، خليج عدن، األمالح المغذية، كلورفيل: مفتاحيةالكلمات ال

 

 

 



IBRAHIM A. AL-AKHALY  ET AL 

 

18 

 

1. Introduction 

he most overwhelming feature of the Gulf of Aden and Arabian Sea coastal regions affecting every aspect of the 

present day physical, biological and socio-economic environment is the fact that the area is a desert. The Yemen 

coast is characterized by a narrow coastal plain between the Gulf of Aden and the mountain range that parallels the 

shoreline [1]. The Yemen coastal region is influenced by two distinct monsoon seasons. The months of April and May, 

and September and October are transitional months as global pressure patterns re-adjust to the changing incoming solar 

energy [2]. The climate of the Yemen coast and nearby waters is dominated by hot and extremely arid conditions 

characteristic of the Arabian Peninsula [3]. Consequently, the present work was undertaken to study the nutrient salts 

and Chl-a in the Gulf of Aden and Arabian Sea coastal areas by different cities within Yemen. Therefore the results of 

these investigations could be considered to be a pilot for further similar studies in the coastal waters of the Gulf of 

Aden and Arabian Sea.  

The high primary productivity, due in part to upwelled nutrients, supports a feed web which ultimately sustains 

the fish community. The seasonality of the monsoon wind and the upwelling can see seasonal periodicity throughout 

the food web [4]. 

Among the components of waste water most likely to have an impact on the marine ecosystem are nutrients, 

organic matter and microorganisms. Several literature reports have described the occurrence of eutrophication as a 

result of high concentrations of nutrient chemicals in coastal waters [5-7]. Eutrophication is a process driven by 

enrichment of water by nutrients, especially compounds of nitrogen and/or phosphorus, leading to increased growth, 

primary production and biomass of algae, changes in the balance of organisms, and water quality degradation. The 

consequences of eutrophication are undesirable if they appreciably degrade ecosystem health and/or the sustainable 

provision of goods and services [8]. The phenomenon of eutrophication due to nutrient inputs from land-based 

pollution sources is a major environmental problem and the geographical distribution of eutrophication in the different 

seas occurs in densely populated areas characterized by intensive economic activities [9]. There are good reasons to 

believe that eutrophication can, in the near future, become a common hazard in marine coastal areas in many parts of 

the world. Such a process would have damaging effects on both inshore fisheries and recreational facilities. Monitoring 

major nutrient levels, therefore, is important to assess the degree of pollution and/ or the quality state of water 

resources [6,10-12]. Riley et al., [13] reported that, the range of nutrient concentrations in marine water under normal 

environmental conditions are as follows (μg/l): nitrate, 1.0-120; phosphate, 1.0-160; ammonia, 0.0-50 and nitrite, 0.2- 

30. Coastal waters have higher concentrations of nutrient salts and Chl-a than the open sea waters [14,15]. 

The present study aimed to determine inorganic micronutrient salts (DIN, phosphate and silicate) and Chl-a 

variation along the coastal area of the Gulf of Aden and Arabian Sea, Yemen. 

2. Materials and Methods 

Seventy two surface sea water samples were collected using a clean plastic bucket from the surface (0.90 m) at 

12 stations (Figure 1) for nutrient salt and Chl-a  analysis and transferred to cleaned 100 ml polyethylene bottles which 

had been prewashed with 10% hydrochloric acid. At the time of sampling, the sample bottles were rinsed twice with 

the sampled water, and then filled with it. For nutrient salt analysis, samples were filtered through Whatman GF/C 

Millipore filter papers (0.47μm) and frozen (−20 °C). Once in the laboratory, the samples were allowed to thaw for 24 

hours prior to determination of dissolved nutrients [16]. The phytoplankton standing crop as Chl-a was extracted with 

90% acetone. The measurements of dissolved nutrient salts and Chl-a were performed using a Shimadzu double beam 

spectrophotometer UV-150-02, following the methodology of Strickland and Parsons [17]. Double distilled water 

and/or deionized water was used for dilution of samples. Blank determinations were carried out for each group of 

samples on a monthly basis. The concentrations of the nutrient salts and Chl-a were measured three times and the mean 

values were taken. Correlation matrices were estimated to show the relationship between nutrient salt concentrations 

and Chl-a. These analyses were applied to interpret the data and to obtain better information about the surface water of 

the studied stations. 

2.1  Study area 

The Gulf of Aden and Arabian Sea is dominated by the Indian Ocean monsoon system (Figure 2). From January 

to March the northeast monsoon blows in a south western direction. Between May and September, the south west 

monsoon generates winds which blow onshore and replace surface waters by cooler nutrient-rich water from deeper 

layers. This upwelling has limited the growth of coral reefs but triggers high primary production which supports the 

region’s rich pelagic fish stocks [18,19].  

Mean surface water temperature in the Gulf of Aden and Arabian Sea coastal area is about 24.44 
o
C in summer 

(August) and about 26.60 
o
C in winter (January). 

 

T 



DISTRIBUTION OF NUTRIENT SALTS AND CHLOROPHYLL-A 

19 

 

 

Figure 1.  Map of Gulf of Aden and Arabian Sea showing the sampling stations. 

 

 
 

Figure 2. Gulf of Aden and Arabian Sea climatological QuikSCAT wind speed (m/s) for January and August, NE and 

SW monsoon [20,21]. 

3. Results and discussion 

3.1. Nutrient salts 

3.1.1. DIN (ammonium, nitrite and nitrate) 

Ammonium is the major nitrogenous product of the bacterial decomposition of organic matter containing 

nitrogen, and is an important excretory product of invertebrates and vertebrates. As for the utilization of nitrogenous 

materials, NH4 is the preferred inorganic source because of its ease of uptake and incorporation into amino acids (N-

assimilation). The present study shows that August 2014 had the higher values of ammonium, ranging between 0.65 

and 0.95 μg/l with an average of 0.83±0.10 μg/l, whereas January 2015 had lower values of ammonium, ranging 

between 0.33 to 0.85 μg/l with an average of 0.60±0.17 μg/l (Table 1 and Figure 3).  

The level of ammonium during August 2014 and January 2015 was relatively low; this may be attributed to the 

increase in its consumption rate by phytoplankton. However, generally, the concentrations of ammonia during August 

2014 were mostly higher than those of January 2015 (Figure 4). The available ammonium may have been the 

decomposition product of organic material. 

Nitrite concentrations during August 2014 ranged from 9.55 to 13.60 μg/l with an average of 10.98± 1.52 μg/l, 

whereas the concentrations in January 2015 ranged from 8.50 to 12.60 μg/l with an average of 10.03±1.42 μg/l (Table 

1 and Figure 3). The average values for the different locations of nitrite in January 2015 were slightly lower than the 

average values in August 2014 (Figure 4). 

 

 

 

 



IBRAHIM A. AL-AKHALY  ET AL 

 

20 

 

Table 1. Mean concentration of nutrient salts and Chl-a at selected stations in the Gulf of Aden and Arabian Sea coast 

surface water during August 2014 and January 2015.   

 

Station 

No. 

Location 

name 
Month 

Nitrite 

(µg/l) 

Nitrate 

(µg/l) 

Ammonium 

(µg/l) 

phosphate 

(µg/l) 

Silicate 

(µg/l) 

Chl-a 

(mg/m
3
) 

1 As Suqayyah 
Aug. 2014 9.55 14.33 0.65 8.80 20.40 0.10 

Jan. 2015 8.50 12.25 0.33 7.00 18.30 0.09 

2 Khor-Omair 
Aug. 2014 9.60 14.50 0.70 8.85 20.60 0.12 

Jan. 2015 8.60 12.50 0.40 7.30 18.60 0.09 

3 Aden 
Aug. 2014 9.63 14.60 0.72 8.95 20.80 0.09 

Jan. 2015 8.65 12.55 0.45 7.65 19.00 0.11 

4 Shuqrah 
Aug. 2014 9.80 14.65 0.80 9.50 21.00 0.14 

Jan. 2015 8.90 12.70 0.50 8.00 20.30 0.10 

5 Ahwar 
Aug. 2014 9.83 14.80 0.83 10.30 25.30 0.13 

Jan. 2015 9.50 13.00 0.53 8.30 20.30 0.13 

6 Balhaf 
Aug. 2014 10.25 15.30 0.83 10.50 27.80 0.20 

Jan. 2015 9.56 13.50 0.55 8.50 20.55 0.12 

7 Al-Mukalla 
Aug. 2014 10.30 15.65 0.85 10.75 30.00 0.33 

Jan. 2015 9.80 14.30 0.61 9.30 21.00 0.20 

8 Qusayír 
Aug. 2014 11.53 17.00 0.90 11.00 33.40 0.37 

Jan. 2015 10.30 15.50 0.66 9.50 23.50 0.25 

9 Ras Sharwin 
Aug. 2014 11.76 17.30 0.93 11.30 35.60 0.36 

Jan. 2015 10.50 16.53 0.73 9.55 25.80 0.30 

10 Haswayn 
Aug. 2014 12.35 19.00 0.93 11.30 37.40 0.40 

Jan. 2015 11.00 17.40 0.81 9.70 26.20 0.33 

11 Al-Muhyfif 
Aug. 2014 13.50 19.50 0.92 11.50 40.00 0.43 

Jan. 2015 12.50 18.00 0.80 10.00 28.30 0.37 

12 Hawf 
Jan. 2014 13.60 20.30 0.95 11.55 44.30 0.45 

Aug. 2015 12.60 18.50 0.85 10.30 30.20 0.40 

 Minimum 
Aug. 2014 9.55 14.33 0.65 8.80 20.40 0.09 

Jan. 2015 8.50 12.25 0.33 7.00 18.30 0.09 

 Maximum 
Aug. 2014 13.60 20.30 0.95 11.55 44.30 0.45 

Jan. 2015 12.60 18.50 0.85 10.30 30.20 0.40 

 Average 
Aug. 2014 10.98 16.41 0.83 10.36 29.72 0.26 

Jan. 2015 10.03 14.73 0.60 8.76 22.67 0.21 

 STD 
Aug. 2014 1.52 2.16 0.10 1.07 8.39 0.14 

Jan. 2015 1.42 2.35 0.17 1.11 4.03 0.12 

 

 

The present data of nitrite was similar to that recorded off  the Hadramout coast; 10.34-13.50 μg/l [4]. A very 

strong to excellent positive correlation was recorded between nitrite and ammonium (r = 0.84 on August 2014 and       

= 0.94 on January 2015) (Table 2). 

Nitrate is the final oxidation product (nitrification) of other nitrogen compounds in toxic seawater having a high 

redox potential. The nitrate form is generally considered the most stable and predominant DIN in oxygenated sea water 

[22]. Its concentration during August 2014 ranged from 14.33 to 20.30 μg/l with an average of 16.41±2.16 μg/l, 

whereas the concentration during January 2015 ranged from 12.25 to 18.50 μg/l with an average of 14.73±2.35 μg/l 

(Table 1 and Figure 3). The distribution of nitrate showed that the concentration during August 2014 was higher than 

that in January 2015 (Figure 4). In addition, it was observed that the concentration of ammonium was less than that of 

nitrate. This relates to the fact that the rate of nitrification is mostly similar to that of denitrification, or due to the 

oxidation of ammonium to nitrite and nitrate either chemically or biologically.  

 

 

 

 

 

 

 



DISTRIBUTION OF NUTRIENT SALTS AND CHLOROPHYLL-A 

21 

 

Table 2. Correlation coefficients of nutrient salts and Chl-a. 

 

 Nitrite Nitrate Ammonium Phosphate Silicate Chl-a  

Nitrite 1.00 
     

Nitrate 
0.99 

  0.97* 
1.00 

    

Ammonium 
0.84 

  0.94* 

     0.84 

 0.97* 
1.00 

   

Phosphate 
0.86 

  0.92* 

     0.85 

 0.94* 

0.98 

  0.98* 
1.00 

  

Silicate 
0.97 

  0.97* 

     0.97 

 0.99* 

0.91 

  0.96* 

0.94 

  0.92* 
1.00 

 

Chl-a 
0.93 

  0.96* 

     0.93 

 0.99* 

0.90 

  0.96* 

0.93 

  0.94* 

0.97 

  0.98* 
1.00 

r = 0.86 for August 2014                    r = 0.92* for January 2015 

 

 

 

Figure 3. Average concentrations of nutrient salts in the Gulf of Aden and Arabian Sea coast surface water during 

August 2014 and January 2015. 

 

 

The present data for nitrate was similar to that previously recorded on the Hadramout coast; 17.30-20.90 μg/l [4]. 

An excellent positive correlation was recorded between nitrate and nitrite (r = 0.99 in August 2014 and = 0.97 in 

January 2015) and a very strong to excellent positive correlation was recorded between nitrate and ammonium (r = 0.84 

in August 2014 and = 0.97 in January 2015) (Table 2). Lower DIN concentrations were detected in As Suqayyah and 

high concentrations were detected in Hawf. 

The average values of nitrate concentrations of 16.41 and 14.73 μg/l for August 2014 and January 2015, 

respectively, were much higher than the average contents of nitrate, of 10.98 and 10.03 μg/l for the same period, 

respectively, while the concentration of ammonium was fifteen and tenfold less than those recorded for nitrate and 

nitrite, respectively. Based on these results, the abundance of nitrogen species in the study area is principally in the 

order nitrate > nitrite > ammonium. This reflects the preferred uptake of the DIN species by phytoplankton organisms 

in their N-assimilation. 

3.1.2. Reactive phosphate  

Phosphorus plays a major role in biological metabolism; it is an essential nutrient element in photosynthesis and 

other processes in plants. Phosphate concentrations in August 2014 ranged from 8.80 to 11.55 μg/l with an average of 

10.36±1.07 μg/l, whereas concentrations in January 2015 ranged from 7.00 to 10.30 μg/l with an average of 8.76±1.11 

μg/l (Table 1 and Figure 3). The average value of phosphate in August 2014 was higher than the average value in 

January 2015 (Figure 4). Lower phosphate concentrations were detected in As Suqayyah and higher concentrations 

were detected in Hawf (Figure 4).  

A very strong to excellent positive correlation was recorded between phosphate and other nutrient salts (r ≥ 0.85) 

and Chl-a (r ≥ 0.93) (Table 2). 



IBRAHIM A. AL-AKHALY  ET AL 

 

22 

 

The present data for Phosphate was similar to that previously recorded for the Hadramout coast; 10.30-11.20 μg/l 

[4]. 

 

 

Figure 4. Spatial distribution of inorganic nutrient salts and Chl-a at selected stations in the Gulf of Aden and Arabian 

Sea coast surface water during August 2014 and January 2015. 

3.1.3. Reactive silicate  

Silicate is one of the major mineral constituents in sea water. It is a good indicator of fresh water dispersion and 

of the potential for diatoms [23]. Silicate concentration in August 2014 ranged from 20.40 to 44.30 μg/l with an 

average of 29.72±8.39 μg/l, whereas the concentration in January 2015 ranged from 18.30 to 30.20 μg/l with an 

average of 22.67± 4.03 μg/l (Table 1). The average value of silicate in August 2014 was higher than the average value 

in January 2015 (Figure 3). Lower silicate concentrations were detected in As Suqayyah and actually high 

concentrations were detected in Hawf (Figure 4). 

The concentration of silicate in the present study revealed high levels (>18 μg/l). Probably, during August, the 

dissolution of diatom skeletons by increasing temperature, up-welling and sandstorms are responsible for high levels of 

silicate. The average concentrations of silicate were higher than those of the other nutrient salts. This means that 

silicate is not a limiting factor for phytoplankton growth in the stations studied. An excellent positive correlation was 

recorded between silicate and other nutrient salts (r ≥ 0.91) (Table 2). 

The present data for silicate was similar to that previously recorded on the Hadramout coast; 20.30-40.50 μg/l 

[4]. 



DISTRIBUTION OF NUTRIENT SALTS AND CHLOROPHYLL-A 

23 

 

The coastal areas of the Gulf of Aden and Arabian Sea exhibit comparatively high values of nutrient salts, 

indicating the probable effects of upwelling. Upwelling of variable intensity is reported to occur along the se coasts 

depending mainly upon influencing factors like wind stress, and acceleration of the vertical movements due to the 

changing current regime [24]. 

Spatial distribution of surface nutrient concentrations showed high concentrations of ammonium, nitrite, nitrate, 

phosphate and silicate in the east of the study area but lower concentrations to the west during both cruises (Figure 4). 

3.2. Chlorophyll-a (Chl-a) 

Marine phytoplankton play a central role in the planktonic food web and biogeochemical cycling in the global 

ocean. Primary production by phytoplankton is consumed or decomposed to support other trophic levels, including the 

fish we harvest, or is exported to deeper waters [25].  

Chl-a is the main pigment that can be used for the determination of phytoplankton biomass [26], and it is used as 

a trophic state indicator. Chl-a concentration in August 2014 varied between 0.09 and 0.45 mg/m
3 

with an average of 

0.26±0.14 mg/m
3
, whereas the concentration in January 2015 varied between 0.09 and 0.40 mg/m

3 
with an average of 

0.21±0.12 mg/m
3 

(Table 1). The average value of Chl-a in August 2014 was higher than the average value in January 

2015 (Figure 5). 

 

 
 

Figure 5. Minimum, maximum and average concentrations of Chl-a in the Gulf of Aden and Arabian Sea coast surface 

water during August 2014 and January 2015. 

 

Nutrient concentrations decline from east to west in the Gulf of Aden and along the Arabian Sea coast. The 

highest concentrations were recorded in station 12 and lower concentrations were encountered in station 1surface water 

(Figure 4). Generally, during January 2015 levels of Chl-a were lower than those recoded during August 2014 (Figure 

4). The present data for Chl-a was similar to that recorded previously on the Hadramout coast, with 0.23-0.34 mg/m
3 

[4], and semi-similar to that recorded in the Aegean Sea, with 10-0.80 mg/m
3 

[27] and 0.03-0.70  mg/m
3
 [28], but 

lower than that reported by Khomayis [29] in the coastal waters of Jeddah city, Red Sea (0.02-10.16 μg/l) and higher 

than that reported by Ignatiades et al., [30] in the north and eastern Mediterranean Sea (0.01-0.15 μg/l).The study 

values indicate that the production potential of the Gulf of Aden and Arabian Sea coast is low. 

The reason why higher concentrations were noticed at station 12 (Hawf) may be due to the intense upwelling and 

the advection of the upwelled water of the Somali region brought into this area due to the intensification of the Somali 

current, a part of which flows northwards into the area further north along the coast of Oman. The distribution of Chl-a 

also follows exactly the same pattern as that of the nutrient salts, indicating a higher productivity due to the blooming 

of phytoplankton in areas rich in nutrient salts, and showing a direct relationship between the two as illustrated in Table 

2.  The results show a relationship between phytoplankton and nutrients salts; this is confirmed by the excellent 

positive correlation between Chl-a and nutrient salt concentration (r ≥ 0.93) (Table 2). 

In general, the high values of Chl-a in the coastal area investigated are undoubtedly due to the rich supply of 

DIN, phosphate and silicate; these nutrient salts contribute to the growth of phytoplankton, expressed by the high levels 

of Chl-a, which has ledto a eutrophication process in the Gulf of Aden and Arabian Sea coasts. The levels of DIN, 

phosphate, silicate and Chl-a indicate that, the Gulf of Aden and Arabian Sea is in a eutrophic condition. 

The general trend of temporal distribution of nutrient salts and Chl-a showed slightly higher values during 

August 2014 than January 2015. The data in this work clearly demonstrate the oligotrophic nature of the Gulf of Aden 

and Arabian Sea coasts.  

 

 



IBRAHIM A. AL-AKHALY  ET AL 

 

24 

 

Conclusion 

The distributions of nutrient salts and Chl-a during August 2014 and January 2015 cruises in the Gulf of Aden 

and Arabian Sea coasts have been investigated. The content of nitrate through the study period is higher than the 

content of ammonium. This observation may reflect the oxidation of ammonium to nitrite and then to nitrate which 

may justify the very good relation between ammonium and nitrate concentrations.  

Based on the results, the abundance of nitrogen species in the study area is principally in the order: nitrate > 

nitrite > ammonium. This reflects the uptake preferable of the inorganic nitrogen species by phytoplankton organisms 

in their N-assimilation. The concentrations of nutrient salts and Chl-a during August 2014 are higher than observed 

concentrations during January 2015. The spatial distribution of nutrients affects the distribution of phytoplankton, as 

confirmed by the Chl-a data in the Gulf of Aden and Arabian Sea coasts (between 0.09-0.45 mg/m
3
). 

Hence, surface seawater in Gulf of Aden and Arabian Sea coast maintains normal environmental conditions. The 

results of these investigations could be considered as pilot for further similar studies in the coastal waters of Gulf of 

Aden and Arabian Sea.  

Conflict of interest  

The authors declare no conflict of interest.  

Acknowledgements 

We thank the anonymous reviewers for helpful comments and constructive criticisms to improve the manuscript. 

References 

1. Ba-Sumaid, A.A. Effects of Masila oil Terminal on coastal Fauna M.Sc. Thesis, Dep. Biology, Fac. Sci, Sana’a 
University, 1997, 133p. 

2. Naval Oceanography Command Detachment. Climate study of the near coastal zone, Red Sea south and Gulf of 
Aden. U.S. Naval Oceanographic Command Detachment, Asheville, NC, 1982- USA. 

3. Howe, G.H., Reed, L.J., Ball, J.J., Fisher, G.E. and Lasso, W.G. Classification of world desert areas. Report 69-
38ES, Earth Science laboratory, United States Army Natick Laborites, Natick, MA, 1968. 

4. Al-Shwafi, N.A  and Ahmed, A.M. A Systematic Evolution of Selected Nutrient and Chlorophyll - A Along of 
Hadramout Coast, Yemen. Academic Notes, 2009, No. 9. 

5. Cederwall, H. and Elmgren, R. Biomass incase of Benthic macrofauna Demonstrates Eutrophication of the Baltic 
Sea. Ophelia Supplement, 1980, 1, 287-304. 

6. Rosenberg, R. Eutrophication the future Marine Coastal Nuisance. Marine Pollution Bulletin, 1985, 16, 227-231. 
7. Degobbis, D. Increase Eutrophication of the Northern Adriatic. Sea: Secona Act. Marine Pollution Bulletin, 1989, 

20, 452-457. 

8. Ferreira, J.G., Andersen, J.H., Borja, A., Bricker, S.B., Camp, J., Cardoso da Silva, M., Garcés, E., Heiskanen, 
A.S., Humborg, C., Ignatiades, L., Lancelot, C., Menesguen, A., Tett, P., Hoepffner, N., Claussen, U. Marine 

Strategy Framework Directive e Task Group 5 Report Eutrophication. EUR 24338 EN Joint Research Centre. 

Office for Official Publications of the European Communities, Luxembourg, 2010, 49 p. 

9. Malagó, A., Bouraoui,F., Grizzetti, B., and Roo., A.D. Modelling nutrient fluxes into the Mediterranean Sea. 
Journal of Hydrology: Regional Studies, 2019, 22. 

10. Friligos, N. Nutrient Conditions in the Euboilkos Gulf (West Aegean). Marine Pollution Bulletin, 1985, 16, 435-
439. 

11. Zoffmann, C.F. Rodriguez-Valera, M. Perez_fillol, F. Ruia-Bevia, M. Torreblance and F. Colom, Microbial and 
Nutrient Pollution Along the Coasts of Alicante, Spain Marine Pollution Bulletin, 1989, 20, 74-81. 

12. Hassan, E.S. Banat, I.M., El-Shahawi, S. and Abu-Hilal, A.H. Asystematic Evolution of Selected Nutrients, Heavy 
Metals and Microbial pollution Along the east Coast of the United Arab Emirate University Journal of Faculty of 
Science., UAE University, 1995, 17, 203-226. 

13. Riley, J.P. Nutrient Chemicals (including those derived detergents and agricultural chemicals). In: A Guide to 
Marine Pollution. (Goldberg, E.D., ed). Gordon and Beach Science Publishers, New-York, London, Paris, 1978. 

14. Rahav, E., Raveh, O., Hazan, O., Gordon, N., Kress, N., Silverman, J., Herut, B. Impact of nutrient enrichment on 
productivity of coastal water along the SE Mediterranean shore - a bioassay approach. Marine Pollution Bulletin, 

2018, 127, 559-567. 

15. Raveh, O., David, N., Rilov, G., Rahav, E. The temporal dynamics of coastal phytoplankton and bacterioplankton 
in the eastern Mediterranean Sea. PLOS One 10, e0140690, 2015. 

16. McDonald, R.W., McLaughlin, F.A. The effect of storage by freezing of dissolved inorganic phosphate, nitrate 
and reactive silicate for samples from coastal and estuarine waters. Water Respiratory., 1982, 16:95-104. 

17. Strickland, J. and Parsons, T. A practical handbook of sea water analysis. Bulletin of the Fisheries Research Board 
of Canada, 1972, 167, 310p. 



DISTRIBUTION OF NUTRIENT SALTS AND CHLOROPHYLL-A 

25 

 

18. Alsayed, A. and Ghaddaf, M. Upwelling and fish mortality, in the northern Gulf of Aden, Indian Journal of 
Marine Science, 1993, 22, 305-307. 

19. UNDP/GEF. Biodiversity conservation and sustainable development programme, Socotra Archipelago, Republic 
of Yemen. Mac Alister Elliott and partners Ltd. United Kingdom, 1996. 

20. Gittings J.A., Raitsos D.E., Racault M., Brewin R.J., Pradhan Y., Sathyendranath S., and Platt T. Seasonal 
phytoplankton blooms in the Gulf of Aden revealed by remote sensing, Remote Sensing of Environment, 2017, 

189, 56-66. 

21. Alkawri, A. and Gamoyo, M. Remote sensing of phytoplankton distribution in the Red Sea and Gulf of Aden,  
Acta Oceanologica Sinica, 2014, 33(9), 93-99. 

22. Kandil, M.M. Hydrological and chemical studies on the Red Sea waters infront of Hurgada. M.Sc. Thesis, Alex. 
University, 1982. 

23. Fahmy, M.A., Beltagi, A.I. and Abbas, M.M. Nutrient salts and Chlorophyll-a in the Egyptian Mediterranean 
coastal waters. MEDCAST 99- EMECS99 Joint conferences, Land-Ocean. Interactions: Managing costal 

Ecosystems, 9-13 November, Antalya, Turkey, 1999. 

24. Boze, R. and Tomczak, M. Upwelling ecosystems. Springer Verlag, Berlin.,1978, 303 p. 
25. Anglès, S., Jordi, A., Henrichs, D.W. and Campbell, L. Influence of coastal upwelling and river discharge on the 

phytoplankton community composition in the northwestern Gulf of Mexico. Progress in Oceanography, 2019, 

173, 26-36. 

26. Carlson, R.  A trophic state index for lakes. Limnology and Oceanography,1977,22(2), 361-369. 
27. UNESCO, 1990.  Review of potentially harmful substances. Nutrients, Reports and Studies, No.34. 40p. 
28. Kucuksezgin, F., Balci, A., Kontas, A., and Alta Y, O. Distribution of nutrients and chlorophyll-a in the Aegean 

Sea, Oceanologica Acta.,1995, 18, 343-352. 

29. Khomayis, H.S. The Annual Cycle of Nutrient Salts and Chlorophyll-a in the Coastal Waters of Jeddah, Red Sea. 
Journal of King Abdulaziz University: Marine Science., 2002, 13,135-141. 

30. Ignatiades, L., Karydis, M., Vounatsou, P.  A possible method for evaluating oligotrophy and eutrophication based 
on nutrient concentration scales. Marine Pollution Bulletin, 1992, 24(5), 238-43. 

 

 

Received   7 October 2019  

Accepted   20 November 2019