Your search keyword '"Alraddadi, Turki M."' showing total 9 results

1. Heat Balance in the Sharm Obhur and Exchange with the Red Sea

Author

Alshreem, Badriah M., Alsaafani, Mohammed A., Alraddadi, Turki M., and Abdulla, Cheriyeri Poyil

Published

2019

2. Climatology of mixed layer depth in the Gulf of Aden derived from in situ temperature profiles

Author

Abdulla, Cheriyeri P., Alsaafani, Mohammed A., Alraddadi, Turki M., and Albarakati, Alaa M.

Published

2019

3. What Causes the Arabian Gulf Significant Summer Sea Surface Temperature Warming Trend?

Author

Alawad, Kamal A., Al-Subhi, Abdullah M., Alsaafani, Mohammed A., and Alraddadi, Turki M.

Subjects

OCEAN temperature, ATLANTIC multidecadal oscillation, ATMOSPHERIC temperature, AIR masses, SUMMER, TIME series analysis, WATER masses

Abstract

The present study investigated the significant sea surface temperature (SST) warming trend during the summer season over the Arabian Gulf (AG) and its links with the large-scale atmospheric driver, namely, the Atlantic multidecadal oscillation (AMO), from 1900 to 2021. The link between the AMO and the AGs oceanic circulations has received little scientific attention. It has been found that there is a significant spatial positive trend, with a maximum of up to 0.6 °C per decade over the far northern end, while the time series trend shows a significant shift after 1995, with an average value of about 0.36 °C per decade. The spatial trend in the AG is eight times and four times higher than the global value from 1980 to 2005 using HadISST and OISST, respectively. The AMOs significant role in the AGs SST significant warming trend has been confirmed by the spatial and temporal correlation coefficient, which is above 0.50 and 0.48, respectively, with statistical significance at the 99% level. The underlying mechanisms that explained the AMO-related AGs SST decadal variability can be explained as follows: when the AMO is in a positive phase, the surface northwesterly wind weakens, leading to (1) less advection of the relatively cold air masses from Southern Europe to the AG and surrounding areas, (2) less evaporation, and thus less surface cooling (3); thus, this enhances the water masses stratification and decreases the upwelling process, and vice versa occurs for the negative phase. For the air temperature, the positive AMO phase coincides with the occurrence of warm air masses covering all of the Arabian Peninsula, North Africa, and Southern Europe. These processes prove that the AMO is a possible candidate for the AGs SST decadal variability, hence enabling a better evaluation of future climate scenarios for this important region. Our results provide initial insights into the AMO-driven spatiotemporal variability in the SST over the AG and prove that the relation is nonstationary over time. Further analyses are required to explore whether the impacts of the AMO are extended to other oceanic variables such as evaporation rate, heat transport, etc. [ABSTRACT FROM AUTHOR]

Published

2023

4. Seasonal Variability in Ocean Heat Content and Heat Flux in the Arabian Gulf.

Author

Alsayed, Afnan Y., Alsaafani, Mohammed A., Al-Subhi, Abdullah M., Alraddadi, Turki M., and Taqi, Ahmed M.

Subjects

ENTHALPY, HEAT flux, SEASONS, SPRING, AUTUMN, COASTAL sediments

Abstract

This study aimed to evaluate the seasonal variability in surface heat content in the Arabian Gulf (AG) based on hydrographic data. The ocean heat content (OHC) was initially estimated from surface to maximum depth (75 m) to show the seasonal variability, where the seasonal temperature reaches to that depth. Then OHC was re-estimated from the surface to a depth of 35 m, which represents the average depth of AG, to obtain accurate horizontal distributions. Results showed that during winter, the northern part of AG experiences the lowest OHC compared to the southeastern part. The monthly spatial average implies that the highest OHC of AG water was in September and October, while the lowest heat content was found in February and March. However, the OHC horizontal distributions were almost the same for the entire gulf during summer. In general, there was increasing in the OHC in the southeast region of the gulf. OHC anomalies are concentrated in the northern region of the AG, while the southeastern part near the Strait of Hormuz has the lowest values. Regarding heat flux, the highest heat gains were during spring, while the highest loss was in autumn. The water exchange between the AG and the Indian Ocean through the Strait of Hormuz may play a major role in the seasonal variability in OHC. [ABSTRACT FROM AUTHOR]

Published

2023

5. Decadal variability and recent summer warming amplification of the sea surface temperature in the Red Sea.

Author

Alawad, Kamal Aldien, Al-Subhi, Abdullah M., Alsaafani, Mohammed A., and Alraddadi, Turki M.

Subjects

OCEAN temperature, GLOBAL warming, SUMMER, BELT & Road Initiative, CLIMATE change

Abstract

Under climate change, regional Sea Surface Temperature (SST) changes are a crucial factor affecting marine ecosystems, which thrive only within a certain thermal limit. Thirty-seven years of monthly gridded Optimum Interpolation SST data from 1982 to 2017 were used to investigate the decadal variability of this parameter in the Red Sea during the summer season, in relation to large-scale climate variability. We identified a non-uniform warming trend beginning around the mid-1990s over the whole basin, with a predominant amplified warming over the northern half (0.04°C year-1), which is approximately four times higher than the global warming trend, but much weaker warming over southern end (0.01°C year-1). It was found that the Atlantic Multi-Decadal Oscillation (AMO) and the Silk Road Pattern (SRP) are shaping the RS SST, since their phase shift concurs with the timing of the significant non-uniform warming over the basin. The AMO triggers the SRP-related vertical and horizontal temperature advection that leads to opposite changes in the SST. We suggest that warming is amplified over the basin due to an overlap with global warming signals. Our results have important implications for interannual and decadal SST predictions based on the predictability of AMO and SRP patterns. [ABSTRACT FROM AUTHOR]

Published

2020

6. Potential Energy Deficit: A Parameter to Indicate Stratification in Sharm Obhur.

Author

Alraddadi, Turki M.

Subjects

*POTENTIAL energy, *HYDROGRAPHIC surveying, *SALINITY, *DENSITY, *WATER

Abstract

Twenty two field trips were carried out during 2016 at the entrance of Sharm Obhour for a hydrographic survey covering all seasons. Also, to investigate a parameter of potential energy deficit which can be used to measure density stratification. The vertical structure of hydrographic properties (temperature, salinity, and density) shows that the water column is almost well-mixed during all seasons (winter, spring and fall season) except summer season where the stratification is clear in the water column. The results show that the peak values of the potential energy deficit ∆P observed during July with of 402.70 ±157.22 J m-2 and this attributed to the strong stratification in the water column. While the lowest values of ∆P were found with 23.09 ±0 J m-2 and 28.02 ±0 J m-2 in October and February months respectively. These lowest values attributed to the strong mixing during these months for the whole water column with small differences in the potential density of about 0.09 kg m-3 . [ABSTRACT FROM AUTHOR]

Published

2020

7. Mixed layer depth variability in the Red Sea.

Author

Abdulla, Cheriyeri P., Alsaafani, Mohammed A., Alraddadi, Turki M., and Albarakati, Alaa M.

Subjects

SEA level, OCEAN surface topography, CLIMATE change, BATHYTHERMOGRAPH

Abstract

For the first time, a monthly climatology of mixed layer depth (MLD) in the Red Sea has been derived based on temperature profiles. The general pattern of MLD variability is clearly visible in the Red Sea, with deep MLDs during winter and shallow MLDs during summer. Transitional MLDs have been found during the spring and fall. The northern end of the Red Sea experienced deeper mixing and a higher MLD associated with the winter cooling of the high-saline surface waters. Further, the region north of 19° N experienced deep mixed layers, regardless of the season. Wind stress plays a major role in the MLD variability of the southern Red Sea, while net heat flux and evaporation are the dominating factors in the central and northern Red Sea regions. Ocean eddies and Tokar Gap winds significantly alter the MLD structure in the Red Sea. The dynamics associated with the Tokar Gap winds leads to a difference of more than 20m in the average MLD between the north and south of the Tokar axis. [ABSTRACT FROM AUTHOR]

Published

2018

8. Atmospheric Forcing of the High and Low Extremes in the Sea Surface Temperature over the Red Sea and Associated Chlorophyll-a Concentration.

Author

Alawad, Kamal A., Al-Subhi, Abdullah M., Alsaafani, Mohammed A., and Alraddadi, Turki M.

Subjects

OCEAN temperature, AIR masses, BOUNDARY layer (Aerodynamics), GLOBAL warming, ATMOSPHERIC circulation, PHYSICS

Abstract

Taking advantage of 37-year-long (1982–2018) of high-quality satellite datasets, we examined the role of direct atmospheric forcing on the high and low sea surface temperature (SST) extremes over the Red Sea (RS). Considering the importance of SST in regulating ocean physics and biology, the associated impacts on chlorophyll (Chl-a) concentration were also explored, since a small change in SST can cause a significant impact in the ocean. After describing the climate features, we classified the top 5% of SST values (≥31.5 °C) as extreme high events (EHEs) during the boreal summer period and the lowest SST values (≤22.8 °C) as extreme low events (ELEs) during the boreal winter period. The spatiotemporal analysis showed that the EHEs (ELEs) were observed over the southern (northern) basin, with a significant warming trend of 0.027 (0.021) °C year−1, respectively. The EHEs were observed when there was widespread less than average sea level pressure (SLP) over southern Europe, northeast Africa, and Middle East, including in the RS, leading to the cold wind stress from Europe being relatively less than usual and the intrusion of stronger than usual relatively warm air mass from central Sudan throughout the Tokar Gap. Conversely, EHEs were observed when above average SLP prevailed over southern Europe and the Mediterranean Sea as a result of the Azores high and westward extension of the Siberian anticyclone, which led to above average transfer of cold and dry wind stress from higher latitudes. At the same time, notably less wind stress due to southerlies that transfer warm and humid air masses northward was observed. Furthermore, physical and biological responses related to extreme stress showed distinct ocean patterns associated with each event. It was found that the Chl-a concentration anomalies over the northern basin caused by vertical nutrient transport through deep upwelling processes are the manifestation of the superimposition of ELEs. The situation was the opposite for EHEs due to the stably stratified ocean boundary layer, which is a well-known consequence of global warming. [ABSTRACT FROM AUTHOR]

Published

2020

9. Large-Scale Mode Impacts on the Sea Level over the Red Sea and Gulf of Aden.

Author

Alawad, Kamal A., Al-Subhi, Abdullah M., Alsaafani, Mohammed A., Alraddadi, Turki M., Ionita, Monica, and Lohmann, Gerrit

Subjects

SEA level, SOUTHERN oscillation, ORTHOGONAL functions, LA Nina, SEAS, BAYS

Abstract

Falling between seasonal cycle variability and the impact of local drivers, the sea level in the Red Sea and Gulf of Aden has been given less consideration, especially with large-scale modes. With multiple decades of satellite altimetry observations combined with good spatial resolution, the time has come for diagnosis of the impact of large-scale modes on the sea level in those important semi-enclosed basins. While the annual cycle of sea level appeared as a dominant cycle using spectral analysis, the semi-annual one was also found, although much weaker. The first empirical orthogonal function mode explained, on average, about 65% of the total variance throughout the seasons, while their principal components clearly captured the strong La Niña event (1999–2001) in all seasons. The sea level showed a strong positive relation with positive phase El Niño Southern Oscillation in all seasons and a strong negative relation with East Atlantic/West Russia during winter and spring over the study period (1993–2017). We show that the unusually stronger easterly winds that are displaced north of the equator generate an upwelling area near the Sumatra coast and they drive both warm surface and deep-water masses toward the West Indian Ocean and Arabian Sea, rising sea level over the Red Sea and Gulf of Aden. This process could explain the increase of sea level in the basin during the positive phase of El Niño Southern Oscillation events. [ABSTRACT FROM AUTHOR]

Published

2019