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Volume 3, Issue 1 (4-2016)
Climate change is one of the most significant threats facing the world today. One of the most important consequences of climate change is increasing frequency of climate hazards, mainly heat waves. This phenomena has a robust impacts on human and other ecosystems. The aim of this study is investigating changes of heat waves in historical (1980-2014) and projected (2040-2074) data in northern cost of Persian Gulf.
The focus here is on Mean daily maximum temperature and Fujibe index to extract heat waves. For this purpose 6 weather stations locating in north coast of Persian Gulf, Iran, are used (table 1).
Table1: weather stations
|
Station |
Latitude |
Longitude |
Elevation(m) |
|
Abadan |
30° 22' N |
48° 20' E |
6.6 |
|
Boushehr |
28° 55' N |
50° 55' E |
9 |
|
Bandarabbas |
27° 15' N |
56° 15' E |
9.8 |
|
Bandarlengeh |
26° 35' N |
54° 58' E |
22.7 |
|
Kish |
26° 54' N |
53° 54' E |
30 |
In addition, 4 model ensemble outputs from the Coupled Model Intercomparison Project Phase 5 (CMIP5) are used to project future occurrence and severity of heat waves (2040 to 2070), under Representative Concentration Pathways 8.5 (RCP8.5), adopted by the Intergovernmental Panel on Climate Change for its Fifth Assessment Report (AR5) (table 2).
Table2: List of the AR5 CMIP5 Used Models
|
Model |
Modeling Cener |
Country |
|
CanESM2 |
Canadian Earth System Model |
Canada |
|
MPI-ESM-MR |
Max-Planck-Institut für Meteorologie |
Germany |
|
CSIRO-Mk3-6-0 |
Commonwealth Scientific and Industrial Research Organization |
Australia |
|
CMCC-CESM |
CMCC Carbon Earth System Model |
Italy |
The output of models is downscaled using artificial neural network method (ANN). A feed-forward network of multi-layer perceptron with an input layer, a hidden layer and an output layer is used for this purpose. 73 percent (1980 – 2000) of the data is used for training and 27 percent (2000-2005) for testing ANN models. Root Mean Square Error (RMSE) is used as an indicator of the accuracy of Models.
RMSE=
Here 
is the outputs of ANN models (downscaled data) and 
is the observation data.
Fujibe et all (2007) used an index based on Normalized Thermal Deviation (NTD) for extracting long-term changes of temperature extremes and day to day variability using following equations:
Where N is the number of days in the summation except missing values. Then nine-day running average was applied three times in order to filter out day-to-day irregularities.
=(i,j,n)=T(i,j,n)-T(I,j)
The departure from the climatic mean is given by
=
If NTD >2 and at least lasts for 2 days it determine as a heat wave.
Results
Table 3 shows the results of downscaling selected GCM models.
|
nodes |
RMSE |
Average RMSE |
||||||
|
Sigmoid function |
Linear function |
Abadan |
Bushehr |
Bandarabbas |
Bandar-e-Lengeh |
Kish |
||
|
CanESM2 |
5 |
1 |
9.6 |
6.1 |
4.85 |
4.7 |
4.5 |
5.97 |
|
MPI-ESM-MR |
5 |
1 |
9.3 |
7.1 |
3.9 |
5 |
4.3 |
5.9 |
|
CSIRO-MK3-6-0 |
15 |
1 |
8.8 |
5.6 |
3.6 |
3.4 |
3.6 |
5 |
|
CMCC-CESM |
10 |
1 |
9.2 |
5.8 |
3.9 |
4.7 |
3.9 |
5.5 |
Table 4 compares the frequency of heat waves for GCMs and historical data.
|
CanESM2 |
MPI-ESM-MR |
CSIRO-Mk3-6-0 |
CMCC-CESM |
Historical data |
|
|
Abadan |
434 |
401 |
448 |
387 |
430 |
|
Bushehr |
376 |
423 |
420 |
406 |
407 |
|
Bandarabbas |
441 |
405 |
457 |
382 |
410 |
|
Bandar-e-Lengeh |
380 |
414 |
388 |
401 |
400 |
|
Kish |
421 |
442 |
415 |
442 |
399 |
For historical data, heat waves are more frequent in Abadan station than other stations. There is an increasing trend in the occurrence of heat waves in historical data and monthly frequency of heat waves show the highest amounts for summer.
For both historical and future data 2 days listening heat waves are more frequent.
Table 5 shows seasonal changes of heat waves for historical data and GCMs.
|
season |
The ratio of heat waves from total historical data (percent) |
The ratio of heat waves from total projected data (percent) |
|
|
Abadan |
Spring |
30.43 |
24.02 |
|
Summer |
29.19 |
27.87 |
|
|
Autumn |
17.39 |
22.61 |
|
|
Winter |
22.98 |
25.48 |
|
|
Bushehr |
Spring |
21.42 |
24.23 |
|
Summer |
25 |
26.21 |
|
|
Autumn |
28.57 |
24.82 |
|
|
Winter |
24 |
25.32 |
|
|
Bandarabbas |
Spring |
21.73 |
24.7 |
|
Summer |
26.81 |
27.01 |
|
|
Autumn |
25.81 |
25.17 |
|
|
Winter |
24.1 |
24.63 |
|
|
Bandar-e-Lengeh |
Spring |
23.55 |
23.74 |
|
Summer |
23.33 |
29.82 |
|
|
Autumn |
23.74 |
25.81 |
|
|
Winter |
25.17 |
20.8 |
|
|
Kish |
Spring |
24.27 |
24.8 |
|
Summer |
25.53 |
28.32 |
|
|
Autumn |
23.35 |
25.21 |
|
|
Winter |
23.1 |
23.8 |
In recent years the frequency of heat waves is increasing in all studied stations. Coincide with Russia and Europe, the highest amounts of heat waves is occurred in 2010 in northern coast of Persian Gulf and this is adopted Esmaeilnezhad et all (2013), Gavidel (2015) and Azizi (2011).
Volume 5, Issue 3 (12-2018)
Sea surface temperature is one of the most effective physical parameters that affects the health of coral reefs communities.High frequency of the bleaching phenomenon has extensively occurred in the Persian Gulf in the recent years due to the increase in temperature and increased changes in the sea surface temperature (SST) resulting in great mortality in the coral communities. The aim of this research is to determinate a temperature threshold which may function as a warning for the incidence anticipation of this phenomenon. Data on the variation of the SST that has been taken from National Oceanic and Atmospheric Administration (NOAA). Information related to bleaching in the regions of the southern Persian Gulf was extracted from the published papers and reports. Each of these sources also has been extracted for a 35-year statistical course (1980-2015) and by the index of degree heating weeks (DHWs) determined for the same statistical course in this research for the assessment and anticipation of bleaching phenomenon. For reviewing of the work accuracy, Peirce Skill Score (PSS) technique was used to quantify the accuracy of previous and subsequent anticipations. According to the derived results, DHWs threshold for the study region was determined to be 7.13. the threshold 7.13 for DHW is suggested as a caution threshold for bleaching incidence in southern regions of the Persian Gulf that is whenever the values of weekly positive temperature DHW show number 7.13 and higher, there is an expectation of bleaching phenomenon incidence of corals for these regions. And the score of PSS= 0.72 derived from the amounts of H= 7/8= 0.87 for the Hit rate and F= 4/26= 0.15 for the False alarm rate of the bleaching was obtained for the southern regions of Persian Gulf and study region. In northern regions of the Persian Gulf the threshold 5.3 for DHW is suggested as a caution threshold for bleaching incidence. The rate of pss = 0.62 derived from the amounts of (3/4 = 0.75) for the Hit rate and ( 3/23 = 0.13) for the False alarm rate of the bleaching was obtained for the northern regions of Persian Gulf and study region. Difference in DHWs values of the south and north of Persian Gulf shows more resistance of the corals of south Persian Gulf against DHW changes and SST anomalies. Also the amounts of DHW alongside SST can help more completely to the anticipation of bleaching phenomenon.
Volume 9, Issue 3 (12-2022)
Synoptic analysis of the changes trend of the share of systems due to the Sudan low
In the cold period of the Persian Gulf coast during 1976-2017
Introduction
In the Ethiopian-Sudan range forms the low pressure system without front in the cold and transition seasons that is affecting the climate of the adjacent regions by crossing the Red sea. Based on the evidence in the context of Iran, studying Sudan low was first begun by Olfat in 1968. Olfat refers to low pressures which are formed in northeastern Africa and the Red Sea and then pass Saudi Arabia and the Persian Gulf, enter Iran, and finally, cause rainfall. The most comprehensive research specifically examining Sudan low, was the work carried out by the Lashkari in 1996. While he studying the floods that occurred in southwestern of Iran, he was identified Sudan low by the most important cause of such flooding and he explained how they are formed, and how these low-pressure systems were deployed on the southwest of Iran.
Materials and methods
The study period with long-term variations was considered from 9.5 to 11 years based on solar cycles. Precipitation data for 13 synoptic stations are considered above 5 mm in south and southwestern Iran. With three criteria were determined for the days of rainfall caused by each type of atmospheric system. The visual analysis of high and low altitude cores and geopotential height at 1000 hPa pressure level (El-Fandy, 1950a; Lashkari, 1996; 2002) were considered based on the aim of the study. Accordingly, the approximate locations of activity centers, as well as the range of the formation and displacement of the Sudan system were initially identified based on the location of the formation of low and high-pressure cores. Then, the rainy days due to the Sudan system in January were separated from the precipitation of the other atmospheric system.
Results and discussion
According to the selected criteria in the forty-year statistical period, 507 precipitation systems were identified with different continuities that led to precipitation in the northern coast of the Persian Gulf. The pattern of independent Sudan low rainfall was responsible for 77% of the precipitation in the Persian Gulf. Decade frequency share of Sudan low was lower in the first decade (16%) compared to the next three decades. This system of rainfall was more activated during the second and third decades compared to the first decade. However, rainfall changes were not evident in the mid-decade. Independent Sudan low precipitation provide 25% and 27% of the cold season precipitation of the Persian Gulf during the second and third decades respectively. In accordance with the 24th solar cycle, at the end of the study period, the Sudan low was more effective on the Gulf coast than ever before. During this decade, 125 cases of Sudan low rainfall was recorded for the Persian Gulf. Thus, the frequency of Sudan low during the fourth decade was about 31%, which was higher than in the rest of the decade. Overall, the Sudan low rainfall was repeated 151 times for 2 days rainfall, during the statistical period studied. This Precipitation has increased over the last decades compared to other periods.
Conclusion
The severe variability of rainfall along the timing and location of the permanent Persian Gulf coasts can have a significant impact on the economic and agricultural behavior of the Gulf population in the three provinces of Ahwaz, Bushehr and Hormozgan.The purpose of this study was to evaluate the precipitation changes due to Sudan low in the Persian Gulf coastal region during the cold period. The results of this study showed that the role of integration patterns in influencing the precipitation of the Persian Gulf coast has decreased with the strengthening and further activation of the Sudan low system during the last two decades. That way, about 77percent of the region's rainfall is provided by independent Sudan low. At the end of the course (in accordance with 24th solar cycle activity) the Sudan low system was more active than before. Although the Sudan low activity was different at each station during the period studied, but in the historical passage incremental and decade's positive behavior of Sudan low was common to all stations. Evaluation of changes in rainfall duration shows that the pattern of precipitation with 2days duration is more frequent than the patterns of one to several days.
Keywords: Sudan low- Solar cycle- Persian Gulf.
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