Investigating the Interaction of Caspian Sea Level Change and Sediment Fluctuations in Coastline changes (Case study:Tajan River shoreline)

Document Type : مقاله پژوهشی

Authors

University of Tehran

Abstract

Introduction

Coastal changes are one of the major environmental issues that affect coastal areas around the world. The Caspian shores have been considered by human societies and numerous activities have taken place on the coast. Sea-level changes cause damages. Today, several methods are used to monitor coastlines throughout the world. Remote sensing data is often replaced by field studies. The aim of this study is monitoring the changes of the Caspian Sea coastline in Tajan river coast from 1955 to 2016 in order to identify relationship between coastal displacement and sea level changes and sedimentary changes in this area. In this research, coastal lines have been investigated over a long period of time when the water surface has rapid changes. In addition, the amount of sediment and water discharges have been used as an effective factor in the displacement of coastal lines.

Materials and Methods

The study area is located in the Mazandaran province and the middle part of the southern shores of the Caspian Sea, with a geographical position of 36◦48'25'' northern latitude and '53◦05'18'' eastern longitude in the western of the estuary to 36◦49'30'' northern latitude and 53◦09'50'' eastern longitude which is located in the western part of estuary. First, all aerial photographs and digital maps of 1: 25,000 from the National Mapping Organization and Google Earth images of 2013 and 2016 were prepared. Aerial photos were scanned, then carefully georeferenced by Arc GIS 10.3 software. In order to accurately estimate these images, they were matched with 1: 25,000 digital maps. Finally, the coast line was drawn by the Water Line method. In the next step, Google Earth images were received using geospatial elshayel smart software. Again, they were adapted with digital maps of 1: 25,000. Then, the coast line was drown in Arc GIS 10.3 software. The DSAS extension was used in 10.3 Arc GIS software to determine the coastline variation. For this purpose, across the coast, transects were drown perpendicular to the coastline at intervals of 100 meters and then the statistical parameters were extracted. Finally, water and sediment data from Iran Water Resources Management Company were received and the mean water and sediment discharge were calculated individually at each time interval and adapted to the position of the coastline.

Results and Discussion

The level of the Caspian Sea has been fluctuating since 1955. For the better study of the shorelines of the Caspian Sea, coastal changes were calculated based on incremental and decreasing sea level cycles. The findings of this study showed that the coastline of Tajan River has not been stable since 1955. In order to achieve the shorelines change in each sea level changes, the statistical parameters for the first period from 1955 to 1977 were examined on the coastlines in this time period. In this section, the EPR, SCE, and the NSM values were 1,765, 25.62, and19.60, respectively. All values in this period are positive and indicate the accretion. The nearest water and sediment station is Kordkhil Station where the water flow rate data is available since 1969 and the sediment discharge data is available since 1981. It does not include the first time zone, so it was not considered for the first time period. The second time period, from 1977 to 1995 includes two series of coastal lines including 1981 and 1994. In this section, the EPR was -11.90, the SCE was 155.22, and the NSM equaled -155.22. This part of the coast in this time have erosion. In the second period of time, the rate of water flux at Kordkhil station is 14.36 m 3 / s and the sediment discharge rate at Kordkhil station is 14802.79 tons per month. The third time has been around since 1995 until now which includes three series of coastlines surveys including 2006, 2013, and 2016. In this section, EPR was 5.95, SCE was 61.26, and NSM equaled 61.24. This part of the coast has a sedimentation status. In the third time period at Kordkhil station, the water flux rate is 9. m 3 / s, and the sediment discharge rate is 42406.5 tons per month.

Conclusion

The rise of the sea level causes beach erosion, as it causes water to deepen and finaly causes larger and stronger waves to reach the coast and the sand is transported to the sea. Also, down on the surface of the sea, causing sedimentation. This study in the Tajan River confirms the scientists' view on the role of the sea level at the location of the beaches. In the first period of time, the most changes occurred in the estuarine to the eastern or river, which indicates the effective role of sediments in the estuaries. In addition, moving sediments through longshore current along the western shores of the Caspian Sea is so important. Because these flows move from west to east and divert the sediments to the east. There is a severe erosion of the coast in the second time zone. Rising water prevents sedimentation and the highest rate of erosion in this period is in the eastern part. Totally, in this time, three factors of the sea level increase, increasing water flow, and reducing the sediment discharge can be effective. There is a reduction in the water level during the third period and the rate (EPR) in each transect is different. The highest amount of sediment is found in the estuary of the river and the east of river. The amount of water flood in this period decreased compared to the previous period and the amount of sediment has increased. High sediment supply, reduced water flow, reduced sea level, and expanding location for growing beaches has led to coastal advances towards the sea, and the longshore current moved these sediments to eastward. Finally, according to the results, it can be said that the displacement of the coastline is according to the general rules that scientists have said about the changes in the sea level and the displacement of the coastline.

Keywords


برد، اریک؛ چارلز، فردریک؛ (1392) ژئومورفولوژی ساحلی (ترجمه مجتبی یمانی، وحید محمد نژاد)، انتشارات دانشگاه تهران.
تقوی مقدم، ابراهیم؛ قنواتی، عزت‌الله؛ اکبری، الهه؛ حسینی، هاشم؛ (1396) تحلیل ژئومورفودینامیک تغییرات خط ساحلی قاعده دلتای رودخانه مند بوشهر با استفاده از سنجش‌ازدور. فصلنامه‌ی علمی-پژوهشی فضای جغرافیایی، سال هفدهم، شماره 60، 190-169
خسرویان، مریم؛ انتظاری، علیرضا؛ رحمانی، ابوالفضل؛ باعقیده، محمد؛ (1396) پایش تغییرات سطح آب دریاچه پریشان با استفاده از شاخص‌های سنجش‌ازدور. مجله هیدروژئومورفولوژی، شماره 13، 120-99
شریفی کیا، محمد؛ شایان، سیاوش؛ ولی، مایسا؛ تعیین تغییرات دینامیک خط ساحل بخش شرقی دریای خزر به کمک داده‌های چند زمانه/چند سنجنده‌ای.(1396) برنامه‌ریزی و آمایش فضا، دوره بیست و یکم، شماره 4
عبدالهی کاکرودی، عطااله؛ (1392) نوسانات دریای خزر و تأثیر آن بر سواحل جنوب شرقی دریای خزر. پژوهش‌های ژئومورفولوژی کمی، سال دوم، شماره 3، 44-33
لرستانی، قاسم؛ (1394). بررسی تغییرات خط ساحلی با استفاده از روش پلی گون تغییرات، محدوده موردمطالعه: قاعده دلتای سفیدرود. پژوهش‌های ژئومورفولوژی کمی، سال چهارم، شماره 3، 180- 168
نگهبان، سعید؛ باقری، کیوان؛ حیدری، سوسن؛ گروسی، لیلا؛ (1396) بررسی و پایش تغییرات خط ساحلی دریای عمان در منطقه جاسک. پژوهش‌های ژئومورفولوژی کمی، سال ششم، شماره 1، 136-119
Bruun P. 1962. Sea-Level Rise as a Cause of Shore Erosion. American Society of Civil Engineers Journal of the Waterways and Harbours Division. 88: 117–130
Burningham Helene. French Jon. 2017. Understanding coastal change using shoreline trend analysis supported by cluster-based segmentation. Geomorphology 282:131–149
Chen J. L. Pekker T. Wilson C. R. Tapley B. D. Kostianoy A. G. Cretaux J.F. and Safarov E. S. 2017.Long-term Caspian Sea level change. Geophysical Research Letters. 21 JUN 2017
Dolan R. Hayden B.P. May P and May S.K. 1980. The reliability of shoreline change measurements from aerial photographs. Shore and Beach, 48(4): 22–29.
Esmail, Mohammed. Elham Mahmod Wael. Fath Hassan.2019.Assessment and prediction of shoreline change using multi-temporal satellite images and statistics: Case study of Damietta coast, Egypt. Applied Ocean Research 82: 274–282
Hakko Mounir. Hakko Mehdi. Hakko Tarik. El khalidi Khalid. El Ouai Driss. Benmohammadi Aïcha. 2018. Multi-decadal assessment of shoreline changes using geospatial tools and automatic computation in Kenitra coast, Morocco. Ocean and Coastal Management 163: 232–239
Jonah F.E. Jonah I. Osman A. Shimba M.J. Mensah E.A. Adu-Boahen K. Chuku E.O. Effah E.2016. Shoreline change analysis using end point rate and net shoreline movement statistics: An application to Elmina, Cape Coast and Moree section of Ghana’s coast. Regional Studies in Marine Science 7: 19–31
Kakroodi A.A. Kroonenberg S.B. Hoogendoorn R.M. Mohammd Khani H. Yamani M. Ghassemi M.R. Lahijani H.A.K. 2012. Rapid Holocene sea-level changes along the Iranian Caspian coast, Quaternary International 263:93e103
Kankara R. S. Chenthamil Selvan S. Markose Vipin J. Rajan B. Arockiaraj S.2015 Estimation of long and short term shoreline changes along Andhra Pradesh coast using Remote Sensing and GIS techniques. Procedia Engineering 116: 855 – 862
Kermani Saci. Boutiba Makhlouf. Guendouz Mostefa. Guettouche Mohamed.Said. Khelfani Dalila 2016. Detection and analysis of shoreline changes using geospatial tools and automatic computation: Case of jijlian sandy coast (East Algeria). Ocean & Coastal Management 132: 46e58
Manc E. Pascucci V. Deluca M. Cossu A. Andreucci S. 2013. Shoreline evolution related to coastal development of a managed beach in Alghero, Sardinia, Italy. Ocean. Coast. Manag. 85: 65e76.
Masselink G. and Russell P. 2013 Impacts of climate change on coastal erosion, MCCIP Science Review, 71-86, doi:10.14465/2013.arc09.071-086
Misra A. Balaji R. A.2015. study on the shoreline changes and Land-use/ land-cover along the South Gujarat coastlineA study on the shoreline changes and Land-use/ land-cover along the South Gujarat coastline. Procedia Engineering 116: 381 – 389
Naderi beni Abdolmajid. Alizadeh-Lahijani Hamid. Pourkerman Majid. Jokar Rahman. Djamali Mortza. Marriner Nick. Andrieu-Ponel Valerie. Mousavi Harami Reza.2014. Late Holocene Caspian Sea Level Changes and its Impacts on Low Lying Coastal Evolution: a Multidisciplinary Case Study from South Southeastern Flank of the Caspian Sea. Journal of the Persian Gulf (Marine Science)/Vol. 5/No. 16/June 2014/22/27-48
Natesan Usha. Parthasarathy Anitha. Vishnunath R. Edwin Jeba Kumar Vincent G. Ferrer A .2015. Monitoring longterm shoreline changes along Tamil Nadu, India using geospatial techniques. Aquatic Procedia 4: 325 – 332
Pilkey O.H. Hume T. 2001. The shoreline erosion problem: lessons from the past.Water Atmos. 9 (2), 22e23.
Salghuna N.N.Aravind Bharathvaj S.2015. Shoreline Change Analysis For Northern Part Of The Coromandel Coast. Aquatic Procedia 4: 317 – 324
Vivek G. Goswami Santonu. Samal R.N. Choudhury S.B.2019. Monitoring of Chilika Lake mouth dynamics and quantifying rate of shoreline change using 30m multi-temporal Landsat data. Data in Brief 22: 595–600
CAPTCHA Image