TY - JOUR ID - 50618 TI - Sedimentary Evidence of Climate Changes in Holocene, Zeribar Lake JO - Physical Geography Research JA - JPHGR LA - en SN - 2008-630X AU - Maghsoudi, Mehran AU - Jafar Beglou, Mansour AU - Rahimi, Omid AD - Associate Prof. of Geomorphology, Faculty of Geography, University of Tehran AD - Assistant Prof. of Geomorphology, Faculty of Geography, University of Tehran AD - Ph.D. Candidate in Geomorphology, Dep. of Physical Geography, University of Mohaghegh Ardabili Y1 - 2014 PY - 2014 VL - 46 IS - 1 SP - 43 EP - 58 KW - climate change KW - Lake Sediments KW - Lake Zeribar KW - Palaeogeomorphology DO - 10.22059/jphgr.2014.50618 N2 - IntroductionLakes are very interesting sedimentary environments for study of ancient climate changes in theenvironments and lake level changes. Lake Zeribar is situated in the province of Kurdistan, inthe Zagros Mountains in three kilometers north-west of Marivan. The main purpose of thisresearch is to study grain-size sediments accumulated in Zeribar lakes in order to check thewater level fluctuations, climatic and environmental changes during the Holocene. Grain-size ofthe lake sediments is mainly controlled by the distance of the core site from the shoreline, thekinetic energy of the lake circulation and the source of the sediments (Lerman, 1978). Thesediments sorting principle states that the grain size of lake sediments becomes finer and finerfrom the shore to the center, and sediment belts of different grain-size can be distinguished.Lake Zeribar sediments, providing a record of climatic variations more than 40,000 years long,have been the subject of multidisciplinary investigations reported in several publications(among others: plant macrofossils by Wasylikowa, 1967, 2005; diatoms by Snyder et al., 2001;stable isotopes by Stevens et al., 2001). However, sediments of the lake have not yet beenanalyzed for grain-size, whereas it could reveal important information about the lake history andsedimentary process-geomorphology.􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯􀀯∗E-mail: maghsoud@ut.ac.ir Tel: +98 91239060198 Physical Geography Research Quarterly, 46 (1), Spring 2014MethodologyA 6.88 m long core was extracted from the west part of the lake by a standard chamber corer,the Russian corer, 50 cm in length and 5 cm in diameter.Sediments were sampled at an interval of 1-10 cm. All samples were split into halves andweighed. One half was wet-sieved using a 63 􀈝m diameter sieve. The >63 􀈝m fraction (sand andgranule) was dried and weighed for sand and granule content. The other half was analyzed formineral type. The <63 􀈝m fraction was analyzed using a laser diffraction particle size analyzer(Micro tec A-22, Analysette 22 ) which utilizes grain-size range, 0.001-2 mm. Samples weretreated with 30% H2O2 to remove organic matters. The samples were further dispersed via 10minutes of exposure in an ultrasonic bath just before size analysis. For the purpose of particlesizespecification, the following scale used by Folk and Ward (1957) was adopted; granule:>2mm, sand: 2000-63 􀈝m (-1 to 4􀔄), silt: 63-3.9 􀈝m (4-8􀔄), and clay: 3.9-0.24 􀈝m (8-12􀔄).Radiocarbon dating of the sediments was performed for three bulk sediments using astandard Accelerator Mass Spectrometer (AMS) method at the Institute of Accelerator AnalysisLtd, Japan. The 14CAMS dates were calibrated to years AD and calendar years BP usingOxCalv.4.1 (Bronk Ramsey, 2009) and IntCal09 (Reimer et al, 2009).Results and DiscussionBased on the patterns of long-term fluctuations in median, mean and mode sample diameterscombined with the percentages of the clay: (<2 􀈝m), silt: (2–63 􀈝m) and sand: (>63 􀈝m) sizefractions, frequency curves, and lithology, the whole sediment record is divided into 4subdivisions as A (688-528 cm, 8950-6870 calyr BP), B (528–423cm, 6870-5500 calyr BP), C(423–244 cm, 5500–3170 calyr BP), and D (244–100 cm, 3170–1300 calyr BP) as describedbelow, separately.During phase A (688-528 cm, 8950-6870 cal BP) the percentage content of silt increases to~74.8%, while the content of sand decreases to ~6.33%.During phase B (528–423 cm, 6870–5500 calyr BP), the percentage of sand (average=14%)increases sharply while the percentage of silt (average=67.18%) decreases. The relatively highcontent of sand likewise implies a low lake level, which reflects effective moisture in the wholedrainage.During phase C (423–244 cm, 5500–3170 calyr BP) the percentage content of silt increasesto ~77.4%, while the content of sand decreases to ~5.4% indicating high effective humidity andmoisture in Lake Zeribar. The high and stable content of silt and fine components in thesediments indicates that lake-level reaches its highest value in the Holocene at this time.During phase D (244–100 cm, 3170-1300 calyr BP), the content of sand (average=10.5%)increases while the content of silt (average=69.86%) decreases. Several cycles in grain-size maybe related to centennial climate cycles. The high content of the coarse component suggest lakelevellowering.Physical Geography Research Quarterly, 46 (1), Spring 2014 9ConclusionThe grain size data and descriptive statistics (mean, standard deviation, kurtosis, and skewness)showed various degrees of fluctuations in both short and long terms. Changes in climate andlake size appear to be the main factors affecting the variability in the grain-size distribution,properties, and type of minerals. The results of the data analysis suggests the existence of warmand wetter climate, increased spring rains, episode of higher lake water level, existence of freshwaterconditions, prevailing high-energy condition, dominance of erosional processes, seasonalsupply of detritus, inflows strength and dominance of chemical weathering about 8950-6870and 5500-3170 calyr BP. The results indicate the existence of dry climate, reduced rainfall,occurrence of drought, lake-level lowering, prevailing low-energy condition, absence ofseasonal supply of detritus, conditions of tidal changes, and dominance of physical weatheringabout 6870-5500 and 3170-1300 calyr BP. It can be suggested that during the late Holocene3170-1300 calyr BP variations of water-level occurred irregularly, as the results of precipitationchanges, occasional lake overflows, and perhaps human activities. UR - https://jphgr.ut.ac.ir/article_50618.html L1 - https://jphgr.ut.ac.ir/article_50618_60b8ac5a5f49507d34e34db64547eb5e.pdf ER -