بررسي نقش تكتونيك در ناهنجاري مورفومتري شبكه‎ي زهكشي در چهار حوضه‎ي آبخيز در زاگرس

بررسي نقش تكتونيك در ناهنجاري مورفومتري شبكه‎ي زهكشي در چهار حوضه‎ي آبخيز در زاگرس

اين پژوهش، نقش تكتونيك در ناهنجاري سيستم زهكشي در چهار حوضه‎ي زهكشي پيران، پاطاق، كمندان و درّه‎تخت در زاگرس شمال‎غرب را بررسي كرده است. شاخص ناهنجاري سلسله‎مراتبي (?a)، شاخص انشعابات (R)، شاخص عدم تقارن حوضه (AF)، شاخص تقارن توپوگرافي عرضي حوضه (T) و الگوي زهكشي پارامترهاي مورد بررسي اين پژوهش هستند. پارامترهاي مذكور، بر اساس نقشه‎هاي توپوگرافي با مقياس 50000/1 به‎دست آمد. خطوط منحني ميزان، با اختلاف ارتفاع 20 متر حوضه‎ها در محيط نرم‎افزار ILWIS رقومي شد و بر اساس آن، نقشه‎ي مدل ارتفاعي رقومي حوضه‎ها و شبكه‌هاي زهكشي با درجه‎هاي مختلف به‎روش استراهلر تهيه شد. بعد از تعيين مسيرهاي زهكشي ناهنجار و تعداد آبراهه‎ها در هر مسير، شاخص‎هاي ناهنجاري زهكشي براي حوضه‎ها تعيين شد. شاخص‎هاي عدم تقارن حوضه (AF) و شاخص تقارن توپوگرافي عرضي حوضه (T) بر اساس تعيين خط مركز حوضه‎ها و رودخانه‌هاي اصلي حوضه‎ها محاسبه شدند. نتايج اين پژوهش نشان مي‌دهد كه مقدار شاخص ناهنجاري سلسله‎مراتبي (?a) در حوضه‎ي پاطاق و پيران كه در زاگرس چين‎خورده قرار دارند، نسبت به دو حوضه‎ي ديگر در زاگرس رورانده، بيشتر است. شاخص مذكور در حوضه‎هاي پاطاق، پيران، كمندان و درّه‎تخت به‎ترتيب 06/2 ، 65/1، 24/1، 15/1 است. حداكثر پارامتر R (شاخص انشعابات) نيز در حوضه‎ي پاطاق (01/1) و حداقل آن در حوضه‎ي كمندان (75/0) است. بررسي داده‎ها نشان مي‎دهد، رابطه‎ي معنادار مستقيمي بين پارامتر ?a و AF وجود دارد، به‎طوري‎كه ضريب همبستگي بين اين دو متغيّر 96 درصد است. ضريب همبستگي بين ?a و T نيز87 درصد است؛ با اين وجود، بررسي رابطه بين پارامتر R و AF نشان مي‎دهد كه رابطه‎ي مستقيمي بين اين دو متغيّر وجود ندارد و ضريب همبستگي آنها حدود 44 درصد است. ضريب همبستگي بين R و T نيز ضعيف (23 درصد) است. مطالعه‎ي الگوي زهكشي در حوضه‌ها نشان داد كه حوضه‌هاي قديمي‌تر و فرسايش‎يافته‌ترِ واقع در زاگرس رورانده (كمندان و درّه‎تخت) الگوي زهكشي شبكه‎ي درختي دارند. الگوي زهكشي كلّي در دو حوضه‎ي پيران و پاطاق (در بخش جوان‎تر و فعّال‎تر زاگرس چين‎خورده) داربستي است، با اين وجود، در اين حوضه‎ها در پهلوهاي پرشيب طاقديس‎ها، الگوي موازي توسعه يافته است، درحالي‎كه در مناطق كم‎شيب ساختماني‌، الگوي شبكه‎ي درختي ديده مي‎شود. به‎طوركلّي، اين پژوهش نشان مي‎دهد كه ناهنجاري زهكشي در حوضه‌هاي مورد مطالعه، متاثر از تكتونيك بوده و پارامتر ?a، در مقايسه با پارامتر R‌، كارايي بالايي در تعيين تكتونيك فعّال حوضه‎ها دارد.

Introduction Studied catchments are parts of Zagros belt which is part of the Arabia–Eurasia collision zone. Zagros is an example of a young and active orogenic belt and geomorphic, geologic and seismic evidences reveal that uplifting is migrating from northeast towards the southwest. Among geomorphological evidence of active tectonics, drainage systems and their characteristics like drainage pattern, drainage anomaly, confluence angle of drainages and river direction play an important role in identifying active tectonics and their Spatial variations. In this study, with the aim of evaluation of effect of tectonic on drainage system anomaly, four catchments, Patagh, Piran, Kamandan and Daretakht have been studied. Patagh and Piran are located in Zagros Folded Belt and two other catchments are located in Zagros Thrust Belt. General characteristics of catchments like drainage divide and topography were extracted from topographic maps at a scale of 1:50000. Geological units and their areas were derived from 1:250000-scale geological maps. Methodology Hierarchical anomaly index (?a), Bifurcation index (R), asymmetry factor (AF), transverse topographic symmetry factor (T) and drainage pattern are studied parameters in this research. For calculating mention factors, at first, 20 meter topographic contour lines of catchments have been digitized in the ILWIS (Integrated Land and Water Information System) software and thereby Digital Elevation Model (DEM) and drainage system ordering by Strahler’s method have been prepared. After ordering process, number of channels for all orders was determined. Then, anomalous drainage paths and number of rivers in each anomalous path were achieved. For calculating Hierarchical anomaly index, at first, Ha (minimum number of first order channels which would be necessary to make the drainage network perfectly hierarchized), were calculated for catchments. ?a was calculated as the ratio of Ha divided by the real number of first-order segments of the network. Bifurcation index (R) was calculated as the difference between the bifurcation ratio and the direct bifurcation ratio . of channels with a given order was computed by dividing the number of channels of a given Order by the number of channels of the immediately higher order. Bifurcation ratio of a catchment was achieved by the mean Rb of all stream orders. Direct bifurcation ratio was calculated as: Where represents the number of channels of a given order that flow in channels of the next, higher order, and is the number of channels of the next higher order. The asymmetry factor (AF) was defined as AF=100 (Ar/At), where Ar is the area of the catchment to the right (facing downstream) of the trunk stream, and At is the total area of the catchment. Transverse topographic symmetry factor was calculated as T=Da/Dd, where Da is the distance from the midline of the catchment to the main river, and Dd is the distance from the catchment midline to the catchment divide. Results and Discussion Results of this study shows that the values of hierarchical anomaly index (?a) in Piran and Patagh, in the zone of Folded Zagros, are higher than Kamandan and Daretakht catchments located in the zone of Thrust Zagros. The values of mentioned index in Patagh, Piran, Kamandan and daretakht catchments are 2.06, 1.65, 1.24 and 1.15 respectively. The highest value of Bifurcation index (1.01) is in Patagh and the lowest value (0.75) is in Kamandan catchment. The T values of Patagh, Piran, Kamandan and daretakht catchments are 48%, 39%, 33% and 21% respectively. The values of AF in Patagh, Piran, Kamandan and daretakht are 63, 59, 57 and 56 respectively, indicating that all catchments have been titled towards left. Data analysis reveals that there is meaningful positive relation between ?a and AF so that correlation coefficient (R^2) of these two parameters is 96%. Correlation coefficient between ?a and T is 87%. Nevertheless, studying the relation between R and AF shows that there no positive relation between these two parameters and that their R^2 is 44%. Correlation coefficient between R and T is also weak (23%). Conclusion Studying the drainage pattern of studied catchments illustrates that older and more eroded catchments (Kamandan and Daretakht) in Thrust Zagros have dendritic drainage pattern. Drainage pattern in Patagh and Piran catchments (in younger parts of Folded Zagros) is trellis. However, parallel drainages have developed in steep limbs of anticlines whereas dendritic pattern have established in structural gentle slope. Overall, this research shows that drainage anomaly in studied catchments is affected by tectonics and, that ?a has more performance than R in determining active tectonics of catchments.