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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Construction of sediment budgets in large scale drainage basins : the case of the upper Indus River

Ali, Khawaja Faran 03 December 2009
High rates of soil loss and high sediment loads in rivers necessitate efficient monitoring and quantification methodologies so that effective land management strategies can be designed. Constructing a sediment budget is a useful approach to address these issues. Quantifying a sediment budget using classical field-based techniques, however, is labour intensive and expensive for poorly gauged, large drainage basins. The availability of global environmental datasets in combination with GIS techniques provides an opportunity for studying large basins. Following this approach, a framework is presented for constructing sediment budgets for large, data-sparse drainage basins, which is applied to the mountainous upper Indus River basin in northern Pakistan. The methodological framework consists of five steps: (1) analyzing hydro-climatological data for dividing the drainage basin into characteristic regions, and calculating sediment yields; (2) investigation of major controls on sediment yields; (3) identification and mapping of sediment source areas by spatially distributed modelling of erosional processes; (4) spatially distributed modelling of sediment yields; and (5) carrying out the sediment budget balance calculation at the basin outlet. Further analysis carried out on the Indus data has enabled a better understanding of sediment dynamics in the basin.<p> Analysis of the available hydro-climatological data indicates that the basin can be subdivided into three characteristic regions based on whether runoff production and subsequent sediment generation is controlled by temperature (Region 1, upper, glacierized sub-basins), precipitation caused by the monsoon and western disturbances (Region 3, lower sub-basins), or a combination of the two (Region 2, middle reach sub-basins). It is also demonstrated that contrary to the conventional model, the specific sediment yield increases markedly with drainage area along the Indus River. An investigation of major controls on specific sediment yield in the basin indicates that percent snow/ice cover is a major land cover control for specific sediment yield. Spatially distributed erosion modelling predictions indicate that 87% of the annual gross erosion takes place in the three summer months with greatest erosion potential concentrated in sub-basins with high relief and a substantial proportion of glacierized area. Lower erosion rates can be explained by the arid climate and low relief on the Tibetan Plateau, and by the dense vegetation and lower relief in the lower monsoon sub-region. The model predicts an average annual erosion rate of 3.2 mm/a or 868 Mt/a. Spatially distributed sediment yield predictions made with coupled models of erosion and sediment delivery indicate that the Indus sub-basins generally show an increase of sediment delivery ratio with basin area. The predicted annual basin sediment yield is 244 Mt/a and the overall sediment delivery ratio in the basin is calculated as 0.28. The long-term mean annual sediment budget, based on mass balance, is characterized by a gross erosion of 762.9, 96.7 and 8.4 Mt, and a gross storage of 551.4, 66.1, and 6.5 Mt in the upper, middle, and lower regions of the basin, respectively. The sediment budget indicates that the major sources of eroded sediment are located in the Karakoram, in particular in the Hunza basin. Substantial sediment storage occurs on the relatively flat Tibetan Plateau and the Indus River valley reach between Partab Bridge and Shatial. The presented framework for sediment budget construction requires relatively few data, mostly derived from global datasets. It therefore can be utilized for other ungauged or poorly gauged drainage basins of the world.
22

Construction of sediment budgets in large scale drainage basins : the case of the upper Indus River

Ali, Khawaja Faran 03 December 2009 (has links)
High rates of soil loss and high sediment loads in rivers necessitate efficient monitoring and quantification methodologies so that effective land management strategies can be designed. Constructing a sediment budget is a useful approach to address these issues. Quantifying a sediment budget using classical field-based techniques, however, is labour intensive and expensive for poorly gauged, large drainage basins. The availability of global environmental datasets in combination with GIS techniques provides an opportunity for studying large basins. Following this approach, a framework is presented for constructing sediment budgets for large, data-sparse drainage basins, which is applied to the mountainous upper Indus River basin in northern Pakistan. The methodological framework consists of five steps: (1) analyzing hydro-climatological data for dividing the drainage basin into characteristic regions, and calculating sediment yields; (2) investigation of major controls on sediment yields; (3) identification and mapping of sediment source areas by spatially distributed modelling of erosional processes; (4) spatially distributed modelling of sediment yields; and (5) carrying out the sediment budget balance calculation at the basin outlet. Further analysis carried out on the Indus data has enabled a better understanding of sediment dynamics in the basin.<p> Analysis of the available hydro-climatological data indicates that the basin can be subdivided into three characteristic regions based on whether runoff production and subsequent sediment generation is controlled by temperature (Region 1, upper, glacierized sub-basins), precipitation caused by the monsoon and western disturbances (Region 3, lower sub-basins), or a combination of the two (Region 2, middle reach sub-basins). It is also demonstrated that contrary to the conventional model, the specific sediment yield increases markedly with drainage area along the Indus River. An investigation of major controls on specific sediment yield in the basin indicates that percent snow/ice cover is a major land cover control for specific sediment yield. Spatially distributed erosion modelling predictions indicate that 87% of the annual gross erosion takes place in the three summer months with greatest erosion potential concentrated in sub-basins with high relief and a substantial proportion of glacierized area. Lower erosion rates can be explained by the arid climate and low relief on the Tibetan Plateau, and by the dense vegetation and lower relief in the lower monsoon sub-region. The model predicts an average annual erosion rate of 3.2 mm/a or 868 Mt/a. Spatially distributed sediment yield predictions made with coupled models of erosion and sediment delivery indicate that the Indus sub-basins generally show an increase of sediment delivery ratio with basin area. The predicted annual basin sediment yield is 244 Mt/a and the overall sediment delivery ratio in the basin is calculated as 0.28. The long-term mean annual sediment budget, based on mass balance, is characterized by a gross erosion of 762.9, 96.7 and 8.4 Mt, and a gross storage of 551.4, 66.1, and 6.5 Mt in the upper, middle, and lower regions of the basin, respectively. The sediment budget indicates that the major sources of eroded sediment are located in the Karakoram, in particular in the Hunza basin. Substantial sediment storage occurs on the relatively flat Tibetan Plateau and the Indus River valley reach between Partab Bridge and Shatial. The presented framework for sediment budget construction requires relatively few data, mostly derived from global datasets. It therefore can be utilized for other ungauged or poorly gauged drainage basins of the world.
23

The Geopolitics of Infrastructure: Development, Expertise, and Nation on the Indus Rivers

Akhter, Majed January 2013 (has links)
This dissertation approaches the geopolitics of river infrastructure in the Indus Basin through the structured interaction of "hydraulic regionalism" and "technocratic developmentalism". The former occurs when regional elites feel their access to river resources are threatened by upstream infrastructure development. The latter occurs when technocratic elites underplay the geopolitics of regional vulnerability by stressing the overall integrated development of river resources to maximize utility. The dissertation interprets archival, legal, and ethnographic data regarding the negotiation and adjudication of the Indus Waters Treaty between India, Pakistan, and the World Bank, as well as the implementation of the Indus Basin Development Fund Agreement. The dissertation also analyzes upstream/downstream tension between the Pakistani provinces of Punjab and Sindh. The contributions of this dissertation are in the fields of post-colonial state theory, the political ecology/economy of environmental knowledge, the geopolitics of river disputes, and Marxist methodology.
24

Towards Sustainable Flood Management in upper Sindh, Pakistan : A case study of District Sukkur

Khan, Imran January 2013 (has links)
Flooding is the most devastating natural hazard in Pakistan and the recent flooding has demonstrated its severeness. Floods are common all over the country, though the province of Sindh experience the most damages. River Indus flows on a ridge here and once the surplus water during flood events leave the main channel does not return back. Therefore it is very important to adapt to this disaster. This study aims at identifying ways to address the problem of floods in upper Sindh for which Sukkur district was chosen. Questionnaire survey and interviews were conducted in three talukas of the district in the aftermath of recent floods (2010, 2011 and 2012) to provide a baseline study for Sustainable Flood Disaster Management Plan for the upper Sindh region. Recommendations were put to reduce the flood losses for the future floods.
25

Freundschaft und Macht eine Fallstudie aus Indus Kohistan, Nordpakistan

Jahn, Wiegand January 2006 (has links)
Zugl.: Tübingen, Univ., Diss., 2006 u.d.T.: Jahn, Wiegand: Freundschaft und Macht in einer segmentären Gesellschaft
26

Quantified Assessment of the Meteorological Variables Facilitating the Establishment of the Karakoram Anomaly

Bashir, Furrukh, Bashir, Furrukh January 2016 (has links)
Lofty Hindukush, Karakoram and Himalayan (HKH) mountain ranges centered in the Northern Pakistan are host to some of the world’s largest glaciers outside the Polar Regions and are a source of water for drinking and irrigation to the millions of people living downstream. With the increase in the global temperatures, glaciers are reported as retreating globally. However, some of the glaciers in the Karakoram mountain ranges are reported as surging with positive mass balance, especially since the 1990s. This phenomenon is described as "The Karakoram Anomaly". Various efforts have been made to explain the state and fate of the HKH glaciers in the recent past. However, they are limited to quantification of the change in temperature, precipitation and river runoff, or through their impact on future climate projections. For the HKH region, temperature fluctuations have been out of the phase with hemispheric trends for past several centuries. Therefore, climate change in this region is not solely the temperature effect on melting as compared to other glaciated regions. To identify the reasons for the establishment of the Karakoram Anomaly, monthly mean climatic variables for last five decades, reported from meteorological observatories at the valley floors in HKH region, are analyzed. In addition to the climatic variables of temperature and precipitation, monthly mean synoptic observations reported by meteorological observatories in both morning and afternoon, along with monthly mean radiosonde data are used. From these data the role of different near-surface and upper atmospheric meteorological variables in maintaining the positive mass balance of the glaciers and the development of the Karakoram Anomaly can be explained. An overall warming in the region is observed. The trends in the summer temperatures, which were reported as decreasing a decade ago, are now found as increasing in updated time series. However, the overall gradient is still negative. The winter mean and maximum temperatures are increasing with accelerated trends. Both maximum and minimum temperatures in summer are not diverging anymore and the diurnal temperature range is decreasing in the most recent decade. The afternoon cloudiness is found as increasing throughout the year except for spring, which is indicative of an increase in convective uplifting. Moreover, humidity is increasing all over the region; due to evaporation in the spring, from monsoon moisture advection in summer, and due to the recycling of monsoon moisture in autumn. Furthermore, near-surface wind speed and net radiation in the region are decreasing, explaining the decrease in the summer minimum temperature and the presence of the cloudy skies. The decrease in near-surface wind speed, and net radiation, and increase in water vapor pressure put a limit on the evapotranspiration process. In addition, winter and summer precipitation is increasing. The aridity index, which is based on the ratio of precipitation and reference evaporation, indicates that region is turning moisture surplus and energy deficient. Surface atmospheric pressure and 700 hPa geopotential height is increasing due to warming in the bottom layers of the troposphere. Nighttime inversion in the lower tropospheric layers is decreasing due to warming. Analysis of gridded observed and reanalysis datasets indicates that they are not presenting a signal of change in accordance with the instrumental record. Furthermore, it is found that meteorological conditions during the summer season are still favorable for the sustenance of glaciers whereas more melting may occur in the spring season that may increase the early season river flows and may affect lower lying portions of the debris-free glaciers.
27

IMPACTS OF CLIMATE CHANGE ON THE QUANTITY AND TIMING OF RIVER FLOW IN THE UPPER INDUS BASIN, KARAKORAM-HIMALAYA, PAKISTAN / パキスタン国力ラコルム・ヒマラヤ山脈インダス川上流城における河川流量と流出時期に及ぼす気候変動の影響

BAIG, MUHAMMAD SOHAIB 26 July 2021 (has links)
京都大学 / 新制・課程博士 / 博士(工学) / 甲第23429号 / 工博第4884号 / 新制||工||1763(附属図書館) / 京都大学大学院工学研究科社会基盤工学専攻 / (主査)教授 田中 茂信, 准教授 田中 賢治, 准教授 佐山 敬洋 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM
28

Fish exploitation of the Baluchistan and Indus Valley traditions an ethnoarchaeological approach to the study of fish remains /

Belcher, William R. January 1998 (has links) (PDF)
Thesis (Ph.D.)--University of Wisconsin-Madison, 1998. / Includes bibliographical references.
29

Development and conflict : India-Pakistan issue on Indus Water Treaty and China Pakistan Economic Corridor

Abbas, Hassan January 2021 (has links)
Abstract India and Pakistan are at war with each other for over 70 years. To date, the two countrieshave four full scale wars. This thesis evaluates whether the dispute between Pakistan andIndia is linked with the economic development of the rival country or there are otherreasons for it such as terrorism, border disputes, etc. In the analysis, special attention ispaid to tensions related to Kashmir which started in 1948 and are still there. Kashmirplays a vital role in development of Pakistan in a broader context because The IndusRiver, which is the lifeline to Pakistan, flows through the Jammu and Kashmir. Casestudy method was employed, based on secondary data from the existing studies. Thisthesis is based on theories of international politics to explore the Indus Water Treaty andChina Pakistan Economic Corridor in relation to the economic development of Pakistan.The findings reveal that, contrary to the popular belief of the people of the two countriesthat India and Pakistan are fighting over Kashmir’s territory, much of the problems arerelated to economic issues. Indus Water Treaty and China Pakistan Economic Corridorare helping Pakistan in coming out of the vicious circle of poverty and moving towardsdevelopment. Economic development in Pakistan is not beneficial for India, as Pakistanand India compete in their export markets. So, India is creating hurdles in the economicdevelopment of Pakistan. The violation of Indus Water Treaty by India and India’sinterferences in China Pakistan Economic Corridor are two such examples of it. TheChina Pakistan Economic Corridor will increase foreign investment in Pakistan whichwill lead to economic development of Pakistan. This may strengthen Pakistan’s exportsector and challenge India in its international export markets. Therefore, India is creatinghurdles for Pakistan. Moreover, efficient utilization of water may lead to an increase inpower generation in Pakistan which would help it in overcoming energy shortageproblem, especially electricity. If this problem will be resolved, industry and exportsector will be developed, and Pakistan may compete India in export markets. It wasconcluded that major reason of conflicts between India and Pakistan are economic, notpolitical, geographical, or military.
30

D’une amulette en cuivre aux grandes statues de bronze : évolution des techniques de fonte à la cire perdue, de l’Indus à la Méditerranée, du 5e millénaire au 5e siècle av. J.-C. / From a copper amulet to large bronze statues : evolution of lost-wax casting techniques, from the Indus to the Mediterranean, from the 5th millennium to the 5th Century BC.

Mille, Benoit 13 June 2017 (has links)
Dans une démarche pluridisciplinaire, qui emprunte aussi bien aux sciences humaines et sociales (archéologie, histoire des techniques, réexamen des textes anciens) qu’aux sciences chimiques (science des matériaux, métallurgie expérimentale, chimie analytique), cette recherche vise à reconstituer l’évolution des techniques de fonte à la cire perdue, depuis les plus anciens témoignages de son utilisation à Mehrgarh (Pakistan, 5e millénaire av. J.-C.) jusqu’aux premières grandes statues de bronze dans le monde égéen (fin du VIe, début du Ve s. av. J.-C.).L’étude des objets a parfois nécessité des développements analytiques spécifiques pour pallier à leur très forte altération, comme par exemple l’imagerie de photoluminescence synchrotron. Cela a notamment permis de reconstituer en détail la chaîne opératoire de fabrication de la rouelle de Mehrgarh, l’une des plus anciennes fontes à la cire perdue connue à ce jour. Sur la base de ces résultats, il est suggéré que la fonte à la cire perdue pourrait avoir été inventée pour donner la possibilité aux individus non métallurgistes de créer des objets importants en métal tels que ces amulettes, par le biais du façonnage d’un modèle en cire.Nous montrons que la cire perdue a ensuite été mise à profit pour donner naissance à une nouvelle forme de sculpture, la statuaire de métal. Au prix de parois très épaisses et d’assemblages mécaniques, nous mettons en évidence une première période de production de grandes statues en Mésopotamie pendant la deuxième moitié du 3e millénaire av. J.-C. Après un long hiatus, la grande statuaire métallique renaît de façon spectaculaire pendant la première moitié du 1er millénaire av. J. C., à la fois dans les mondes égyptien, sabéen et égéen. Nous identifions deux innovations importantes responsables de cette renaissance : le procédé indirect et l’assemblage soudé.Des essais de coulabilité effectués en faisant varier la composition de l’alliage et le matériau du moule sont présentés dans la dernière partie de notre travail. En moule de plâtre et avec un fort préchauffage, une coulabilité exceptionnelle a été obtenue pour le bronze à fort taux de plomb, donnant pour la première fois une idée des conditions de coulée nécessaires à l’obtention des parois très minces souvent observées sur les grandes statues antiques. / Following a multidisciplinary approach combining social sciences (archaeology, history of techniques, examination of ancient texts) and chemistry (materials science, experimental metallurgy, analytical chemistry), our research aims to reconstruct the evolution of lost-wax casting techniques, from the earliest evidence of its use in Mehrgarh (Pakistan, 5th millennium BC) to the first large bronze statues in the Aegean (end of the 6th, beginning of the 5th century BC).The archaeological artefacts under study have sometimes required specific analytical developments to overcome their very strong alteration, such as synchrotron photoluminescence imaging. This allowed reconstructing in detail the chaîne opératoire of the Mehrgarh wheel-shaped amulet, one of the oldest lost-wax castings known to date. Based on the results thus obtained, it has been suggested that lost-wax casting might have been invented to give non-metalworkers the opportunity to create important metal objects such as amulets by simply shaping a wax model.We show that lost-wax casting was afterwards used to create a new form of sculpture, namely metal statuary. At the cost of very thick metal walls and mechanical assemblies, this led to an early production step of large statues in Mesopotamia during the second half of the 3rd millennium BC. After a long hiatus, large metal statuary reappeared spectacularly during the first half of the 1st millennium BC, both in the Egyptian, the Sabean and the Aegean areas. We were able to identify two important innovations responsible for this renaissance: the indirect process and the flow fusion welding.Castability tests carried out by varying the composition of the alloy and the material of the mould are presented in the last part of our work. An exceptional castability was obtained for highly-leaded bronze in plaster mould and with a high preheating. For the first time some insights are thus drawn on the casting conditions necessary to obtain the very thin walls often observed on large metal statues during the Classical Antiquity.

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