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    Coastal vulnerability assessment of the future sea level rise in Udupi coastal zone of Karnataka state, west coast of India
    (2009) Dwarakish, G.S.; Vinay, S.A.; Natesan, U.; Asano, T.; Kakinuma, T.; Venkataramana, K.; Pai, B.J.; Babita, M.K.
    Udupi coast in Karnataka state, along the west coast of India, selected as a study area, is well known for sandy beaches, aquaculture ponds, lush greenery, temples and major and minor industries. It lies between 13°00?00?-13°45?00? north latitudes and 74°47?30?-74°30?00? east longitudes, the length of the coastline is 95 km, and is oriented along the NNW-SSE direction. It is vulnerable to accelerated sea level rise (SLR) due to its low topography and its high ecological and touristy value. The present study has been carried out with a view to calculate the coastal vulnerability index (CVI) to know the high and low vulnerable areas and area of inundation due to future SLR, and land loss due to coastal erosion. Both conventional and remotely sensed data were used and analysed through the modelling technique and by using ERDAS Imagine and geographical information system software. The rate of erosion was 0.6018 km2/yr during 2000-2006 and around 46 km of the total 95 km stretch is under critical erosion. Out of the 95 km stretch coastline, 59% is at very high risk, 7% high, 4% moderate and 30% in the low vulnerable category, due to SLR. Results of the inundation analysis indicate that 42.19 km2 and 372.08 km2 of the land area will be submerged by flooding at 1 m and 10 m inundation levels. The most severely affected sectors are expected to be the residential and recreational areas, agricultural land, and the natural ecosystem. As this coast is planned for future coastal developmental activities, measures such as building regulation, urban growth planning, development of an integrated coastal zone management, strict enforcement of the Coastal Regulation Zone (CRZ) Act 1991, monitoring of impacts and further research in this regard are recommended for the study area. © 2009 Elsevier Ltd. All rights reserved.
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    A comprehensive assessment of increased iron ore production on the environment - A case study
    (2011) Thimmaiah, S.A.; Rao, Y.; Murthy, C.H.S.N.
    There has been a significant increase in iron ore production in the Bellary- Hospet-Sandur sector of Karnataka, India due to sudden increase in the demand of iron ore from other countries as well as by local steel plants set up in the region. An attempt has been made in this paper to study the effect of increase in the iron ore production on various environmental parameters like air, water, soil and noise. For this purpose a study area of 10 Km radius was taken and the various environmental parameters were monitored before and after increase in iron ore production in the region. Study shows that there is no significant change in the air quality in terms of SPM, RPM, SO2 and NOx in the region. In many locations, there is decrease in the concentrations of these parameters. This is mainly due to improvement of roads by asphalting, effective covering of iron ore trucks by tarpaulin, awareness among mine owners about the protection of environment by following various pollution control measures, dust suppression measures on the public road using water sprinklers and stringent monitoring of the environmental protective measures by various regulatory authorities. The concentration of SO2 and NOx was found to increase due to increase in traffic by movement of tippers in the public/village road. The deployment of heavy earth moving machinery at mine site also contributed for increase of SO2 and NOx. The surface water quality parameters were found to be within the acceptable limits in the study area. There is no possibility of disturbing/altering ground water table due to mining operations as the mining is being carried out on hill top which is above the general ground level. In agricultural soil, except that of potassium and electrical conductivity, variations in other parameters are insignificant as the agricultural lands are located 2 to 3 Kms away from the active mining area. Increase in noise level is found at most of the locations of the study area. Therefore, serious attempts should be made by mine owners as well as statutory bodies to reduce the sound level at various locations for increasing the quality of life in these locations in terms of sound level. © 2011 CAFET-INNOVA technical society. All right reserved.
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    Utilisation of mine waste in the construction industry - A Critical Review
    (CAFET INNOVA Technical Society 1-2-18/103, Mohini Mansion, Gagan Mahal Road, Domalguda, Hyderabad 500029, 2016) Shreekant, R.L.; Mangalpady, M.; Vardhan, H.
    The exploitation of mineral resources would promote the development of economy and society, but it will also generate massive waste/tailings that may pollute the environment significantly (in the form of spreading of waste in and around the mines, siltation of soil/slimes in nearby water bodies, air pollution etc.) Therefore, developing comprehensive utilization of waste fines/tailings in large scale is the need of the day in order to improve the surroundings and for sustainable development of resources. Manufacturing of non-fired bricks is one of the options for utilization of waste generated in mines along with reduction of CO2 emission. If the waste material is improperly dumped in mine site, the flow of material during rainy season may reduce the fertility of nearby agricultural land. Hence, waste utilization plays a vital role in natural resource conservation. Further, building blocks/bricks from mine waste is eco-friendly as it utilizes waste and reduces air, land and water pollution. It is energy efficient and also cost effective as reported by various investigators in the past. Hence, it is very much necessary to find alternative for making use of iron ore waste material (fines)/tailings as an aggregate in construction materials like bricks or paving blocks. This paper provides a critical review of the utilization of mine waste for brick making in the construction industry. © 2016 CAFET-INNOVA TECHNICAL SOCIETY. All rights reserved.