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ISSN (Print): 2328-3912 ISSN (Online): 2328-3920 Website: https://www.sciepub.com/journal/aees Editor-in-chief: Alejandro González Medina
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Applied Ecology and Environmental Sciences. 2021, 9(4), 450-457
DOI: 10.12691/aees-9-4-4
Open AccessArticle

Carbon Sequestration Potential of Hills (Studied) Around Pune City, Pune

Shinde Vijayalaxmi R1, and Mahajan D.M.2

1Department of Environmental Science, Abeda Inamdar Senior College of Arts, Science & Commerce, Camp, Pune-411001

2Department of Botany, Baburaoji Gholap College, Sangvi, Pune-411027

Pub. Date: April 09, 2021
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Cite this paper:
Shinde Vijayalaxmi R and Mahajan D.M.. Carbon Sequestration Potential of Hills (Studied) Around Pune City, Pune. Applied Ecology and Environmental Sciences. 2021; 9(4):450-457. doi: 10.12691/aees-9-4-4

Abstract

Pune is situated in close proximity (50kms) on the biodiversity of Sahyadri Hills also known as the Western Ghats. As per the land use distribution of Pune city, the total area covered under hills and hill slopes is 1245 ha i.e., 5.10% of the total land. The Hills environment in the city is subjected to intense pressure due to all types of developmental projects and encroachment. The mounting concrete structures due to these developments have resulted in the loss of green covers on the hills covering parts of Western Ghats which are a resultant of the increasing climate change. We have sampled 10 hills namely ARAI. Baner, Bhopdev Ghat, Chaturshringi, Fergusson College, Kothrud hill, Sutarwadi. University, Vetal- Parvati for biomass, a total of 124 quadrates of size 15 m X 15 m were plotted. Each and every tree in the quadrate is sampled along with GPS and random soil samples were collected for soil carbon analysis. Soil samples were taken from soil profile up to 30 cm depth. Walkley-Black Wet Oxidation method was applied for measuring soil organic carbon. Total amount of above and belowground carbon sequestered was estimated and the values are extrapolated which comes to the value of1336886568 tonnes; litter and deadwood 17509.44 tonnes, and soil organic carbon 792001603.46 tonnes; and the sum of all were 212,89,05,681 tonnes. The rates of carbon in active markets are US$ 30 (Thirty dollars) per tonne. Putting a conservative value of US$ 30 per tonne of CO2 locked in these sampled gardens, this carbon sink of about 212,89,05,681 tonnes of CO2 is worth of US $ 63,867,170,430 or Indian Rs. 4,701,901,087,056.6 /- It will help in mitigating the total carbon emissions and reducing the carbon footprints of the Pune city and thereby decreasing atmospheric carbon dioxide levels.

Keywords:
carbon sinks carbon pool carbon footprint GHG Soil Organic Carbon above ground and below ground biomass GPS sustainable development

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References:

[1]  Anonymous, (1998), “Method for Calculating Carbon Sequestration by Trees in Urban and Suburban Settings”, Voluntary Reporting of Greenhouse Gases Program, U.S. Department of Energy, Energy Information Administration, EI-81, 1000 Independence Avenue, S.W., Washington, DC 20585. pp 1-15.
 
[2]  Baes C.F., Goeller H.E., Olson J.S., and Rotty R.M. (1977). Carbon dioxide and climate: The uncontrolled experiment. American Scientist, Vol. 65; 310-320.
 
[3]  Choudhari Nisha R., D.M. Mahajan, V.R. Gunale and M.G. Chaskar (2014). Assessment of carbon sequestration potential of an urban managed garden in the Pimpri-Chinchwad City. Environment Observer, Vol. 20: pp 63-67
 
[4]  Grace Peter R., Wilfred M. Post, and Kevin Hennessy (2006). The potential impact of climate change on Australia’s soil organic carbon resources. Carbon balance Management, 1-14.
 
[5]  Hangarge L.M., D.K. Kulkarni, V.B. Gaikwad, D.M. Mahajan and Nisha Chaudhari (2012). “Carbon Sequestration potential of tree species in Somjaichi Rai (Sacred grove) at Nandghur village, in Bhor region of Pune District, Maharashtra State, India.” Annals of Biological Research, Vol. 3(7): 3426-3429.
 
[6]  Hangarge, LM; Kulkarni, DK; Gaikwad, VB; Mahajan, DM; and Gunale, VR (2015). Soil Organic Carbon (SOC) in selected Sacred Groves from Bhor region of Western Ghats, Maharashtra. Asian Journal of Environmental Science, Vol. 10 (2): 166-171.
 
[7]  Houghton JT, Jenluns GJ, Ephraums JJ (eds), (1990), ‘Climate change - the IPCC Scientific Assessment’. IPCC, Cambridge University Press. Cambridge, Great Britain, New York, NY, USA and Melbourne, Australia 410 pp.
 
[8]  IPCC, (2003), ‘Good practice guidance for land use, land use change and forestry’ Institute for Global Environmental Strategies, Hayama, Japan.
 
[9]  IPCC, (2006), ‘Guidelines for national greenhouse gas inventories’. Vol. 4, Agriculture, forestry and other land use (AFLOLU). Institute for Global Environmental Strategies, Hayama, Japan.
 
[10]  Kalra, Y.P.; Maynard, D.G. (1991). Methods manual for forest soil and plant analysis. Forestry Canada, Northwest Region, Northern Forestry Centre, Edmonton, Alberta. Information Report NOR-X-319E. 116 p.
 
[11]  Matthews E, Payne R, Rohweder M and Murray S, (2000), ‘Forest ecosystem: Carbon storage sequestration - Carbon Sequestration in Soil’, Global Climate Change Digest, 12 (2) 19-99.
 
[12]  Miller, Robert W. (1997) ‘Urban Forestry: Planning and Managing Urban Greenspaces’, 2nd edition. Prentice-Hall, Inc., Upper Saddle River, New Jersey.
 
[13]  Nowak DJ and DE Crane (2001) ‘Carbon storage and sequestration by urban trees in the USA’ Environ. Pollution 116 (3): 381-389.
 
[14]  Ravindranath NH and Ostwald Madelene 2008, ‘Carbon Inventory Methods - Handbook for Greenhouse Gas Inventory, Carbon Mitigation and Roundwood Production Projects’ Springer-Verlang, p-304.
 
[15]  Schlesinger, W.H. (1999) Carbon Sequestration in Soils. Science, Vol. 284; 2095-2097.
 
[16]  Shinde V.R. and Mahajan D.M. (2015) Carbon pool analysis of urban parks (Chh. Sambhaji Garden and Chittaranjan Vatika, Pune). Journal of Basic Sciences, Vol. 1(1): pp. 20-27.
 
[17]  Shinde V.R. and Mahajan D.M. (2016). Comparative account of carbon pool analysis of urban park (Empress garden) and an educational institute, Pune. In: Proceeding of International Conference on Environmental System and Sustainable Development, organized by C.T. Bora College, Shirur, Dist. Pune (India) during January 15-16, 2016.
 
[18]  http://www.robasworld.com/arai-pune-birds.
 
[19]  http://soilquality.org.au/factsheets/organic-carbon.
 
[20]  https://www.agric.wa.gov.au/soil-carbon/measuring-and-reporting-soil-organic-carbon.
 
[21]  https://www.agric.wa.gov.au/measuring-and-assessing-soils/what-soil-organic-carbon.
 
[22]  https://www.researchgate.net/publication/278033292_Methods_for_calculating_soil_organic_carbon_stocks_and_fractions_in_soils_of_North-East_Hill_Regions_of_India.
 
[23]  https://www.nrcs.usda.gov/Internet/FSE_DOCUMENTS/nrcs142p2_053256.pdf.
 
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