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2024
2019

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Rupa, T. R.

Development of allometric equations for grafted sapota (Manilkara zapota) through destructive tree sampling for non-destructive estimation of tree biomass

Abstract Views :109 |

Authors

A. N. Ganeshamurthy ¹, T. R. Rupa ¹, Karusala Alivelu ², S. Rajendran ¹, R. H. Laxman ¹, G. Ramanandan ¹, S. Mohapatra ¹, B. Aruna ¹

Affiliations
1 Indian Institute of Horticultural Research, Hessaraghatta Lake Post, Bengaluru 560 089, IN
2 Indian Institute of Oilseeds Research, Rajendranagar, Hyderabad 500 030, IN

Source

Current Science, Vol 127, No 10 (2024), Pagination: 1227-1232

Abstract

Sapota fruit tree biomass cannot be estimated using general forest tree allometric equations involving measurement of diameter at breast height (DBH) as grafted sapota tree branches below this height. Therefore grafted sapota trees of commercial orchards require an independent allometric equation for nondestructive estimation of tree biomass. Sapota allometric equations were hence developed with a destructive sampling of grafted sapota trees using parameters other than DBH and compared with other equations developed for grafted mangoes. The selected allometric parameters were significantly related to the age of the trees. The root-to-shoot ratio also differed from those reported for forest trees. The biomass expansion factor by and large attained stability beyond 16 years of tree age. The equations so developed generally fitted the data well, and in most cases, more than 50% of the observed variation in biomass was explained by primary branch girth ´ number of primary branches. There was a good agreement between the observed and the predicted biomass using both multiple linear regression and power model equations. Further, our purpose was to see if the grafted mango tree equation can predict sapota tree biomass. The results of this study confirmed that the mango equation equally predicts sapota tree biomass and hence the mango tree allometric equation can also be used for estimating sapota tree biomass efficiently.

Keywords

Allometric equation, biomass expansion factor, grafted trees, mango, sapota.

Full Text

Carbon Sequestration Potential of Mango Orchards in the Tropical Hot and Humid Climate of Konkan Region, India

Abstract Views :410 | PDF Views:170

Authors

A. N. Ganeshamurthy ¹, V. Ravindra ¹, T. R. Rupa ¹, R. M. Bhatt ¹

Affiliations
1 ICAR- Indian Institute of Horticultural Research, Bengaluru 560 089, IN

Source

Current Science, Vol 116, No 8 (2019), Pagination: 1417-1423

Abstract

Cultivated grafted mangoes are not the same as polyembryonic seedling-based wild mangoes in terms of biomass production and carbon sequestration. We estimated the carbon sequestration potential of mangoes in Konkan region, which is a prime mango belt of India producing the popular Alphonso mangoes. Allometric equation developed for grafted mangoes was used to estimate tree biomass. Konkan mango belt spread over 106,210 ha sequesters 9.913 mt of carbon. However, the carbon sequestration potential of these cultivated grafted mangoes is very low compared to polyembryonic seedling-grown mangoes in the wild. Since mangoes in the Konkan region have mostly occupied degraded lands of lateritic origin, such regions have been brought under productive mango orchards. As a consequence where forests have disappeared and mangoes have occupied the region, the carbon sequestered by them is a bonus apart from the production of mangoes. The administrators in these regions must use this information for claiming carbon credits for the benefit of farmers and the local population.

Keywords

Carbon Sequestration, Mango Orchards, Soil Carbon Stocks, Tree Biomass.

Full Text

References

Achard, F., Eva, H. D., Stibig, H. J., Mayaux, P., Gallego, J., Richards, T. and Malingreau, J. P., Determination of deforestation rates of the world’s humid tropical forests. Science, 2002, 297, 999–1002.

Fearnside, P. M. and Laurance, W. F., Tropical deforestation and greenhouse gas emissions. Ecol. Appl., 2004, 14(4), 982–986.

Gitay, H. et al., Ecosystems and their services. In Impacts, Adaptation and Vulnerability to Climate Change. Third Assessment Report of the Intergovernmental Panel on Climate Change, Cambridge University Press, 2001, pp. 236–342.

Houghton, R. A., Revised estimates of the annual net flux of carbon to the atmosphere from changes in land use and land management 1850–2000. Tellus, 2003, 55, 378–390.

Hudson, J. M., Gherini, S. A. and Goldstain, R. A., Modelling the global carbon cycle: N fertilization of the terrestrial of the biosphere and the ‘missing’ CO2 sink. Global Biogeocycles, 1994, 8, 307–333.

Arulselvi, G., Ramalingam, V. and Palanivel, S., Analysis of carbon sequestration pattern in tropical fruit trees. Int. J. Comput. Appl., 2011, 30(7), 24–29.

Dadhwal, V. K., Pandya, N. and Vora, A. B., Carbon cycle for Indian forest ecosystem: a preliminary estimate. In Global Change Studies: Scientific Results from ISRO-GBP (eds Subbaraya, B. H. et al.), ISRO, Bengaluru, 1998, pp. 411–430.

Ravindranath, N. H., Somshekhar, B. S. and Gadgil, M., Carbon flows in Indian forests. Climate Change, 1997, 35, 297–320.

Horticultural Statistics at a Glance, National Horticulture Board and Horticulture Statistics Division Department of Agriculture, Cooperation and Farmers’ Welfare, Ministry of Agriculture and Farmers’ Welfare, Government of India.

Ganeshamurthy, A. N., Eleven models of sustainable soil management in horticultural systems. IIHR, Technical Bulletin. 2015, p. 44.

Ganeshamurthy, A. N., Ravindra, V., Venugopalan, R., Malarvizhi Mathiazhagan and Bhatt, R. M., Biomass distribution and development of allometric equations for non-destructive estimation of carbon sequestration in grafted mango trees. J. Agric. Sci., 2016, 8, 201–211.

Seber, G. A. F. and Wild, C. J., Nonlinear Regression, John Wiley, NY, USA, 1989; doi:10.1002/0471725315.

Venugopalan, R. and Shamasundaran, K. S., Nonlinear regressions: a realistic modeling approach in horticultural crop research. J. Indian Soc. Agric. Stat., 2003, 56, 1–6.

Nelson, D. W. and Sommers, L. E., Total carbon, organic carbon and organic matter. In Methods of Soil Analysis: Chemical Methods. Part 3 (ed. Sparks, D. L.), Soil Science Society of America, Madison, WI, USA, 1996, pp. 61–1010.

Ganeshamurthy, A. N. and Reddy, Y. T. N., Fitness of mango for colonization in low fertility soils and dry lands: examination of leaf life-span, leaf nutrient resorption, and nutrient use efficiency in elite mango varieties. Agric. Res., 2015, 4(3), 254–260.

Borkar, V. S., Gokhale, N. B., Dhopavkarm, R. V., Khobragade, N. H., More, S. S. and Kasture, M. C., Distribution of nutrients in different soil types in Konkan region of Maharashtra. Int. J. Chem. Stud., 2018, 6(1), 275–279.

Shinde, S. B., Physico-chemical properties of lateritic soil from mango orchards in Ratnagiri and Sindhudurg districts. M Sc (Agric) thesis, Dr Balasaheb Sawant Konkan Krishi Vidyapeet, Dapoli, 2006.

Selvaraj, A., Jayachandran, S., Thirunavukkarasu, D. P., Jayaraman, A. and Karuppan, P., Carbon sequestration potential, physicochemical and microbiological properties of selected trees – Mangifera indica L., Manilkara zapota L., Cocos nucifera L. and Tectona grandis L. Biosci. Discov., 2016, 7(2), 131–139.

Eneji, I. S., Obinna, O. and Azua, E. T., Sequestration and carbon storage potential of tropical forest reserve and tree species located within Benue State of Nigeria. J. Geosci. Environ. Prot., 2014, 2, 157–166.

Usuga, J. C. L., Toro, J. A. R., Alzate, M. V. R. and Tapias, Á. J. L., Estimation of biomass and carbon stocks in plants, soil and forest floor in different tropical forests. For. Ecol. Manage., 2010, 260(10), 1906–1913.

Chandran, P., Ray, S. K., Durge, S. L., Raja, P., Nimkar, A. M., Bhattacharyya, T. and Pal, D. K., Scope of horticultural land-use system in enhancing carbon sequestration in ferruginous soils of the semi-arid tropics. Curr. Sci., 2009, 97(7), 1039–1046.

Ganeshamurthy, A. N., Annual Report, Indian Institute of Horticultural Research (IIHR), Bengaluru, 2012.

Ordo´n˜ez, J. A. B. et al., Carbon content in vegetation, litter, and soil under 10 different land-use and land-cover classes in the Central Highlands of Michoacan, Mexico. For. Ecol. Manage., 2008, 255, 2074–2084.

Gupta, M. K., Soil organic carbon pools under different land use in Haridwar district of Uttarakhand. Indian For., 2011, 137(1), 1–8.

Chhabra, A., Palria, S. and Dadhwal, A. K., Soil organic carbon pools in Indian forests. For. Ecol. Manage., 2003, 173, 187–199.

Wood database – Mango. 2018; http://www.wood-database.com/mango/

Carbon Sequestration Potential of Mango Orchards in India

Abstract Views :725 | PDF Views:189

Authors

A. N. Ganeshamurthy ¹, V. Ravindra ¹, T. R. Rupa ¹

Affiliations
1 Indian Institute of Horticultural Research, Bengaluru 560 089, IN

Source

Current Science, Vol 117, No 12 (2019), Pagination: 2006-2013

Abstract

Estimates of carbon stocks and stock changes in fruit orchards are necessary under the United Nations Framework Convention on Climate Change and the Kyoto Protocol. In this direction we estimated the carbon stocks in cultivated mango orchards in India using an exclusive allometric equation developed for estimation of tree biomass of grafted mangoes. Extensive tree, litter, weed and soil samples were collected for estimation of carbon pools by grouping mango areas based on similarity of tree canopy, climate, and dominance of mango varieties grown in these regions. The carbon held in these pools was then compiled and national-level carbon storage in cultivated mango orchards was computed by multiplying with the area occupied by mango in these regions. The country as a whole has sequestered 285.005 mt of carbon in its mango orchards. This is, however, very low compared to polyembrionic mango trees grown from seeds in the wild.

Keywords

Allometric Equation, Carbon Sequestration, Mango Orchards, Tree Biomass.

Full Text

References

Lal, M. and Singh, R., Carbon sequestration potential of Indian forests. Centre for Atmospheric Sciences, Indian Institute of Technology Environmental Monitoring and Assessment, 2000, 60, 315–327, 2000. Kluwer Academic Publishers, Printed in the Netherlands.

Hui, D., Deng, Q., Tian, H and Luo, Y., Climate change and carbon sequestration in forest ecosystems. In Handbook of Climate Change Mitigation and Adaptation (eds Chen, W.-Y. et al.), Springer Science + Business Media, New York, USA, 2015.

Dadhwal, V. K., Pandya, N. and Vora, A. B., Carbon cycle for Indian forest ecosystem: a preliminary estimated. In Global Change Studies: Scientific Results from ISRO-GBP (Subbaraya, B. H. et al.), Indian Space Research Organisation, Bengaluru, 1998, pp. 411–430.

Ravindranath, N. H., Somshekhar, B. S. and Gadgil, M., Carbon flows in Indian forests. Climate Change, 1997, 35, 297–320.

Kerckhoffs, L. H. J. and Reid, J. B., Carbon sequestration in the standing biomass of orchard crops in New Zealand. Hastings, New Zealand: New Zealand Institute for Crop and Food Research Ltd, Report, 2007, pp. 1–4.

Procter, J. T. A., Watson, R. L. and Landsberg, J. J., The carbon budget of a young apple tree. J. Am. Soc. Hortic. Sci., 1976, 101, 579–582.

Blanke, M. M. and Kappel, F., Contribution of soil respiration to the carbon balance of an apple orchard. Acta Hortic., 1997, 451, 337–341.

Ebert, G. and Lenz, F., Annual course of ischolar_main respiration of appletrees and its contribution to the CO2-balance. Gartenbauwissenschaft, 1991, 56, 130–133.

Sekikawa, S., Kibe, T. and Koizumi, H., Soil carbon budget in peach orchard ecosystem in Japan. Environ. Sci., 2003, 16, 97– 104.

Sofo, A. et al., Net CO2 storage in Mediterranean olive and peach orchards. Sci. Hortic., 2005, 107, 17–24.

Kimmins, J. P., Forest Ecology: A Foundation for Sustainable Management, Pearson Prentice Hall, New Jersey, 1997, 2nd edn, pp. 1–596.

Ganeshamurthy, A. N., Ravindra, V., Rupa, T. R. and Bhat, P. M., Carbon sequestration potential of mango orchards in tropical hot and humid climate of Konkan region of India. Curr. Sci., 2019, 116(8), 1417–1423.

NHB, Horticultural Statistics at a Glance, National Horticultural Board and Horticulture Statistics Division, Department of Agriculture, Cooperation and Farmers Welfare, Ministry of Agriculture and Farmers Welfare Government of India, 2017.

Selvaraj, A., Sivasankari, J., Dhivya, P., Thirunavukkarasu, A., Jayaraman and Perumal, K., Carbon sequestration potential, physicochemical and microbiological properties of selected trees Mangifera indica L., Manilkara zapota L., Cocos nucifera L. and Tectona grandis L., Biosci. Discovery, 2016, 7(2), 131–139.

Eneji, I. S., Obinna, O. and Azua, E. T., Sequestration and carbon storage potential of tropical forest reserve and tree species located within Benue State of Nigeria. J. Geosci. Environ. Prot., 2014, 2, 157–166.

Chandran, P., Ray, S. K., Durge, S. L., Raja, P., Nimkar, A. M., Bhattacharyya, T. and Pal, D. K., Scope of horticultural land-use system in enhancing carbon sequestration in ferruginous soils of the semi-arid tropics. Curr. Sci., 2009, 7, 1039–1046.

Ordóñez, J. A. B. et al., Carbon content in vegetation, litter, and soil under 10 different land-use and land-cover classes in the Central Highlands of Michoacan, Mexico. For. Ecol. Manage., 2008, 255, 2074–2084.

Ganeshamurthy, A. N., Ravindra, V., Panneerselvam, P, Sathyarahini, K. and Bhatt, R. M., Conservation horticulture in mango orchards: comparative effects of conventional and conservation management practices on soil properties of an Alfisol under seasonally dry tropical Savanna climate. J. Agric. Sci., 2016, 8, 1–16.

Ganeshamurthy, A. N., Ravindra, V., Venugopalan, R., Mathiazhagan, Malarvizhi and Bhatt, R. M., Biomass distribution and development of allometric equations for non-destructive estimation of carbon sequestration in grafted mango trees. J. Agric. Sci., 2016, 8, 201–211.

Seber, G. A. F. and Wild, C. J., Nonlinear Regression, 1989, John Wiley, New York, USA; http://dx.doi.org/10.1002/0471725315

Venugopalan, R. and Shamasundaran, K. S., Nonlinear regressions: a realistic modeling approach in horticultural crop research. J. Indian Soc. Agric. Stat., 2003, 56, 1–6.

Venkateswarlu, J., Effect of resource management system for dry lands of India. Adv. Soil Sci., 1987, 7, 165–121.

Ganeshamurthy, A. N., Dinesh, R., Ravisankar, N., Nair, A. and Ahlawat, S. P. S., Land resources of Andaman and Nicobar Islands, Central Agricultural Research Institute, Port Blair, 2002, p. 134.

FSI, Carbon stocks in India’s forests. In India State of Forest Report 2017 Chapter 8.0, Forest Survey of India, 2017, pp. 120–136.

Usuga, J. C. L., Toro, J. A. R., Alzate, M. V. R. and Tapias, A. J. L., Estimation of biomass and carbon stocks in plants, soil and forest floor in different tropical forests. For. Ecol. Manage., 2010, 260(10), 1906–1913.

Ganeshamurthy, A. N., Annual Report, Indian Institute of Horticultural Research, Bengaluru, India, 2012.

Gupta, M. K., Soil organic carbon pools under different land use in Haridwar district of Uttarakhand. Indian For., 2011, 137, 1–8.

Chhabra, A., Palria, S. and Dadhwal, A. K., Soil organic carbon pools in Indian forests. For. Ecol. Manage., 2003, 173, 187–199.

Wood database, 2018; https://www.wood-database.com/mango/

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Author Details

Rupa, T. R.

Development of allometric equations for grafted sapota (Manilkara zapota) through destructive tree sampling for non-destructive estimation of tree biomass

Authors

Source

Abstract

Keywords

Full Text

Carbon Sequestration Potential of Mango Orchards in the Tropical Hot and Humid Climate of Konkan Region, India

Authors

Source

Abstract

Keywords

Full Text

References

Carbon Sequestration Potential of Mango Orchards in India

Authors

Source

Abstract

Keywords

Full Text

References