Open Access
Subscription Access
Relationship of Physiological Plant Functional Traits With Soil Carbon Stock in The Temperate Forest of Garhwal Himalaya
The composition of species can play an essential role in reducing the atmospheric carbon dioxide. Forest trees are an important part of the functioning of the terrestrial ecosystem, predominantly in the cycling of carbon. However, tree physiology is much less studied than crop physiology for several reasons: a large number of species, difficulty in measuring photosynthesis of tall trees or forest species. This study aims to establish the relationship between physiological plant functional traits (photosynthesis rate, transpiration rate, stomatal conductance, leaf chlorophyll and carotenoid content) with soil carbon stock in Pinus roxburghii forest of Garhwal Himalaya. The present findings revealed that photosynthesis rate, chlorophyll a, chlorophyll b and carotenoid content positively correlated to the soil carbon stock. The different regression models also showed that photosynthesis rate with water-use efficiency, stomatal conductance and carotenoid content is a good predictor of soil carbon stock in Pinus roxburghii forest. Physiological plant functional characteristics are thus crucial for regulating the carbon cycle and ecosystem functioning in Garhwal Himalaya.
Keywords
Carbon Assimilation, Ecosystem Services, Soil Carbon, Water-Use Efficiency.
User
Font Size
Information
- Kumar, A. et al., Carbon mineralization and inorganic nitrogen pools under Terminalia chebula Retz. – based agroforestry system in Himalayan Foothills, India. Forest Sci., 2020. 66(5), 634–643.
- Kumar, A. et al., Soil organic carbon pools under Terminalia chebula Retz. based agroforestry system in Himalayan foothills, India. Curr. Sci., 2020, 118(7), 1098–1103.
- Kumar, M., Rawat, S. P. S., Singh, H., Ravindranath, N. H. and Kalra, N., Dynamic forest vegetation models for predicting impacts of climate change on forests: an Indian perspective. Indian J. For., 2018, 41(1), 1–12.
- Sharma, R., Chauhan, S. K. and Tripathi, A. M., Carbon sequestration potential in agroforestry system in India: an analysis for carbon project. Agrofor. Syst., 2016, 90(4), 631–644.
- deDeyn, G. D. B., Cornelissen, J. H. C. and Bardgett, R. D., Plant functional traits and soil carbon sequestration in contrasting biomes. Ecol. Lett., 2008, 11, 516–531.
- Diaz, S., Lavorel, S., de Bello, F., Quetier, F., Grigulis, K. and Robson, T. M., Incorporating plant functional diversity effects in ecosystem service assessments. Proc. Natl. Acad. Sci., 2007, 104(52), 20684–20689.
- Rawat, M., Arunachalam, K., Arunachalam, A., Alatalo, J. and Pandey, R., Associations of plant functional diversity with carbon accumulation in a temperate forest ecosystem in the Indian Himalayas. Ecol. Indic., 2019, 1(98), 861–868.
- Hassiotou, F., Renton, M., Ludwig, M., Evans, J. R. and Veneklaas, E. J., Photosynthesis at an extreme end of the leaf trait spectrum: how does it relate to high leaf dry mass per area and associated structural parameters? J. Exp. Bot., 2010, 61(11), 3015– 3028.
- Kasel, S. and Bennett, L. T., Land-use history, forest conversion, and soil organic carbon in pine plantations and native forests of south eastern Australia. Geoderma, 2007, 137, 401–413.
- Kim, D. G., Kirschbaum, M. U. and Beedy, T. L., Carbon sequestration and net emissions of CH4 and N2O under agroforestry: Synthesizing available data and suggestions for future studies. Agric. Ecosyst. Environ., 2016, 226, 65–78.
- Kumar, A., Kumar, P., Singh, H. and Kumar, N., Adaptation and mitigation potential of roadside trees with bio-extraction of heavy metals under vehicular emissions and their impact on physiological traits during seasonal regimes. Urban For. Urban Green., 2020, 126900.
- Kirschbaum, M. U. F. and Tompkins, D., Photosynthetic responses to phosphorus nutrition in Eucalyptus grandis seedlings. Austr. J. Plant Physiol., 1990, 17, 527–535.
- Singh, H., Yadav, M., Kumar, N., Kumar, A. and Kumar, M., Assessing adaptation and mitigation potential of roadside trees under the influence of vehicular emissions: A case study of Grevillea robusta and Mangifera indica planted in an urban city of India. PLoS ONE, 2020, 15(1), 557–562.
- Ballantyne, A. P., Alden, C. B., Miller, J. B., Tans, P. P. and White, J. W. C., Increase in observed net carbon dioxide uptake by land and oceans during the past 50 years. Nature, 2012, 488, 70–72.
- King, D. A., Davies, S. J., Nur Supardi, N. M. and Tan, S., Tree growth is related to light interception and woody density in two mixed dipterocarp forests of Malaysia. Funct. Ecol., 2005, 19, 445–453.
- Kitajima, K., Mulkey, S. S. and Wright, S. J., Decline of photosynthetic capacity with leaf age in relation to leaf longevities for five tropical canopy tree species. Am. J. Bot., 1997, 84, 702–708.
- Casals, P., Romero, J., Rusch, G. and Ibrahim, M., Soil organic C and nutrient contents under trees with different functional characteristics in seasonally dry tropical silvopastures. Plant Soil, 2014, 374, 643–659.
- Kumar, M., Rawat, S. P. S., Singh, H., Ravindranath, N. H. and Kalra, N., Dynamic forest vegetation models for predicting impacts of climate change on forests: An Indian perspective. Indian J. For., 2018, 41(1), 1–12.
- Saidy, A. R., Smernik, R. J., Baldock, J. A., Kaiser, K. and Sanderman, J., Microbial degradation of organic carbon sorbed to phyllosilicate clays with and without hydrous iron oxide coating. Eur. J. Soil Sci., 2015, 66, 83–94.
- Von Lutzow, M., Kögel-Knabner, I., Ekschmitt, K., Matzner, E., Guggenberger, G., Marschner, B. and Flessa, H., Stabilization of organic matter in temperate soils: mechanisms and their relevance under different soil conditions – a review. Eur. J. Soil Sci., 2006, 57, 426–445.
- Lloyd, J. and Farquhar, G. D., Effects of rising temperatures and CO2 on the physiology of tropical forest trees. Philos. Trans. R. Soc. B: Biol. Sci., 2008, 27, 363(1498).
- Andrade, H., Brook, R. and Ibrahim, M., Growth, production and carbon sequestration of silvopastoral systems with native timber species in the dry lowlands of Costa Rica. Plant Soil, 2008, 308, 11–22.
- Rennenberg, H., Loreto, F., Polle, A., Brilli, F., Fares, S., Beniwal, R. S. and Gessler, A. J., Physiological responses of forest trees to heat and drought. Plant Biol., 2006, 8(5), 556–571.
- Jia, L., Liu, Z., Chen, W., Ye, Y., Yu, S. and He, X., Hormesis effects induced by cadmium on growth and photosynthetic performance in a hyperaccumulator, Lonicera japonica Thunb. J. Plant Growth Regulat., 2015, 34(1), 13–21.
- Kallarackal, J. and Roby, T. J., Responses of trees to elevated carbon dioxide and climate change. Biodivers. Conserv., 2012, 21(5), 1327–1342.
- Singh, H., Yadav, M., Kumar, N., Kumar, A. and Kumar, M., Assessing adaptation and mitigation potential of roadside trees under the influence of vehicular emissions: a case study of Grevillea robusta and Mangifera indica planted in an urban city of India. PLoS ONE, 2020, 15(1), 557–562.
- Ballantyne, A. P., Alden, C. B., Miller, J. B., Tans, P. P. and White, J. W. C., Increase in observed net carbon dioxide uptake by land and oceans during the past 50 years. Nature, 2012, 488, 70– 72.
- Sharma, R., Singh, H., Kaushik, M., Nautiyal, R. and Singh, O., Adaptive physiological response, carbon partitioning, and biomass production of Withania somnifera (L.) Dunal grown under elevated CO2 regimes. 3 Biotech, 2018, 8(6), 1–10.
- Vesterdal, L., Clarke, N., Sigurdsson, B. D. and Gundersen, P., Do tree species influence soil carbon stocks in temperate and boreal forests? For Ecol. Manage., 2013, 309, 4–18.
- DaCosta, M. V. J., Morphological, physiological, biochemical and molecular response of rice seedlings to metallo-nanoparticles, Doctoral dissertation, Goa University, 2016.
Abstract Views: 308
PDF Views: 129