Optimal allometric biomass equations for Hornbeam (Carpinus betulus L.) boles within the Hyrcanian forests

Document Type : Research article

Author

Ph.D. Forestry, Department of Forest Ecology and Silviculture, Science and Research Branch, Islamic Azad University, Tehran, I.R. Iran

Abstract

According to the amount of carbon emitted to the atmosphere, obtaining accurate estimations of biomass is an effective step to deal with the global warming and climate change on various spatial scales. Therefore, this study pursued the aim of investigating allometric models to increase the accuracy of the dry biomass calculation for hornbeam (Carpinus betulus L.), which is one of the most abundant tree species across the Hyrcanian forests of Iran. The diameter at breast height, bole height and age were used as explanatory variables in non-linear models (power and exponential functions) and as combined variables in linear, log-transformed models. The results showed that the power and exponential functions of diameter returned the best fit and highest accuracy (R2adj= 0.72-0.75; SEE = 0.53-0.51). For the entire combined variables, the squares diameter and height (dbh2 × h) was the best combination, showing the highest correlation with the observations. Subsequently, the log-transformed model containing the mentioned combined variables returned the highest estimation accuracy (R2adj= 0.77; SEE = 0.48) and best fit-goodness. Regarding the acquired variance inflation factor (VIF >10), the multiple linear models were not significant. Furthermore, the least correction factor was calculated (CF = 1.11) to correct for the model bias. Therefore, the optimal model of Y = Exp [-3.47 + 1.007 ln(dbh2 ×h) was introduced to estimate bole biomass of hornbeam.
 

Keywords


- Aboal, R.J., Arevalo, R.J. and Fernandez, A. 2005. Allometric relationships of different tree species and stand above ground biomass in the Gomera laurel forest (Canary Islands). Flora, 200: 264-274.
- Alvarez, E., Duque, A., Saldarriaga, J., Cabrera, K., Salas, G.D.L., Valle, L.D., Lema, A., Moreno, F., Orrego, S. and Rodriguez, L. 2012. Tree above-ground biomass allometries for carbon stocks estimation in the natural forests of Colombia. Forest Ecology and Management, 267: 297-308.
- Anonymous, 2008. Forestry Project of the Third District of Glandrood-Noor (Second Renewal View). Published by Administration of Natural Resources at Nowshahr (In Persian).
- Basuki, T.M., van Laake, P.E., Skidmore, A.K. and Hussin, Y.A. 2009. Allometric equations for estimating the above-ground biomass in tropical lowland Dipterocarp forests. Forest Ecology and Management, 257: 1684-1694.
- Bihamta, M.R. and Zare Chahouki, M.A. 2011. Principle of Statistic for the Natural Resources Science. University of Tehran Press, 300p (In Persian).
- Brown S., Gillespie A. and Lugo A.E. 1989. Biomass estimation methods for tropical forests with applications to forest inventory data. Forest Science, 35:881-902
- Brown, S. and Lugo, A.E. 1982. The storage and production of organic matter in tropical forests and their role in global carbon cycle. Biotropica, 14: 161-18.
- Chave, J., Andalo, C., Brown, S., Cairns, M.A., Chambers, J.Q., Eamus, D., Folster, H., Fromard, F., Higuchi, N., Kira, T., Lescure, J.P., Nelson, B.W., Ogawa, H., Puig, H., Riera, B. and Yamakura, T. 2005. Tree allometry and improved estimation of carbon stocks and balance in tropical forests. Oecologia, 145: 87-99.
- Djomo, A.N., Adamou, I., Joachim, S. and Gode, G. 2010. Allometric equations for biomass estimations in Cameroon and pan moist tropical equations including biomass data from Africa. Forest Ecology and Management, 260: 1873-1885.
- Fehrmann, L. and Kleinn, C. 2006. General considerations about the use of allometric equations for biomass estimation on the example of Norway spruce in central Europe. Forest Ecology and Management, 236: 412-421.
-Han, B., Wang, X.K. and Ouyang, Z.Y. 2005. Saturation levels and carbon sequestration potentials of soil carbon pools in farmland ecosystems of China. Rural Eco-Environment, 21(4): 6-11.
- Henry, M., Besnard, A., Asante, W.A., Eshun, J., Adu-Bredu, S., Valentini, R., Bernoux, M. and  Saint-André, L. 2010. Wood density, phytomass variations within and among trees, and allometric equations in a tropical rainforest of Africa. Forest Ecology and Management, 260: 1375-1388.
- Houghton, R.A., Hall, F. and Goetz, S.J. 2009. Importance of biomass in the global carbon cycle. Journal of Geophysical Research, 114: 13p.
- Joosten, R., Schumacher, J., Wirth, C. and Schulte, A. 2004. Evaluating tree carbon predictions for beech (Fagus sylvatica L.) in western Germany. Forest Ecology and Management, 189: 87- 96.
- Ketterings, Q.M., Coe, R., Noordwijk, M.V., Ambagau, Y. and Palm, C.A. 2001. Reducing uncertainty in the use of allometric biomass equations for predicting above-ground tree biomass in mixed secondary forests. Forest Ecology and Management, 146: 199-209.
- Li, X.Y. and Tang, H.P. 2006. Carbon sequestration: manners suitable for carbon trade in China and function of terrestrial vegetation. Journal of Plant Ecology, 32: 200-209.
- Marvie Mohadjer, M.R. 2005. Silviculture. University of Tehran Press, Tehran, 387p (In Persian).
- Mirabdollahi, M., Bonyad, A.E., Torkaman, J. and Bakhshandeh, B. 2011. Study on tree form of Oriental Beech (Fagus orientalis Lipsky) in different growth stages (Case study: Lomir forest). Iranian Journal of Forest, 3: 177-187 (In Persian).
- Navar, J. 2009. Allometric equations for tree species and carbon stocks for forests of northwestern Mexico. Forest Ecology and Management, 257: 427-434.
- Peichl, M. and Arain, M.A. 2006. Above- and belowground ecosystem biomass and carbon pools in an age-sequence of temperate pine plantation forests. Agricultural and Forest Meteorology, 140: 51-63.
- Ribeiro, S., Fehrmann, L., Pedro Boechat Soares, C., Antônio Gonçalves Jacovine, L., Kleinn, C. and de Oliveira Gaspar, R. 2011. Above and belowground biomass in a Brazilian Cerrado. Forest Ecology and Management, 262: 491-499.
- Segura, M. and Kanninen, M. 2005. Allometric models for tree volume and total aboveground biomass in a tropical humid forest in Costa Rica. Biotropica, 37: 2-8.
- Singh, V., Tewari, A., Kushwaha, S.P.S. and Dadhwal, V.K. 2011. Formulating allometric equations for estimating biomass and carbon stock in small diameter trees. Forest Ecology and Management, 261:1945-1949.
- Sohrabi, H. and Shirvani, A. 2012. Allometric equations for estimating standing biomass of Atlantic Pistache (Pistacia atlantica var. mutica) in Khojir National Park. Iranian Journal of Forest, 4(1): 55-64 (In Persian).
- Turski, M., Beker, C., Kazmierczak, K. and Najgrakowski, T. 2008. Allometric equations for estimating the mass and volume of fresh assimilation apparatus of standing scots pine (Pinus sylvestris L.) trees. Forest Ecology and Management, 255: 2678-2687.
 - Vallet, P., Dhôte, J.F., Moguédec, G.L., Ravart, M. and Pignard, G. 2006. Development of total aboveground volume equations for seven important forest tree species in France. Forest Ecology and Management, 229: 98-110.
- Vann, D.R., Palmiotto, P.A. and Richard, S. 1998. Allometric equations for two South American conifers: Test of a non-destructive method. Forest Ecology and Management, 106: 55-71
- Zhu, B., Wang, X., Fang, W., Piao, S., Shen, H., Zhao, S. and Peng, C. 2010. Altitudinal changes in carbon storage of temperate forests on Mt Changbai, Northeast China. Carbon Cycle Process in East Asia, 123:439-452.
- Zianis, D. and Mencuccini, M. 2004. Onsimplifying allometric analyses of forest biomass. Forest Ecology and Management, 187: 311-332.