Refine your search
Collections
Co-Authors
Year
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All
Zheng, XiaoXian
- Natural Regeneration of an Artificial Platycladus orientalis Stand in Beijing
Abstract Views :173 |
PDF Views:0
Authors
Affiliations
1 Key Laboratory for Silviculture and Conservation of Ministry of Education, Beijing Forestry University, Beijing 100083, CN
2 Qingzhen 551400, Guizhou Province, CN
1 Key Laboratory for Silviculture and Conservation of Ministry of Education, Beijing Forestry University, Beijing 100083, CN
2 Qingzhen 551400, Guizhou Province, CN
Source
Nature Environment and Pollution Technology, Vol 16, No 1 (2017), Pagination: 287-293Abstract
The study of the natural regeneration of an artificial Platycladus orientalis stand is important in order to reflect the potential trend of the stand. This field investigation was carried out in the Shisanling forest farm in Beijing. We analysed the factors that influenced the natural regeneration using the gray correlation method. The results showed that the regeneration status was bad in height classes of 0- 30 cm and 30-50 cm, while it was moderate in the height class of >50 cm; the overall regeneration status was moderate. Eight factors that affected the natural regeneration, in a descending order, are: altitude, aspect, soil depth, slope position, stand density, gradient, shrub-herb cover and litter thickness. It was difficult to satisfy the demand of stand self-replacement because the natural regeneration of artificial P. orientalis stands was poor.Keywords
Platycladus orientalis, Natural Regeneration, Gray Correlation Analysis, Correlation Coefficient, Correlation Degree.Full Text
References
- Appendino, G., Gariboldi, P., Pisetta, A., Bombardelli, E. and Gabetta, B. 1992. Taxanes from Taxus baccata. Phytochemistry, 31: 4253-4257.
- Bao, J.C., Wang, D.X., Chen, F. and Fang, K. 2011. Natural regeneration of Quercus aliena var. acuteserrata forests in Huoditang based on the grey relational analysis method. J. Northwest For.
- University, 26(5): 121-126.
- Ball, M.C., Hodges, V.S. and Laughlin, G.P. 1991. Cold-induced photoinhibition limits regeneration of snow gum at tree-line. Funct. Ecol., 5: 663-668.
- Battaglia, M.A., Mou, P., Palik, B. and Mitchell, R.J. 2002. The effect of spatially variable overstory on the understory light environment of an open-canopied longleaf pine forest. Can. J. For. Res., 32: 1984-1991.
- Caccia, F.D. and Balleré, C.L. 1998. Effects of tree cover, understory vegetation and litter on regeneration of Douglas-fir (Pseudotsuga menziesii) in southwestern Argentina. Can. J. Forest Res., 28: 683-692.
- D’Alessandro,C.M., Saracino, A. and Borghetti. M. 2006. Thinning affects water use efficiency of hardwood saplings naturally recruited in a Pinus radiata D. Don plantation. Forest Ecol. Manag., 222: 116-122.
- Devaney, J.L., Jansen, M.A.K. and Whelan, P.M. 2014. Spatial patterns of natural regeneration in stands of English yew (Taxus baccata L.); Negative neighbourhood effects. Forest Ecol. Manag., 321: 52-60.
- Dodet, M., Collet, C., Frochet, H. and Wehrlen, L. 2011. Tree regeneration and plant species diversity response to vegetation control following a major windthrow in mixed broadleaved stands. Eur. J. Forest. Res., 130: 41-53.
- Farris, E. and Filigheddu, R. 2008. Effects of browsing in relation to vegetation cover on common yew (Taxus baccata L.) recruitment in Mediterranean environments. Plant Ecol., 199: 309-318.
- Garcia, D., Zamora, R., Hódar, J.A., Gómez, J.M. and Castro, J. 2000. Yew (Taxus baccata L.) regeneration is facilitated by fleshyfruited shrubs in Mediterranean environments. Biol. Conserv., 95: 31-38.
- Grassi, G., Minotta, G., Tonon, G. and Bagnaresi, U. 2004. Dynamics of Norway spruce and silver fir natural regeneration in a mixed stand under uneven-aged management. Can. J. Forest. Res., 34: 141-149.
- Iszkulo, G. and Boratynski, A. 2006. Analysis of the relationship between photosynthetic photon flux density and natural Taxus baccata seedlings occurrence. Acta Oecol., 29: 78-84.
- Kunstler, G., Curt, T., Bouchaud, M. and Lepart, J. 2005. Growth, mortality, and morphological response of European beech and downy oak along a light gradient in sub-Mediterranean forest.
- Can. J. Forest Res., 35: 1657-1668.
- Lei, H.P., Wang, Y.G., Liang, F.Y., Su, W.W., Feng, Y.F., Guo, X.L. and Wang, N. 2010. Composition and variability of essential oils of Platycladus orientalis growing in China. Biochem. Syst. Ecol., 38: 1000-1006.
- Ligot, G., Balandier, P., Fayolle, A., Lejeune, P. and Claessens, H. 2013. Height competition between Quercus petraea and Fagus sylvatica natural regeneration in mixed and uneven-aged stands.
- Forest. Ecol. Manag., 304: 391-398.
- Liu, X.D. and Zhang, Y.L. 2009. Natural regeneration of Korean pine mixed forests in Dong Zhelenghe forest station, Xiaoxing’ an Mountains. J. Northeast Forestry University, 37(9): 8-11.
- MacLean, D.A. and Morgan, M.G. 1983. Long-term growth and yield response of young fir to manual and chemical release from shrub competition. Forest Chron., 59: 177-183.
- Ma, J., Liu, S., Shi, Z., Zhang, Y. and Miao, N. 2009. Natural regeneration of Abies faxoniana along restoration gradients of subalpine dark coniferous forest in western Sichuan, China. Chinese J. Plant Ecol., 33 (4): 646-657.
- Nabel, M.R., Newton, M. and Cole, E.C. 2013. Abundance of natural regeneration and growth comparisons with planted seedlings 1013 years after commercial thinning in 50-year-old Douglas-fir, Douglas-fir/western hemlock, Oregon Coast Range. Forest Ecol. Manag., 292: 96-110.
- Nakamura, T. 1992. Effect of bryophytes on survival of conifer seedlings in subalpine forests of central Japan. Ecol. Res., 7: 155-162.
- Narukawa Y. and Yamamoto, S. 2003. Development of conifer seedlings ischolar_mains on soil and fallen logs in boreal and subalpine coniferous forests of Japan. Forest Ecol. Manag., 175: 131-139.
- O’Brien, M. J., O’Hara, K.L., Erbilgin, N. and Wood, D.L. 2007. Overstory and shrub effects on natural regeneration processes in native Pinus radiata stands. Forest Ecol. Manag., 240: 178-185.
- Oquist, G. and Huner, N.P. 1991. Effects of cold acclimation on the susceptibility of photosynthesis to photoinhibition in Scots pine and in winter and spring cereals: a fluorescence analysis. Funct.
- Ecol., 5: 91-100.
- Page, L.M. and Cameron, A D. 2006. Regeneration dynamics of Sitka spruce in artificially created forest gaps. Forest Ecol. Manag., 221: 260-266.
- Pelt, R.V., and Franklin, J.F. 2000. Influence of canopy structure on the understory environment in tall, old-growth, conifer forests. Can. J. For. Res., 30: 1231-1245.
- Petritan, A.M., von Lupke, B. and Petritan, I.C. 2007. Effects of shade on growth and mortality of maple (Acer pseudoplatanus), ash (Fraxinus excelsior) and beech (Fagus sylvatica) saplings. Forestry, 80: 397-412.
- Proll, G., Darabant, A., Gratzer, G. and Katzensteiner, K. 2015. Unfavourable microsites, competing vegetation and browsing restrict post-disturbance tree regeneration on extreme sites in the Northern Calcareous Alps. Eur. J. Forest Res., 134: 293-308.
- Roberts, S.D., Harrington, C.A. and Terry, T.A. 2005. Harvest residue and competing vegetation affect soil moisture, soil temperature, N availability, and Douglas-fir seedling growth. Forest Ecol. Manag., 205: 333-350.
- Rodwell, J.S. 1991. British Plant Communities, Woodlands and Scrub. Cambridge University Press, Cambridge, UK.
- Sarr, D.A., Hibbs, D.E., Shatford, J.P. and Momsen, R. 2011. Influences of life history, environmental gradients, and disturbance on riparian tree regeneration in western Oregon. Forest Ecol. Manag., 261: 1241-1253.
- Smith, C.J. 1980. Ecology of the English Chalk. Academic Press, London.
- Stancioiu, P.T. and O’Hara, K.L. 2006. Regeneration growth in different light environments of mixed species, multiaged, mountainous forests of Romania. Eur. J. Forest Res., 125: 151-162.
- Svenning, J. and Magárd, E. 1999. Population ecology and conservation status of the last natural population of English yew Taxus baccata in Denmark. Biol. Conserv., 88: 173-182.
- Takahashi, K. 1997. Regeneration and coexistence of two subalpine conifer species in relation to dwarf bamboo in the understorey. J. Veg. Sci., 8: 529-536.
- Wagner, S., Collet, C., Madsen, P., Nakashizuka, T., Nyland, R.D. and Sagheb-Talebi, K. 2010. Beech regeneration research: from ecological to silvicultural aspects. Forest Ecol. Manag., 259: 21722-182.
- Yildiz, O., Sarginci, M., Esen, D. and Cromack Jr., K. 2007. Effects of vegetation control on nutrient removal and Fagus orientalis, Lipsky regeneration in the western Black Sea Region of Turkey. Forest Ecol. Manag., 240: 186-194.
- Correlation Analysis Between Stand Structure Factors and Environmental Factors for Typical Forest Types in Beijing
Abstract Views :150 |
PDF Views:0
Authors
Affiliations
1 Key Laboratory for Silviculture and Conservation of Ministry of Education, Beijing Forestry University, Beijing, CN
2 State Forestry Administration Survey Planning and Design Institute, Beijing, CN
1 Key Laboratory for Silviculture and Conservation of Ministry of Education, Beijing Forestry University, Beijing, CN
2 State Forestry Administration Survey Planning and Design Institute, Beijing, CN
Source
Nature Environment and Pollution Technology, Vol 16, No 2 (2017), Pagination: 471-477Abstract
Studying the mechanisms between factors of stand structure and the environment is an important way to research and interpret the complex relationships between stand development and the environment. We investigated 113 sample plots of four typical forest types at Badaling forest farm in Beijing, and analysed stand soil structure, the correlations between stand structure and environmental factors, and the spatial distribution of soil nitrogen (TN) content and soil alkali-hydrolyzale (AN) content. The results showed that the typical forest types had significant differences in soil physical and chemical properties; the stand soil status of broad-leaved forest and scrubland was superior to that of the coniferous forest and the coniferous and broad-leaved mixed forest. The soil physical structure affected the stand structure more than the soil chemical structure, and stand structure variation caused by the soil factors was more important than the topographic factors in all the four typical forest types. Spatial heterogeneity in TN and AN was evidenced, and the overall N content was low.Keywords
Correlation Analysis, Stand Structure, Typical Forests, Badaling Forests.Full Text