[BALOCCHI, C. E., F. E. BRIDGWATER and R. BRYANT (1994): Selection efficiency in a nonselected population of loblolly pine. Forest Science 40: 452-473.]Search in Google Scholar
[BURDON, R. D. (1977): Genetic correlation as a concept for studying genetype-environment interaction in forest tree breeding. Silvae Genetica 26: 5-6.]Search in Google Scholar
[COPPEN, J. J. W. and G. A. HONE (1995): Gum Naval Stores: Turpentine and Resin from Pine Resin, Natural Resources Institute, FAO.]Search in Google Scholar
[DU, L. F., Y. CHEN, Z. F. KE, D. X. GAO, Y. F. XIE, J. ZOU, H. P. LIU, X. H. JIA and Z. W. ZHANG (2010): Genetic gain of analysis on half-sib progenies family of Pinus massoniana. Journal of Huazhong Agricultural University 29: 772-777.]Search in Google Scholar
[FRIES, A. and T. ERICSSON (2009): Genetic parameters for earlywood and latewood densities and development with increasing age in Scots pine. Annals of Forest Science 66: 404.10.1051/forest/2009019]Search in Google Scholar
[GWAZE, D. (2009): Optimum selection age for height in shortleaf pine. New Forests 37: 9-16.10.1007/s11056-008-9104-9]Search in Google Scholar
[HAAPANEN, M. (2001): Time trends in genetic parameters estimates and selection efficiency for scots pine in relation to field testing method. Forest Genetics 8: 129-144.]Search in Google Scholar
[HE, B. X., H. M. LIAN, L. H. ZENG and Z. C. RUAN (1999): A study on pine resin chemical composition and its geographic variation of high resin masson pine superior tree. Guangdong Forestry Science and Technology 15: 1-7.]Search in Google Scholar
[HONG, Y. H., W. J. LIN and Y. F. HUANG (2010): Selection of excellent families and analysis on growth variation for the 12-year-old half-sib family of seed orchard of Pinus massoniana. Journal of Nanjing Forestry University 34: 26-31.]Search in Google Scholar
[HYLEN, G. (1999): Age trends in genetic parameters of wood density in young Norway spruce. Canadian Journal Forest Research 29: 135-143.10.1139/x98-170]Search in Google Scholar
[JI, K. S., M. L. FAN and L. A. XU (2005): Variation analysis and plus family selection on half-sib progenies from clonal seed orchard of Pinus massoniana. Scientia Silvae Sinicae 41: 43-49.]Search in Google Scholar
[JIN, G. Q., G. F. QIN, W. H. LIU, D. Y. CHU, S. Z. HONG and Z. C. ZHOU (2008a): Effects of mating manners on growth traits of Pinus massoniana and selection of cross combinations. Scientia Silvae Sinicae 44: 29-35.]Search in Google Scholar
[JIN, G. Q., G. F. QIN, W. H. LIU, D. Y. CHU, S. Z. HONG and Z. C. ZHOU (2008b): Genetic analysis of growth traits on tester strain progeny of Pinus massoniana. Scientia Silvae Sinicae 44: 71-79.]Search in Google Scholar
[KUMAR, S. and J. LEE (2002): Age-age correlations and early selection for end-of-rotation wood dentsity in radiata pine. Forest Genetics 9: 323-330.]Search in Google Scholar
[LEDIG, F. T. (1974): Analysis of methods for the selection of trees from wild stands. Forest Science 20: 2-16. ]Search in Google Scholar
[LI, L. and H. X. WU (2005): Efficiency of early selection for rotation-aged growth and wood density traits in Pinus radiata. Canadian Journal of Forest Research 35: 2019-2029.10.1139/x05-134]Search in Google Scholar
[LIAN, H. M., L. H. ZENG, B. X. HE, M. LUO, J. QIN, Z.Y. QI and R. K. LUO (2006): Study on the genetic variation of wood properties and correlation in wood properties and rowth, resin yielding ability. Guangdong Forestry Science and Technology 22: 5-11.]Search in Google Scholar
[LIN, Q. H., R. ZHANG, G. Q. JIN, D. Y. CHU and Z. C. ZHOU (2010): Variation of ring width and wood basic density and early selection of Pinus massoniana provenances. Scientia Silvae Sinicae 46: 50-56.]Search in Google Scholar
[LIU, Q. H., G. Q. JIN, R. ZHANG, D. Y. CHU, G. F. QIN and Z. C. ZHOU (2009): Provenance variation in growth, stem-form and wood density of masson pine at 24-yearold and the provenance division. Scientia Silvae Sinicae 45: 55-62]Search in Google Scholar
[LIU, Y. (2001): Production, consumption and prediction of China’s resin. Journal of Chemical Industry of Forest products 35: 31-33.]Search in Google Scholar
[MWASE, W. F., P. S. SAVILL and G. HEMERY (2008): Genetic parameter estimates for growth and form traits in common ash (Fraxinus excelsior, L.) in a breeding seedling orchard at Little Wittenham in England. New Forests 36: 225-238.10.1007/s11056-008-9095-6]Search in Google Scholar
[NAMKOONG, G., R. D. BARNES and J. BURLEY (1980): A philosophy of breeding strategy for tropical forest trees. Tropical Forestry Paper No. 16. Commonwealth Forestry Institute, Oxford, 67 pp.]Search in Google Scholar
[SEBBENN, A. M., F. C. ARANTES, O. V. BOAS and M. L. M. FREITAS (2008): Genetic variation in an international provenance-progeny test of Pinus caribaea Mor. var. bahamensis Bar. et Gol., in Sao Paulo, Brizil. Silvae Genetica 57: 181-187.10.1515/sg-2008-0028]Search in Google Scholar
[SHI, K. and Z. LI (1998): The Development of China’s Forestry: Review and Prospects. The Environmental Science Press of China, Beijing. pp 110. ]Search in Google Scholar
[TOMUSIAK, R. and M. MAGNUSZEWSKI (2009): Effect of resin tapping on radial increments of Scots pine (Pinus sylvestris L.). In: KACZKA, R., I. MALIK, P. OWCZARE, H. GÄRTNER, G. HELLE and I. HEINRICH (eds.) (2009): TRACE - Tree Rings in Archaeology, Climatology and Ecology, Vol. 7, pp 151-157.]Search in Google Scholar
[WANG, Z. and M. M. CALDERON and M. G. CARANDANG (2006): Effects of resin tapping on optimal rotation age of pine plantation. Journal of Forest Economics 11: 245-260.10.1016/j.jfe.2005.10.001]Search in Google Scholar
[WU, H. X., M. B. POWELL, J. L. YANG, M. IVKOVIC and T. A. MCRAE (2007): Efficiency of early selection for rotationaged wood quality traits in radiate pine. Annals of Forest Science 64: 1-9.10.1051/forest:2006082]Search in Google Scholar
[XIE, C. Y. (2008): Ten-year results from red alder (Alnus rubra Bong.) provenance-progeny testing and their implications for genetic improvement. New Forests 36: 273-284.10.1007/s11056-008-9098-3]Search in Google Scholar
[XU, Y. B. (1994): The collected research works on masson pine in Guangdong province. Guangdong Higher Education Press (Ed 1). Guangzhou. pp 11-23.]Search in Google Scholar
[YAMADA, Y. (1962): Genotype by environment interaction and genetic correlation of the same trait under different environments. Japanese Journal of Genetics 37: 498-509.10.1266/jjg.37.498]Search in Google Scholar
[ZENG, L. H. and S. L. YUE (1984): Correlation between resin-yielding capacity and growth traits of Pinus massoniana. Subtropical Forestry Science and Technology 1: 16-18.]Search in Google Scholar
[ZHANG, B. W. (2001): Cultivation technology for plantation of masson pine. China Agriculture Publishing House (Ed 1). Beijing. pp 122-127.]Search in Google Scholar
[ZHANG, Y., Z. C. ZHOU, G. Q. JIN and G. F. QIN (2010): Genetic distances of parents of Pinus massoniana and relationship between growth traits and heterosis of progeny. Journal of Nanjing Forestry University 34: 10-16.]Search in Google Scholar
[ZHOU, L., S. Q. LIU, Y. X. ZHU, Z. Y. HUANG and Z. P. SHAO (2008): Relationship between growth traits and growth stress of masson pine. Scientia Silvae Sinicae 44: 102-101.]Search in Google Scholar
[ZHOU, Z. C., G. R. LI, G. L. HUANG, B. X. CHEN and Y. K. LIN (2000): Genetic control of wood chemical compositions and its implication for wood breeding of masson pine. Scientia Silvae Sinicae 36: 110-117.]Search in Google Scholar