Growth and nutrient dynamics of Betula alnoides seedlings under exponential fertilization

Lin Chen; Chunsheng Wang; Bernard Dell; Zhigang Zhao; Junjie Guo; Daping Xu; Jie Zeng

doi:10.1007/s11676-017-0427-2

Journal of Forestry Research ›› 2017, Vol. 29 ›› Issue (1) : 111 -119. DOI: 10.1007/s11676-017-0427-2

Original Paper

Growth and nutrient dynamics of Betula alnoides seedlings under exponential fertilization

Author information +

History +

PDF

Abstract

Betula alnoides is a fast-growing hardwood species grown in large plantations in Southeast Asia and South China. Nitrogen requirements for producing robust seedlings, growth and nutrient dynamics were investigated using exponential fertilization treatments. Root collar diameter, height, dry mass and nutrient contents of seedlings increased exponentially in all fertilization treatments as time progressed. Moreover, with water soluble fertilizer (Plant Products plus microelements N–P₂O₅–K₂O: 20–20–20), 300 mg N seedling⁻¹ was adequate. Vector analysis revealed that P was the most responsive nutrient element, followed by N and K. Dilutions of N and K were evident in the plants without N addition, which induced initial P sufficiency and then luxury consumption probably due to the antagonistic interaction between N and P. However, deficiencies of N, P and K were mostly observed in all exponential regimes during the experiment because seedling growth rate exceeded nutrient uptake rate, inferring that further study on improving the nutrient uptake efficiency is needed. Analysis of relationships among nutrient supply, dry mass, N content and N concentration demonstrated that 100–400 mg N seedling⁻¹ induced sufficiency to luxury consumption of nitrogen without significant change in dry mass, and 400 mg N seedling⁻¹ is recommended to apply for nutrient loading of seedlings before outplanting. The findings will help improve seedling quality and enhance the production of robust seedlings for plantation forestry of this species.

Keywords

Betula alnoides / Growth performance / Luxury nutrient consumption / Nitrogen requirement / Vector analysis

Cite this article

Download citation ▾

Lin Chen, Chunsheng Wang, Bernard Dell, Zhigang Zhao, Junjie Guo, Daping Xu, Jie Zeng. Growth and nutrient dynamics of Betula alnoides seedlings under exponential fertilization. Journal of Forestry Research, 2017, 29(1): 111-119 DOI:10.1007/s11676-017-0427-2

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Agathokleous E, Saitanis CJ, Wang X, Watanabe M, Koike T. A review study on past 40 years of research on effects of tropospheric O₃ on belowground structure, functioning, and processes of trees: a linkage with potential ecological implications. Water Air Soil Pollut, 2016 227 1 33

[2]	Basave Villalobos E, Cetina Alcalá VM, López López MA, Aldrete A, Del Valle Paniagua DH. Nursery practices increase seedling performance on nutrient-poor soils in Swietenia humilis. iForest-Biogeosciences For, 2014 8 4 552

[3]	Chen L, Zeng J, Xu DP, Zhao ZG, Guo JJ. Macronutrient deficiency symptoms in Betula alnoides seedlings. J Trop For Sci, 2010, 22: 403-413.

[4]	Chen L, Zeng J, Xu DP, Zhao ZG, Guo JJ, Lin KQ, Sha E. Effects of exponential nitrogen loading on growth and foliar nutrient status of Betula alnoides seedlings. Sci Sil Sin, 2010, 46(5): 35-40. (in Chinese)

[5]	Chen L, Zeng J, Jia HY, Zeng J, Guo WF, Cai DX. Growth and nutrient uptake dynamics of Mytilaria laosensis seedlings under exponential and conventional fertilizations. Soil Sci Plant Nutr, 2012, 58(5): 618-626.

[6]	Duan J, Xu C, Jacobs DF, Ma L, Wei H, Jiang L, Ren J. Exponential nutrient loading shortens the cultural period of Larix olgensis seedlings. Scand J For Res, 2013, 28(5): 409-418.

[7]	Gong M, Wang F, Chen Y, Chen Y. Mycorrhizal dependency and inoculant effects on growth of Betula alnoides seedlings. For Res, 1999, 13(1): 8-14. (in Chinese)

[8]	Haase DL, Rose R. Vector analysis and its use for interpreting plant nutrient shifts in response to silvicultural treatments. For Sci, 1995, 41(1): 54-66.

[9]	Heiskanen J, Lahti M, Luoranen J, Rikala R. Nutrient loading has a transitory effect on the nitrogen status and growth of outplanted Norway spruce seedlings. Silva Fenn, 2009, 43(2): 249-260.

[10]	Imo M, Timmer VR. Nitrogen uptake of mesquite seedlings at conventional and exponential fertilization schedules. Soil Sci Soc Am J, 1992, 56(3): 927-934.

[11]	Imo M, Timmer VR. Vector diagnosis of nutrient dynamics in mesquite seedlings. For Sci, 1997, 43(2): 268-273.

[12]	Jiang Y, Wang D, Qiu Q, Yang D, Xu L, Zhao Y, Zhang K, Li Y, Zhao H. Fertilization experiment on young plants of seven broadleaved tree species indigenous to tropical areas. Yunnan For Sci Tech, 2003, 103: 11-16. (in Chinese)

[13]	Quoreshi M, Timmer VR. Growth, nutrient dynamics, and ectomycorrhizal development of container-grown Picea mariana seedlings in response to exponential nutrient loading. Can J For Res, 2000, 30(2): 191-201.

[14]	Rikala R, Heiskanen J, Lahti M. Autumn fertilization in the nursery affects growth of Picea abies container seedlings after transplanting. Scand J For Res, 2004, 19(5): 409-414.

[15]	Rytter L, Ericsson T, Rytter RM. Effects of demand-driven fertilization on nutrient use, root: plant ratio and field performance of Betula pendula and Picea abies. Scand J For Res, 2003, 18(5): 401-415.

[16]	Salifu KF, Jacobs DF. Characterizing fertility targets and multi-element interactions in nursery culture of Quercus rubra seedlings. Ann For Sci, 2006, 63(3): 231-237.

[17]	Salifu KF, Timmer VR. Optimizing nitrogen loading of Picea mariana seedlings during nursery culture. Can J For Res, 2003, 33(7): 1287-1294.

[18]

Salifu KF, Jacobs DF, Birge ZKD (2008) Performance of nutrient-loaded red oak and white oak seedlings on mine lands in southern Indiana. In: Dumroese RK, Riley LE (Technical coordinators) National proceedings: forest and conservation nursery associations-2007. Fort Collins (CO): USDA Forest Service, Rocky Mountain Research Station. Proceedings RMRS-P-57, p 65–71

[19]	Timmer VR. Exponential nutrient loading: a new fertilization technique to improve seedling performance on competitive sites. New For, 1996, 13(1): 279-299.

[20]	Timmer VR, Armstrong G. Growth and nutrition of containerized Pinus resinosa seedlings at varying moisture regimes. New For, 1989, 3(2): 171-180.

[21]	Timmer VR, Armstrong G, Miller BD. Steady-state nutrient preconditioning and early outplanting performance of containerized black spruce seedlings. Can J For Res, 1991, 21(5): 585-594.

[22]	Van den Driessche R. Van den Driessche R. Effects of nutrients on stock performance in the forest. Mineral nutritional in conifer seedlings, 1991, Florida: CRC Press 229 260

[23]	Wang J, Li G, Pinto JR, Liu J, Shi W, Liu Y. Both nursery and field performance determine suitable nitrogen supply of nursery-grown, exponentially fertilized Chinese pine. Silva Fenn, 2015, 49(3): 1-13.

[24]	Wang X, Agathokleous E, Qu L, Watanabe M, Koike T. Effects of CO₂ and O₃ on the interaction between root of woody plants and ectomycorrhizae. J Agric Meteo, 2016, 72(2): 95-105.

[25]	Xu XJ, Timmer VR. Biomass and nutrient dynamics of Chinese fir seedlings under conventional and exponential fertilization regimes. Plant Soil, 1998, 203(2): 313-322.

[26]	Zeng J, Guo WF, Zhao ZG, Weng QJ, Yin GT, Zheng HS. Domestication of Betula alnoides in China: current status and perspectives. For Res, 2006, 19(3): 379-384. (in Chinese)