Soil phosphorus fractions and their availability over natural succession from clear-cut of a mixed broadleaved and Korean pine forest in northeast China

Peng Yu; Xin Zhang; Huiyan Gu; Jianping Pan; Xiangwei Chen

doi:10.1007/s11676-020-01285-6

Journal of Forestry Research ›› 2021, Vol. 33 ›› Issue (1) : 253 -260. DOI: 10.1007/s11676-020-01285-6

Original Paper

Soil phosphorus fractions and their availability over natural succession from clear-cut of a mixed broadleaved and Korean pine forest in northeast China

Author information +

History +

PDF

Abstract

To assess phosphorus (P) status of forest soil under naturally restored vegetation, P fractions in the 10-cm soil layer were quantified at different successional stages on the clear-cut site of mixed broadleaved and Korean pine forest. Four communities of shrub, softwood broad-leaved forest, softwood and hardwood broad-leaved forest, and hardwood broad-leaved forest represented different successional stages. A soil sample from a primary broad-leaved and Korean pine stand was the control. A sequential P fractionation scheme extracted empirically defined pools of P and path analysis used to partition the direct and indirect contribution of soil P fractions to available P. The results show that available P increased significantly with long-term succession, while both sodium bicarbonate-extractable P (NaHCO₃-P) and sodium hydroxide-extractable P (NaOH-P) fractions were reduced in early successional stages and increased in late stages. Compared to the primary forest, concentrations of P fractions in the four stages significantly decreased except for HCl-P, indicating that soil P supplements over the long-term did not return to primary forest levels. The results of related analysis also showed that NaHCO₃-P_i levels were significantly related to available phosphorus. According to the path analysis coefficient, NaHCO₃-P_i exhibited the highest effect on available P among eight P fractions; the indirect effects of other P fractions via NaHCO₃-P_i were larger than those with other P fractions. Overall, this study suggests that soil P bioavailability gradually improved during natural vegetation restoration on clear-cut sites mainly through the increase of NaHCO₃-P, where phosphorous is immediately available, and subsequently available phosphorus NaOH-P.

Keywords

Vegetation succession / Available phosphorus / Phosphorus fractions / Correlation analysis / Path analysis

Cite this article

Download citation ▾

Peng Yu, Xin Zhang, Huiyan Gu, Jianping Pan, Xiangwei Chen. Soil phosphorus fractions and their availability over natural succession from clear-cut of a mixed broadleaved and Korean pine forest in northeast China. Journal of Forestry Research, 2021, 33(1): 253-260 DOI:10.1007/s11676-020-01285-6

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]	Chen LX. Soil experiment and practice tutorials, 2005, Harbin, China (in Chinese): Northeast Forestry University Press.

[2]	Chen X, Li BL. Tree diversity change in remaining primary mixed-broadleaved Korean pine forest under climate change and human activities. Biodiversity Conserv, 2004, 13: 563-577.

[3]	Chen L, Zhang C, Duan W. Temporal variations in phosphorus fractions and phosphatase activities in rhizosphere and bulk soil during the development of Larix olgensis plantations. J Plant Nutr Soil Sci, 2016, 179: 67-77.

[4]	Feng PT, Kim JH, Lee DK. Review of land use history and cover change of the mixed broadleaved-Korean pine forest in northeast China. Forest Sci Technol, 2007, 3: 26-32.

[5]	Fu D, Wu X, Duan C, Zhao L, Li B. Different life-form plants exert different rhizosphere effects on phosphorus biogeochemistry in subtropical mountainous soils with low and high phosphorus content. Soil Tillage Res, 2020, 199: 104516.

[6]	Garay M, Amiotti N, Zalba P. Response of phosphorus pools in Mollisols to afforestation with Pinus radiata D. Don in the Argentinean Pampa. Forest Ecol Manage, 2018, 422: 33-40.

[7]	Gong H, Yao F, Gao J. Succession of a broad-leaved Korean pine mixed forest: Functional plant trait composition. Global Ecol Conserv, 2020, 22: e00950.

[8]	Guan L, Chan Z, Zhang J, Zhang G, Zhang Y. Influence of carbonized maize stalks on fractions and availability of phosphorus in Brown soil. Sci Agri Sinica, 2013, 46: 2050-2057. (in Chinese)

[9]	Guo S, Han X, Li H, Wang T, Tong X, Ren G, Feng Y, Yang G. Evaluation of soil quality along two revegetation chronosequences on the loess hilly region of China. Sci Total Environ, 2018, 633: 808-815.

[10]	Han Y, Choi B, Chen XW. Adsorption and desorption of phosphorus in biochar- amended black soil as affected by freeze-thaw cycles in northeast China. Sustainability, 2018, 10: 1574.

[11]	Han M, Tang M, Shi B, Jin G. Effect of canopy gap size on soil respiration in a mixed broadleaved-Korean pine forest: evidence from biotic and abiotic factors. Euro J Soil Biol, 2020, 99: 103194.

[12]	Hashimoto Y, Kang J, Matsuyama N, Saigusa M. Path analysis of phosphorus retention capacity in allophanic and non-allophanic andisols. Soil Sci Soc Am J, 2012, 76: 441-448.

[13]	He YJ, Liang XY, Qin L, Li ZY, Shao MX, Tan L. Community characteristics and soil properties of coniferous plantation forest monocultures in the early stages after close-to-nature transformation management in southern subtropical China. Acta Ecol Sinica, 2013, 33: 2484-2495.

[14]	Hedley MJ, Stewart JWB, Chauhan BS. Changes inorganic and organic soil phosphorus fractions induced by cultivation practices and by laboratory incubations. Soil Sci Soc Am J, 1982, 46: 970-976.

[15]	Jin GZ, Liu Y, Liu S, Ji HK. Effect of gaps on species diversity in the naturally regenerated mixed broadleaved-Korean pine forest of the Xiaoxing’an Mountains. China J Ecol Environ, 2007, 30: 325-330.

[16]	Li FR. Forest mensuration, 2019 4 Beijing, China: China Forestry Publishing House (in Chinese)

[17]	Li X, Zhang Y, Niu L, Han S. Litter decomposition processes in the pure birch (Betula platyphylla) forest and the birch and poplar (Populus davidiana) mixed forest. Acta Ecol Sinica, 2007, 27: 1782-1790. (in Chinese)

[18]	Maranguit D, Guillaume T, Kuzyakov Y. Land-use change affects phosphorus fractions in highly weathered tropical soils. CATENA, 2017, 149: 385-393.

[19]	Missong A, Holzmann S, Bol R, Nischwitz V, Puhlmann H, Wilpert KV, Siemens J, Klumpp E. Leaching of natural colloids from forest topsoils and their relevance for phosphorus mobility. Sci Total Environ, 2018, 634: 305-315.

[20]	Murphy J, Riley JP. A modified single solution method for the determination of phosphate in natural waters. Anal Chim Acta, 1962, 27: 31-36.

[21]	Prakash D, Benbi DK, Saroa GS. Land-use effects on phosphorus fractions in Indo-Gangetic alluvial soils. Agroforestry Syst, 2018, 92: 437-448.

[22]	Qi Y, Li F, Liu Z, Jin G. Impact of understorey on overstorey leaf area index estimation from optical remote sensing in five forest types in northeastern China. Agri Forest Meteorol, 2014, 198–199: 72-80.

[23]	Shi B, Gao W, Jin G. Effects on rhizospheric and heterotrophic respiration of conversion from primary forest to secondary forest and plantations in northeast China. Euro J Soil Biol, 2015, 66: 11-18.

[24]	Shi B, Gao W, Cai H, Jin G. Spatial variation of soil respiration is linked to the forest structure and soil parameters in an old-growth mixed broadleaved-Korean pine forest in northeastern China. Plant Soil, 2016, 400: 263-274.

[25]	Smith CK, Munson AD, Coyea MR. Nitrogen and phosphorus release from humus and mineral soil under black spruce forests in central Quebec. Soil Biol Biochem, 1998, 30: 1491-1500.

[26]	Soil Survey Staff. Soil Taxonomy: a basic system of soil classification for making and interpreting soil surveys, 1999, Washington, D.C.: USDA Natural Resources Conservation Service.

[27]	Sui YB, Thompson ML, Shang C. Fractionation of phosphorus in a mollisol amended with biosolids. Soil Sci Soc Am J, 1999, 63: 1174-1180.

[28]	Sun Y, Zhu J, Sun OJ, Yan Q. Photosynthetic and growth responses of Pinus koraiensis seedlings to canopy openness: implications for the restoration of mixed-broadleaved Korean pine forests. Environ Exp Bot, 2016, 129: 118-126.

[29]	Tang XL, Wang YP, Zhou GY, Zhang DQ, Liu S, Liu SZ, Zhang QM, Liu JX, Yan JH. Different patterns of ecosystem carbon accumulation between a young and an old-growth subtropical forest in Southern China. Plant Ecol, 2011, 212: 1385-1395.

[30]	Tiecher T, Gomes V, Ambrosini G, Amorim MB, Bayer C. Assessing linkage between soil phosphorus forms in contrasting tillage systems by path analysis. Soil Tillage Res, 2018, 175: 276-280.

[31]	Tiessen H, Moir JO (1993) Characterization of available P by sequential extraction. In: Carter MR (ed) Soil sampling and methods of analysis. Canadian Soc. Soil Sci. 75–86

[32]	Wang GP, Liu JS, Wang JD, Yu JB. Soil phosphorus forms and their variations in depressional and riparian freshwater wetlands (Sanjiang Plain, Northeast China). Geoderma, 2006, 132: 59-74.

[33]	Wang H, Zhang GH, Li NN, Zhang BJ, Yang HY. Soil erodibility influenced by natural restoration time of abandoned farmland on the loess plateau of China. Geoderma, 2018, 325: 18-27.

[34]	Wu Q, Zhang S, Zhu P, Huang S, Wang B, Zhao L, Xu M. Characterizing differences in the phosphorus activation coefficient of three typical cropland soils and the influencing factors under long-term fertilization. PLoS ONE, 2017, 12: e0176437.

[35]	Yang XY, Chen XW. Vertical Distribution of soil phosphorus fractionation in uncultivated black Soil. Chin J Soil Sci, 2016, 47: 378-383.

[36]	Yu DP, Zhou WM, Zhou L, Dai LM. Exploring the history of the management theory and technology of broad-leaved Korean pine (Pinus koraiensis Sieb. et Zucc.) forest in Changbai Mountain region. Northeast China Chin J Appl Ecol, 2019, 30: 1426-1434.

[37]	Zhang H, Shi L, Wen D, Yu K. Soil potential labile but not occluded phosphorus forms increase with forest succession. Biol Fertility Soils, 2016, 52: 41-51.

[38]	Zhang H, Shi L, Lu H, Shao Y, Liu S, Fu S. Drought promotes soil phosphorus transformation and reduces phosphorus bioavailability in a temperate forest. Sci Total Environ, 2020, 732: 139295.