Almajmale A, Hardie M, Doyle R, et al. Influence of soil properties on the aggregate stability of cultivated sandy clay loams. Journal of Soil and Sediments, 2017, 17, 800-809.
Adesodun J K, Adeyemi E F, Oyegoke C O. Distribution of nutrient elements within water-stable aggregates of two tropical agro-ecological soils under different land uses. Soil & Tillage Research, 2006, 92, 190-197.
Ayoubi S, Karchegani P M, Mosaddeghi M R, et al. Soil aggregation and organic carbon as affected by topography and land use change in western Iran. Soil & Tillage Research, 2012, 121, 18-26.
Alagöz Z, Yilmaz E. Effects of different sources of organic matter on soil aggregate formation and stability: A laboratory study on a Lithic Rhodoxeralf from Turkey. Soil and Tillage Research, 2009, 103, 419-424.
Cheng H, Gong Y B, Fu Y X, et al. Soil Aggregate Stability and Characteristics of Organic Carbon Components in Three Forests of the Southwest Edge of Sichuan Basin. Journal of Soil and Water Conservation, 2018, 32, 109-115.
Castellano M J, Mueller K E, Olk D C, et al. Integrating plant litter quality, soil organic matter stabilization, and the carbon saturation concept. Global change biology, 2015, 21: 3200-3209.
Egan G, Crawley M J, Fornara D A. Effects of long-term grassland management on the carbon and nitrogen pools of different soil aggregate fractions. Science of the Total Environment, 2018, 614, 810-819.
Fattet M, Fu Y, Ghestem M, et al. Effects of vegetation type on soil resistance to erosion: relationship between aggregate stability and shear strength. Catena, 2011, 87, 60-69.
Ferro N D, Berti A, Francioso O, et al. Investigating the effects of wettability and pore size distribution on aggregate stability: the role of soil organic matter and the humic fraction. European Journal of Soil Science, 2012, 63, 152-164.
Ge N, Wei X, Wang X, et al. Soil texture determines the distribution of aggregate-associated carbon, nitrogen and phosphorous under two contrasting land use types in the Loess Plateau. Catena, 2019, 172, 148-157.
Guan F Y, Tang X L, Fan S H, et al. Changes in soil carbon and nitrogen stocks followed the conversion from secondary forest to Chinese fir and Moso bamboo plantations. Catena, 2015, 133:455-460.
Jiang X, Hu Y, Bedell J H, et al. Soil organic carbon and nutrient content in aggregate-size fractions of a subtropical rice soil under variable tillage. Soil Use and Management, 2011, 27, 28-35.
Kemper W D, Chepil W S. Size distribution of aggregation. In: Black, C.A., et al. (Eds.). Part 1. American Society of Agronomy. Monograph, 1965, pp: 499-510.
Li C, Li Y, Xie J, et al. Accumulation of organic carbon and its association with macro-aggregates during 100 years of oasis formation. Catena, 2019, 172, 770-780.
Liao X Z. Effect of clear cutting clearances on soil physicochemical properties of Cunninghamia lanceolata stand. Protection Forest Science and Technology. 2015, 10: 7-8.
Lu Y M, Wu D M, Xu E L, et al. Effects of Chinese Fir Inter planting with Broad-leaved Trees on Soil Phosphorus Fractions . Journal of Soil and Water Conservation, 2020, 34, 275-282.
Ma R, Cai C, Li Z, et al. Evaluation of soil aggregate microstructure and stability under wetting and drying cycles in two Ultisols using synchrotron-based X-ray micro-computed tomography. Soil & Tillage Research, 2015, 149, 1-11.
Mangalassery S, Sjogersten S, Sparkes D L, et al. The effect of soil aggregate size on pore structure and its consequence on emission of greenhouse gases. Soil and Tillage Research, 2013, 132, 39-46.
Niu D, Wang S L, Ouyang Z Y. Comparisons of carbon storages in Cunninghamia lanceolata and Michelia macclurei plantations during a 22-year period in southern China. Journal of Environmental Sciences, 2009, 21, 801-805.
Ranatunga T D, Reddy S S, Taylor R W. Phosphorus distribution in soil aggregate size fractions in a poultry litter applied soil and potential environmental impacts. Geoderma, 2013, 192, 446-452.
Ostrowska A, Porebska G. Assessment of the C/N ratio as an indicator of the decomposability of organic matter in forest soils . Ecological Indicators, 2015, 49, 104-109.
Six J, Paustian K. Aggregate-associated soil organic matter as an ecosystem property and a measurement tool. Soil Biology and Biochemistry, 2012, 68, 4-9
Sarker J R, Singh B P, Cowie A L, et al. Agricultural management practices impacted carbon and nutrient concentrations in soil aggregates, with minimal influence on aggregate stability and total carbon and nutrient stocks in contrasting soils. Soil & Tillage Research, 2018, 178, 209-223.
Wen J, Wang X L, Wang Y L, et al. Distribution Characteristics and Mechanism Discussion of Soil Cation Exchange Capacity and Exchangeable Based Cations of Alpine Grassland in the Source Region of Yangtze River. Ecology and Environmental Sciences, 2019, 28, 488-497.
Wang F H, Lü S, Huang R, et al. Distribution of Organic Carbon in Soil Aggregates from Four Kinds of Forest Vegetation on Jinyun Mountain . Environmental Science, 2019, 40: 1504-1511.
Wang Q K, Wang S L, Huang Y. Comparisons of litterfall, litter decomposition and nutrient return in a monoculture Cunninghamia lanceolata and a mixed stand in southern China, Forest Ecology and Management, 2008, 225: 1210-1218.
Wang S L, Liao L P, Deng S J, et al. Mixed of Cunninghamia lanceolata with Michelia macclurei and restoration of self-sustaining mechanism in G. lanceolate Plantation . Chinese Journal of Applied Ecology, 2000, 11(01): 34-37.
Wang S Q, Zhang Z, Ye S M. Response of soil fertility characteristics in water-stable aggregates to tea cultivation age in hilly region of southern Guangxi, China. Catena, 2020a, 191, 1-11.
Wang W B, Zhang Q, Sun X M, et al. Effects of mixed-species litter on bacterial and fungal lignocellulose degradation functions during litter decomposition. Soil Biology and Biochemistry, 2020b, 141.
Wiesmeier M, Steffens M, Mueller CW, et al. Aggregate stability and physical protection of soil organic carbon in semi-arid steppe soils. European Journal of Soil Science, 2012, 63, 22-31.
Wu W, Zheng Z, Li T, et al. Distribution of inorganic phosphorus fractions in water-stable aggregates of soil from tea plantations converted from farmland in the hilly region of western Sichuan, China . Journal of Soils and Sediments, 2018, 18: 906-916.
Yin H J, Wheeler E, Phillips R P. Root-induced changes in nutrient cycling in forests depend on exudation rates. Soil Biology and Biochemistry, 2014, 78:213-221.
Zou C, Li Y, Huang W, et al. Rotation and manure amendment increase soilmacro-aggregates and associated carbon and nitrogen stocks in flue-cured tobaccoproduction. Geoderma, 2018, 325, 49-58.
Zhao D, Xu M X, Liu G B, et al. Quantification of soil aggregate microstructure on abandoned cropland during vegetative succession using synchrotron radiation-based micro-computed tomography. Soil and Tillage Research, 2017, 165, 239-246
Zhou Y, Boutton T W, Wu X. Soil C: N: P stoichiometry responds to vegetation change from grassland to woodland. Biogeochemistry, 2018, 140, 341–357.
Zhang Y, Tigabu M, Zhang Y., et al. Soil parent material and stand development stage effects on labile soil C and N pools in Chinese fir plantations. Geoderma, 2019, 338, 247-258.