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[1] Wu JE, Liu WJ*, Chen CF. How do plants share water sources in a rubber-tea agroforestry system during the pronounced dry season? Agriculture, Ecosystems & Environment, 2017, 236: 69‒77. |
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[2] Wu JE, Zeng HH, Chen CF, Liu WJ*. Can intercropping with the Chinese medicinal herbs change the water use of the aged rubber trees? Agricultural Water Management, 2019, 226, 105803. |
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[3] Wu JE, Liu WJ*, Chen CF. Can intercropping with the world's three major beverage plants help improve the water use of rubber trees?. Journal of Applied Ecology, 2016, 53(6): 1787-1799. |
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[4] Wu JE, Zeng HH, Zhao F, Chen CF, Liu WJ*, Yang B, Zhang WJ. Recognizing the role of plant species composition in the modification of soil nutrients and water in rubber agroforestry systems. Science of The Total Environment, 2020, 138042. |
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[5] Wu JE, Zeng HH, Chen CF, Liu WJ*, Jiang XJ. Intercropping the Sharp-Leaf Galangal with the Rubber Tree Exhibits Weak Belowground Competition. Forests, 2019, 10(10), 924. |
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[6] Wu JE*, Zeng HH, Zhao F, Chen CF, Jiang XJ, Zhu XA, Wang PY, Wu ZX, Liu WJ*. The Nutrient Status of Plant Roots Reveals Competition Intensities in Rubber Agroforestry Systems. Forests, 2020, 11(11), 1163. |
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[7] Zeng HH, Wu JE*, Zhu XA, Singh A.K, Liu WJ*. Jungle rubber facilitates the restoration of degraded soil of an existing rubber plantation. Journal of Environmental Management, 2021, 111959. |
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[8] Wu JE, Liu WJ*, Chen CF. Below-ground interspecific competition for water in a rubber agroforestry system may enhance water utilization in plants. Scientific reports, 2016, 6, 19502. |
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[9] Chen CF, Liu WJ*, Jiang XJ*, Wu JE. Effects of rubber-based agroforestry systems on soil aggregation and associated soil organic carbon: implications for land use. Geoderma, 2017, 299: 13-24. |
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[10] Chen CF, Liu WJ*, Wu JE, Jiang XJ*. Spatio-temporal variations of carbon and nitrogen in biogenic structures of two fungus-growing termites (M. annandalei and O. yunnanensis) in the Xishuangbanna region. Soil Biology and Biochemistry, 2018, 117: 125-134. |
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[11] Chen CF, Liu WJ*, Wu JE, Jiang XJ*, Zhu XA. Can intercropping with the cash crop help improve the soil physico-chemical properties of rubber plantations? Geoderma, 2019, 335: 149–160. |
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[12] Chen CF, Wu JE, Zhu XA, Jiang XJ, Liu WJ*, Zeng HH, Meng FR. Hydrological characteristics and functions of termite mounds in areas with clear dry and rainy seasons. Agriculture, Ecosystems & Environment, 2019, 277, 25–35. |
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[13] Chen CF, Zou X, Wu JE, Zhu XA, Jiang XJ, Zhang WJ, Zeng HH, Liu WJ. Accumulation and spatial homogeneity of nutrients within termite (Odontotermes yunnanensis) mounds in the Xishuangbanna region, SW China[J]. Catena, 2020: 105057. |
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[14] Jiang XJ, Liu WJ*, Wu JE, Wang PY, Liu CA, Yuan ZQ. Land degradation controlled and mitigated by rubber-based agroforestry systems through optimizing soil physical properties and water supply mechanisms: A case study in Xishuangbanna, China. Land Degradation & Development, 2017, 28: 2277-2289. |
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[15] Jiang XJ*, Zakari S, Wu JE, Singh AK, Chen CF, Zhu XA, Zhang WJ, Liu WJ*. Can complementary preferential flow and non-preferential flow domains contribute to soil water supply for rubber plantation? Forest Ecology and Management, 2020, 461:117948. |
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[16] Liu JQ, Liu WJ*, Li WX, Jiang XJ, Wu JE. Effects of rainfall on the spatial distribution of the throughfall kinetic energy on a small scale in a rubber plantation. Hydrological Sciences Journal, 2018, 63: 1078-1090. |
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[17] Liu WJ*, Luo QP, Lu HJ, Wu JE, Duan WP. The effect of litter layer on controlling surface runoff and erosion in rubber plantations on tropical mountain slopes, SW China. Catena, 2017, 149: 167-175. |
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[18] Singh AK*, Jiang XJ, Yang B, Wu JE, Rai A, Chen CF, Ahirwal J, Wang PY, Liu WJ*, Singh N*. Biological indicators affected by land use change, soil resource availability and seasonality in dry tropics. Ecological Indicators, 2020, 115: 106369. |
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[19] Singh AK, Zhu XA, Chen CF, Wu JE, Yang B, Zakari S, Jiang XJ, Singh N, Liu W. (2020). The role of glomalin in mitigation of multiple soil degradation problems. Critical Reviews in Environmental Science and Technology, 1–35. |
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[20] Zakari S, Liu WJ*, Wu JE, Singh AK, Jiang XJ, Yang B, Chen CF, Zhu XA. Decay and erosion-related transport of sulfur compounds in soils of rubber based agroforestry[J]. Journal of Environmental Management, 2020, 274: 111200. |
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[21] Wang PY, Liu WJ*, Zhang JL, Yang B, Singh AK, Wu JE, Jiang XJ. Seasonal and spatial variations of water use among riparian vegetation in tropical monsoon region of SW China. Ecohydrology, 2019, 12: e2085. |
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[22] Zhu XA, Chen CF, Wu JE, Yang JB, Zhang WJ, Zou X, Liu WJ*, Jiang XJ*. Can intercrops improve soil water infiltrability and preferential flow in rubber-based agroforestry system? Soil & Tillage Research, 2019, 191: 327-339. |
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