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   Location:Home > Research > Research Progress
Study Reveals Trade-Offs in Soil Erosion Dynamics After Rubber-to-Balsa Plantation Conversion
Author: Zhou Xia
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Update time: 2026-07-16
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Rubber plantations have long been a major cause of severe soil degradation in tropical regions, including Xishuangbanna in southwest China. In recent years, the expansion of balsa (a fastgrowing lightweight wood) has raised new environmental concerns. A new study, however, suggests that the conversion from rubber to balsa may bring both risks and unexpected benefits.

In a study published in Agricultural Water Management, researchers from Xishuangbanna Tropical Botanical Garden (XTBG) of the Chinese Academy of Sciences and their collaborators tried to investigate how converting traditional rubber plantations to fast-growing balsa wood systems affects soil erosion dynamics. The findings uncovered a complex trade-off that balsas large leaves and sparser canopies can intensify the initial splash of raindrops, but its rootdriven soil properties dramatically boost water infiltration. This enhanced infiltration may actually reduce the urgency of soilconservation interventions compared with rubber systems.

To investigate these effects, the researchers compared splash erosion rates and their drivers across rubber monocultures, balsa monocultures of varying ages (2–4 years), a mixed balsa plantation, and an open-field control. They monitored 14 rainfall events between August and October 2024, measuring throughfall, leaf drip characteristics, splash erosion, and soil infiltration across six plantation types. They used modified splash cups and bowls to quantify both potential and actual splash erosion, providing a comprehensive in-situ assessment.

The results showed that, although balsa monocultures experience significantly higher splash erosion than rubber plantations, their superior infiltration capacity effectively prevents surface runoff and largescale soil loss. Specifically, splash erosion in balsa monocultures was 0.82 to 1.14 times higher than in rubber plots. Mixed balsa stands reduced splash erosion by 80.44% relative to monocultures. Balsa plantations also showed higher infiltration rates and higher saturated hydraulic conductivity than rubber systems. Despite high rainfall intensity, these hydrological gains decouple splash detachment from actual soil loss by minimizing runoff.

Our findings suggest that while balsa monocultures may increase splash erosion potential, their enhanced infiltration capacity largely compensates for this risk, making soil conservation measures less critical than in rubber systems, said LIU Wenjie of XTBG. Notably, integrating native species into balsa plantations offers a nature-based solution that balances productivity with soil protection.

The researchers caution that terrain slope and soil structure could still influence erosion risk in more complex landscapes, but they emphasize that the strong infiltration capacity of balsa systems serves as a primary defense against water and soil loss.

Available online: 27 June 2026


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Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences. Menglun, Mengla, Yunnan 666303, China
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