Rubber planting brings huge economic benefits, but large-scale rubber plantations have a great impact on the ecological environment, especially in terms of soil physical and chemical properties. Previous studies have shown that the rubber agroforestry has significant ecological and economic benefits. However, the understanding of the impact of different rubber planting modes on soil carbon cycle is still lacking.

In a study published in Journal of Environmental Management, researchers from Xishuangbanna Tropical Botanical Garden (XTBG) examined the impacts of rainforest conversion to rubber plantations on soil dissolved organic carbon (DOC), one of the most mobile organic matter (OM) in the terrestrial ecosystem that causes the transformation and migration of C, and the ratio of carbon and nitrogen (C:N). They also explored how such conversion mediated these impacts by altering soil biogeochemical properties.

The researchers evaluated the effects of different land use types on soil DOC and other soil chemical properties, by comparing soil samples from rubber monocultures, mixed rubber plantations (Hevea brasiliensis, Ficus langkokensis, and Actinodaphne henryi), and reference rainforests. To explore the role of micro organisms in the transformation process of DOC, they further analyzed the relationships between microbial biomass carbon (MBC) and nitrogen (MBN) with the DOC/DN ratio.

They found that the rainforest conversion to rubber plantations led to an increase in soil DOC concentration and a decrease in SOC and nutrients,which in turn increased the loss of DOC as its utilization by microorganisms was limited.

Specifically, the rubber plantations had 150–200% higher DOC concentration despite having 38.5% lower SOC concentration than in rainforests, which indicated the lower adsorption potential of soils in rubber plantations than in rainforests. 

In addition, the establishment of rubber agroforestry caused degradation of major soil properties including decreased pH, electrical conductivity, soil organic carbon (SOC), available nitrogen, available phosphorus, total nitrogen (TN) and total phosphorus (TP), which were significantly negatively correlated with DOC.

The researchers thus proposed to optimize plant density and introducing nitrogen-fixing legumes intercropping in rubber plantations, so as to improve soil health and reduce the loss of DOC and its potential environmental impacts.

Contact

LIU Wenjie Ph.D Principal Investigator

Key Laboratory of Tropical Forest Ecology, Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Mengla, Yunnan 666303, China

E-mail:  lwj@xtbg.org.cn 

Published: 19 October 2024