Soil degradation in oil palm and rubber plantations under land resource scarcity

• Published in: Agriculture, ecosystems & environment Vol. 232; pp. 110 - 118
• Main Authors: Guillaume, Thomas, Holtkamp, Anna Mareike, Damris, Muhammad, Brümmer, Bernhard, Kuzyakov, Yakov
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 16.09.2016
• Subjects: Carbon sequestration; Deforestation; Land degradation; Land-use change; Resource depletion; Tropical ecosystems; Indonesia, Sumatera, Jambi; Indonesia; Deforestation; Tropical ecosystems; Land degradation; Carbon sequestration; Resource depletion; Land-use change
• ISSN: 0167-8809; 1873-2305
• DOI: 10.1016/j.agee.2016.07.002

⿢Soils under oil palms had lower carbon stocks and higher density compared to rubber.⿢Oil palms were more frequently established on peat soils and riparian areas.⿢Stronger soil degradation in the interrows than in the rows of oil palms.⿢The resource-use efficiency of agriculture in Sumatra decreases with land scarcity. Tropical regions, such as Sumatra, experiencing extensive transformation of natural ecosystems, are close to complete exhaustion of available land. Agroecosystems strongly modify water and nutrient cycles, leading to losses of soil fertility, C sequestration and biodiversity. Although large companies are the main drivers of deforestation and plantation establishment, smallholders account for 40% of the oil palm and the majority of the rubber production in Indonesia. Here, we assess the extent and mechanisms of soil degradation under smallholder oil palm and rubber plantations in a context of land scarcity. The topsoil properties (C and N contents, C stocks, C/N ratio, bulk density) in 207 oil palm and rubber plantations in the Jambi province of Sumatra were determined beside trees, inside rows and interrows. Soils under oil palms were on average more degraded than under rubber, showing lower C content and stocks, lower N and higher bulk density. While soil properties were homogenous under rubber, two opposite trends were observed under oil palm plantations: the majority of soils had C content <2.2%, but about one fifth of the plantations had >9% C. This resulted from the establishment of oil palms under conditions of land scarcity. Because the oil palm boom started when rubber was already well-established, oil palms were frequently planted in marginal areas, such as peatlands or riparian areas (high C) or soils degraded by previous use (low C). The management of oil palms led to subsequent soil degradation, especially in interrows: C content decreased and bulk density increased in older oil palm plantations. This was not observed in rubber plantations because of a C input from leaf litter spread homogeneously all over the plantation, higher ground cover and a limited use of motorized vehicles. Considering that 10% of soils under oil palms had very low C content (<1%), we conclude that intensive cultivation can lead to intensive soil degradation and expect future degradation of soils under young oil palms. This challenges the sustainability of agricultural intensification in Sumatra. Because Sumatra is a pioneer of tropical land-use change, this should be regarded as potential threats that other tropical regions may face in future.