Adaptive Ecophysiological Characteristics of Leaves and Root Distribution of Robusta Coffee Saplings as Affected by Age of Rubber Trees under an Intercropping System

Document Type : Original Research

Authors
R. Chiarawipa
P. Suteekanjanothai
B. Somboonsuke
Agricultural Innovation and Management Division, Faculty of Natural Resources, Prince of Songkla University, Songkhla, Thailand.
Abstract
Robusta coffee has been grown traditionally in Southern Thailand. This study aimed to evaluate the adaptation in the growth development of sole Robusta coffee (Coffea canephora) saplings and rubber-Robusta coffee saplings intercropping (8- and 16-year-old rubber plantations) planted between the shaded and unshaded conditions. The results showed that capturing light by sole Robusta coffee saplings (100%) was greater than those recorded in the 8- and 16-year-old rubber plantations (93 and 78.22%) over the measurement period. Soil moisture content was markedly higher in both rubber sites (6.34 and 7.25%) throughout the growing season compared to the full sunlight condition. In addition to the rubber canopy, the Leaf Area Indexes (LAI) over the entire period varied from 0.35 to 3.29 and 0.38 to 2.33 for the 8- and 16-year-old rubber plantations, respectively. Results at 18 months after growing also indicated that Robusta coffee saplings grown in full sunlight had higher values of new leaves, and canopy width also had higher values than those of the other two treatments based on rubber intercropping. Meanwhile, no significant differences in photosynthetic pigments (Chla, Chlb, Chla/Chlb, Chltotal, and Car) were observed between the 8-year-old rubber plantations compared to the full sunlight coffee trees. For the root competition, there were significant differences in fine root length in the 20 and 40 cm layers, which were greatly found in 18 months old coffee plants under direct sunlight. Meanwhile, the older rubber trees (16 years) showed a high density of root spread penetrated to all soil depths compared to younger rubber trees (8 years). Thus, these results indicated that the growth potential of Robusta coffee saplings was strongly limited by a combination of shaded and root competition conditions under rubber plantation. Changes in the leaf and root structural traits of Robusta coffee saplings under the conditions of rubber ecological plantations would be valuable for manipulating the efficient growth of coffee for long-term rubber-based intercropping systems.

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Journal of Agricultural Science and Technology
Volume 23, Issue 2
March and April 2021
Pages 387-402