On the success and failure of mixed-species tree plantations: lessons learned from a model system of Eucalyptus globulus and Acacia mearnsii David I. Forrester a,b, * , Ju ¨rgen Bauhus b,c , Annette L. Cowie b,d a School of Resources, Environment and Society, The Australian National University, Canberra, ACT 0200, Australia b Corporative Research Centre for Greenhouse Accounting, GPO Box 475, Canberra, ACT 2601, Australia c Institute of Silviculture, University of Freiburg, Tennenbacherstr. 4, 79106 Freiburg, Germany d Forest Research and Development Division, State Forests of New South Wales, PO Box 100, Beecroft, NSW 2119, Australia Abstract Mixed plantations of a Eucalyptus species with a nitrogen-fixing tree species can produce significantly higher quantities of aboveground biomass than monocultures. However, if species or sites are not chosen correctly, one species may suppress the growth of the other and mixtures may be less productive than monocultures. Based on a study of Eucalyptus globulus and Acacia mearnsii, this paper discusses the species attributes and site factors that should be considered to improve the probability of increasing biomass production using mixed-species plantations. In an 11-year-old mixed-species trial of E. globulus and A. mearnsii in southeastern Australia aboveground biomass production was twice as high in mixtures containing 50% E. globulus and 50% A. mearnsii than in E. globulus monocultures. There are three main types of interactions that led to this growth outcome: competition, competitive reduction and facilitation. Facilitation occurred as A. mearnsii fixed significant quantities of N, both in monoculture and when mixed with E. globulus. In addition, not only rates of N but also those of P cycling through litterfall were significantly higher in mixed stands than E. globulus monocultures, pointing to the importance of selecting a nitrogen-fixing species that is capable of N fixation and subsequent fast nutrient cycling through litterfall. Mixed stands developed stratified canopies, such that E. globulus eventually overtopped A. mearnsii after 9 years. This resulted in an increase in light capture at the stand level and a reduction in competition for light for E. globulus, a relatively shade intolerant species. This illustrates the importance of selecting species based on their height growth dynamics and relative shade tolerances, to ensure that neither species is suppressed by the other and that the less tolerant species is not overtopped by the more shade tolerant species. In addition to species attributes, site factors, such as soil nitrogen, phosphorus and water availability, play an important role in the interactions and processes occurring in mixtures. In a pot trial containing monocultures and mixtures of E. globulus and A. mearnsii, mixtures produced more biomass than monocultures of either species at low levels of N fertiliser. However, at high levels of N fertiliser E. globulus suppressed A. mearnsii and the biomass production of mixtures was not significantly different to that of E. globulus monocultures. This suggests that mixtures should only be planted on sites where the processes and www.elsevier.com/locate/foreco Forest Ecology and Management 209 (2005) 147–155 * Corresponding author. Tel.: +61 2 6125 2623; fax: +61 2 6249 0746. E-mail address: david.forrester@anu.edu.au (D.I. Forrester). 0378-1127/$ – see front matter # 2005 Elsevier B.V. All rights reserved. doi:10.1016/j.foreco.2005.01.012