Eucalyptus and Populus short rotation woody crops for phosphate mined lands in Florida USA

Abstract Our short-rotation woody crops (SRWC) research in central and southern Florida is (1) developing superior Eucalyptus grandis (EG), E. amplifolia (EA), and cottonwood ( Populus deltoides , PD) genotypes, (2) determining appropriate management practices for and associated productivities of these genotypes, and (3) assessing their economics and markets. Reclaimed clay settling areas (CSA) and overburden sites in phosphate mined areas in central Florida are a potential land base of over 80,000 ha for SRWC production. On CSAs, PD grows well in the absence of cogongrass ( Imperata cylindrica ) but is not as productive as the non-invasive EG and EA. SRWC establishment on CSAs requires strict implementation of the following cultural practices: thorough site preparation through herbiciding/disking and bedding, superior trees, watering/packing seedlings, fertilization with ammonium nitrate at planting and annually thereafter as feasible, high planting density possibly including double row planting, and winter harvesting so that coppice regeneration suppresses weeds. PD cultural requirements, that may require post-planting weed control to suppress herbaceous competition, exceed those of the eucalypts. EG SRWCs on CSAs are at risk of blowdown 3–4 years after planting or coppicing; younger PD, EG, and EA SRWCs appear much less susceptible to wind damage. Genetic improvement must continue if EG, EA, and PD are to increase in commercial feasibility. SRWC cost competitiveness will depend on establishment success, yield improvements, harvesting costs, and identifying/using incentives. Strong collaboration among public and private partners is necessary for commercializing SRWCs in Florida.

[1]  M. Langholtz ECONOMIC AND ENVIRONMENTAL ANALYSIS OF TREE CROPS ON MARGINAL LANDS IN FLORIDA , 2005 .

[2]  A. W. Hodges,et al.  Economic development through biomass systems integration in central Florida , 1995 .

[3]  E. A. Stadlbauer,et al.  IN SITU AND ON-SITE BIOREMEDIATION , 1999 .

[4]  D. Rockwood,et al.  Development of Eucalyptus clones for a summer rainfall environment with periodic severe frosts , 1987, New Forests.

[5]  D. Rockwood,et al.  Field performance of micropropagated, macropropagated, and seed-derived propagules of three Eucalyptus grandis ortets , 1994, Plant Cell Reports.

[6]  J. G. Isebrands,et al.  Short-rotation woody crops and phytoremediation: Opportunities for agroforestry? , 2004, Agroforestry Systems.

[7]  T. F. Geary,et al.  Growing eucalypts in Florida for industrial wood production. , 1983 .

[8]  D. Rockwood,et al.  Breeding strategies for coppice production in a Eucalyptus grandis base population with 4 generations of selection. , 1989 .

[9]  R. B. Hall,et al.  Fast-growing trees for heavy metal and chlorinated solvent phytoremediation. , 2004 .

[10]  M. Lesney,et al.  Nodule culture and regeneration of Eucalyptus grandis hybrids , 1991, Plant Cell Reports.

[11]  D. Rockwood,et al.  Promising species for woody biomass production in warm-humid environments , 1986 .

[12]  D. Rockwood,et al.  Micropropagation of field tested superior Eucalyptus grandis hybrids , 1990, New Forests.

[13]  D. Rockwood,et al.  Comparison of Eucalyptus grandis Provenances and Seed Orchards in a Frost Frequent Environment , 1991 .

[14]  Mark D. O. Adams ASSESSING AWARENESS OF FLORIDA HOMEOWNERS ABOUT THE USE OF BIOMASS FOR ELECTRICITY PRODUCTION , 2003 .

[15]  George Meskimen,et al.  Realized gain from breeding Eucalyptus grandis in Florida , 1983 .