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ARS Home » Southeast Area » Houma, Louisiana » Sugarcane Research » Research » Publications at this Location » Publication #330911

Research Project: Integrated Crop, Soil, and Water Management Systems for Sustainable Production of Sugarcane for Bioenergy Feedstock

Location: Sugarcane Research

Title: Unique cover crops for Louisiana sugarcane

Author
item Shrefler, James - Oklahoma State University
item Webber Iii, Charles
item White, Paul
item Dalley, Caleb - North Dakota State University
item Petrie, Eric
item Viator, Ryan - Calvin Viator & Associates

Submitted to: Southern Cover Crop Conference
Publication Type: Abstract Only
Publication Acceptance Date: 7/10/2016
Publication Date: 7/18/2016
Citation: Shrefler, J.W., Webber III, C.L., White Jr, P.M., Dalley, C.D., Petrie, E.C., Viator, R.P. 2016. Unique cover crops for Louisiana sugarcane [meeting abstract]. Proceedings 2016 Southern Cover Crop Conference, July 18-19, 2016, Mount Olive, North Carolina. p. 34.

Interpretive Summary:

Technical Abstract: Louisiana sugarcane production practices provide a tremendous opportunity for the use of cover crops following the final sugarcane harvest in the fall of one year and prior to replanting sugarcane during the summer of the next year. A Louisiana sugarcane field is typically replanted every four years due to declining yields and, although it is a costly process, it is both a necessity, and an opportunity to maximize the financial return during the next four year cropping cycle. The use of cover crops during this fallow period has the potential to influence not only the following sugarcane crop, but the economics of the production system as a whole. A 2 year experiment was conducted at the USDA, ARS, Sugarcane Research Unit at Houma, LA to determine the impact of fallow planting systems on sugarcane production. The experiment included seven treatments; two cover crops, kenaf (Hibiscus cannabinus L.) and cowpeas (Vigna unguiculata L. Walp.), three harvest treatments, and a control. The experiment had four replications. The kenaf and cowpeas were planted on 8 May 2013. The three harvest treatments included the removal of the cover crop at 50 days after planting (DAP), the removal of the harvested cover crop at 100 DAP, and lastly, cutting the cover crop at 100 DAP and incorporating the plant material into the soil prior to sugarcane planting. The control treatment did not have a cover crop. Sugarcane variety HoCP 96-540 was planted on 26 August 2013, 110 days after planting the cover crop crops. The plant cane was harvested on 17 November 2014. The cover crop harvest dates, 50 DAP and 100 DAP, significantly influenced the yield and plant partitioning for both cover crops across all parameters measured. Kenaf fresh and dry yields, for the leaves, stalks, and whole plants, increased from the 50 to 100 DAP. Cowpea, in most aspects, followed a similar trend as kenaf as influenced by DAP harvests with the exception of the cowpea leaf fresh and dry weights. Unlike kenaf, the cowpea leaf, fresh and dry weight yields (50 DAP), 19.4 and 2.5 mt/ha, respectively, decreased to 17.0 and 2.4 mt/ha (100 DAP). Although the sugarcane total recoverable sucrose (TRS) (kg/mt) was greater with the kenaf cover-crop treatment 50 DAP (120 kg/mt) compared to the cowpea treatment 50 DAP (111 kg/mt) and the cowpea 100 DAP with the residue incorporated (112 kg/ha), none of the cover crop treatments were significantly better or worse than the control (no cover crop). The average values for the sugarcane production factors across all treatments were 95,700 plants/ha (plant population), 112 mt/ha (sugarcane yield), 114 kg/mt (sugar yield per metric ton of sugarcane), and 12,841 kg/ha (sugar yield per hectare). The results demonstrate the potential use of these alternative cover crops during the fallow period prior to planting sugarcane without adversely affecting the plant cane yields.