Abstract
Panicum virgatum L. (switchgrass) cultivars (‘Alamo’, ‘Cimarron’, ‘Kanlow’, ‘NL 94C2-3’, ‘NSL 2009-1’, and ‘NSL 2009-2’) were evaluated for salt tolerance in two separate greenhouse experiments. In experiment (Expt.) 1, switchgrass seedlings were irrigated with a nutrient solution at an electrical conductivity (EC) of 1.2 dS·m−1 (control) or a saline solution (spiked with salts) at an EC of 5.0 dS·m−1 (EC 5) or 10.0 dS·m−1 (EC 10) for four weeks, once a week. Treatment EC 10 reduced the tiller number by 32% to 37% for all switchgrass cultivars except ‘Kanlow’. All switchgrass cultivars under EC 10 had a significant reduction of 50% to 63% in dry weight. In Expt. 2, switchgrass was seeded in substrates moistened with either a nutrient solution of EC 1.2 dS·m−1 (control) or a saline solution of EC of 5.0, 10.0, or 20.0 dS·m−1 (EC 5, EC 10, or EC 20). Treatment EC 5 did not affect the seedling emergence, regardless of cultivar. Compared to the control, EC 10 reduced the seedling emergence of switchgrass ‘Alamo’, ‘Cimarron’, and ‘NL 94C2-3’ by 44%, 33%, and 82%, respectively. All switchgrass cultivars under EC 10 had a 46% to 88% reduction in the seedling emergence index except ‘NSL 2009-2’. No switchgrass seedlings emerged under EC 20. In summary, high salinity negatively affected switchgrass seedling emergence and growth. Dendrogram and cluster of six switchgrass cultivars indicated that ‘Alamo’ was the most tolerant cultivar, while ‘NSL 2009-2’ was the least tolerant cultivar at both seedling emergence and growth stages. A growth-stage dependent response to salinity was observed for the remaining switchgrass cultivars. ‘NSL 2009-1’ and ‘NL 94C2-3’ were more tolerant to salinity than ‘Cimarron’ and ‘Kanlow’ at the seedling emergence stage; however, ‘Kanlow’ and ‘Cimarron’ were more tolerant to salinity than ‘NSL 2009-1’ and ‘NL 94C2-3’ at the seedling growth stage.
Highlights
Renewable energy is expected to make a significant contribution to meet global energy needs due to diminishing availability of discoverable fossil fuel reserves and the environmental consequences of exhaust gases from fossil fuel
Leaf area, tiller number, and shoot dry weight of switchgrass varied with salt treatments and cultivars, but no interactive effects occurred between treatment and cultivar
All switchgrass cultivars under electrical conductivity (EC) 5 tended to be shorter, with the exception of ‘Kanlow’
Summary
Renewable energy is expected to make a significant contribution to meet global energy needs due to diminishing availability of discoverable fossil fuel reserves and the environmental consequences of exhaust gases from fossil fuel. The U.S Energy Information Administration [1]. Reported that renewable energy, excluding hydropower, accounted for 28% of the overall growth in electricity generation from 2012 to 2040. One of the most important types of renewable energy, is gaining popularity and the demand for biofuel is increasing. In 2011, a total of 110 billion liters of biofuel were produced worldwide, among which bioethanol accounted for 78.7% [2]. Bioethanol is primarily produced from crops such as corn (Zea mays, L.), sugar beet The production and use of bioethanol may compete with food crops for arable land in the long term. Ethanol made from ligno-cellulosic feedstocks could play a critical role in promoting energy diversity and reducing carbon dioxide emissions [6].
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