The continuous growth of global ene

The continuous growth of global energy demands, coupled with political instability in oil-exporting countries and the persistent threat of climate change, have led to increasing concerns over the widespread use of fossil-derived resources to meet present and future needs of the people. The transportation sector in the U.S., for example, is known to occupy about 72% of the nation’s total liquid fuel consumption (EIA, 2014), and still remains heavily dependent on both domestic and imported petroleum. Although recent analyses have predicted an optimistic reduction of approximately 2.1 million barrels (250 million liters) of gasoline per day over the next two decades, these projections are imperatively contingent on the increased penetration of biofuel and natural gas into domestic markets (EIA, 2014).

Interestingly, there are few large-scale cellulosic biofuel facilities operating in the U.S. (EMTS, 2014) which perhaps best illustrates a well-known bottleneck for commercial development: the production of biofuels cannot yet compete with petroleum-based fuels on the basis of cost. One approach to mitigate this issue has been through the establishment of biorefineries that aim to convert renewable non-food feedstocks into two or more products. In many ways, biorefineries seek to mimic the oil refineries they intend to replace, but unlike conventional oil refineries, the goods produced by biorefineries (in addition to biofuel) will vary across the country as a result of region-specific feedstocks and/or needs.

In (sub)tropical geographies of the world, year-round growing seasons offer a unique benefit for biorefineries, allowing for the continuous 12-month growth of feedstocks, and production of biofuel and biobased products. Candidate crops in these areas (i.e., herbaceous C4 grasses) grow rapidly in high yields, but also typically have higher moisture contents (>70%) which may complicate conventional biomass handling and logistics. An opportunity to implement innovative bioprocessing strategies like green processing, however, as proposed by Takara and Khanal (2011), exists and may be appropriate for biorefineries in these regions. Defined succinctly, green processing is the upstream fractionation of crude feedstock into solid, (hemi)cellulosic fibers for biofuel production and liquid, nutrient-rich juice for high value microbial co-product (e.g., fungal protein) production.

To enhance the economic viability of (sub)tropical biorefineries, rigorous attention must be given to the raw materials entering the processing facility. Napier grass (Pennisetum purpureum), a candidate energy crop capable of achieving high yields of 94 dry metric tons/hectare ( Osgood et al., 1996), has been reported to have significant potential as a feedstock for large-scale renewable biofuel production in the state of Hawaii ( Tran et al., 2011). Perennial feedstocks, however, are believed to change in composition over their natural course of maturation ( Williams et al., 1980). In places with year-round growing seasons, there exists the potential to harvest feedstocks at ages and/or conditions which maximize both biofuel and bioproduct formation while simultaneously minimizing the overall production costs.

In this study, the structural composition of Napier grass, relevant to biofuel production, was analyzed over its natural course of maturation in the subtropical climate of Hawaii. The structural carbohydrates, lignin, ash, and extractives of the fibers were quantified and reported on a dry weight basis. Napier grass juice, collected from the green processing of crude feedstock, was characterized for its bioproduct potential based on its organic and nitrogen contents, and was reported holistically as concentrations of chemical oxygen demand (COD) and total Kjeldahl nitrogen (TKN), respectively. Insight for crop harvests was provided along with results to assist in decision making for commercial biorefineries in (sub)tropical regions of the world.