Abstract
Phragmites australis, Typha latifolia, T. angustifolia and Arundo donax are tall wetland graminoids with the potential to replace fossil fuels under sustainable cultivation conditions. We investigated the biomethane (CH4) production of these four species, including four different genotypes of P. australis, which represent the high intraspecific diversity of European reed. All plants were grown under three different macronutrient supplies (no nutrients added, an equivalent of 75 kg N ha−1 year−1 added and an equivalent of 500 kg N ha−1 year−1 added). Biomethane production was measured in four independent batch digestion tests. Across all experiments, fertilization regime had little effect on CH4 yield, which was on average 222 ± 31 L kg−1 volatile solids (VS). The lowest yield was produced by T. angustifolia (140 L kgVS−1) receiving no nutrients, while the highest yield was produced by A. donax (305 L kgVS−1) in the highest nutrient treatment. The intraspecific diversity of P. australis did not affect biomethane production. All P. australis genotypes produced on average 226 ± 19 L CH4 kgVS−1, which, although high, was still lower than conventional biogas species. The biomass production of P. australis was less increased by fertilization than that of Typha sp. and A. donax, but all species had similar biomass without fertilization.
Highlights
Biomethane is a sustainable and renewable alternative to fossil fuels, produced from organic material, e.g., from highly productive plants
We observed that A. donax produced the highest biomethane yield under all fertilizer regimes, compared to all other taxa, and that the increase in biomethane yield with higher fertilizing regime seemed to depend on taxon
We quantified CH4 production of four paludiculture crops, Typha angustifolia, T. latifolia, Arundo donax and Phragmites australis, and how it was affected by different fertilization regimes
Summary
Biomethane is a sustainable and renewable alternative to fossil fuels, produced from organic material, e.g., from highly productive plants. Biomethane can be used as vehicle fuel, as fuel in combined heat and power systems, or to produce electricity and heat, and the digested effluent (digestate) can be utilized as fertilizer [1,2,3]. In the face of the global climate and energy crisis, it is of utmost importance to identify plants that can serve as biomass feedstock for biomethane production. Species cultivated on arable land, compete with food and fodder production for the cropland and raw materials, such as fertilizers, required for cultivation. Alternative cultivation methods are urgently needed to produce sustainable, renewable resources for bioenergy. A promising option is Resources 2020, 9, 57; doi:10.3390/resources9050057 www.mdpi.com/journal/resources
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
