Two Novel Energy Crops: Sida hermaphrodita (L.) Rusby and Silphium perfoliatum L.—State of Knowledge

Cumplido-Marin, Laura; Graves, Anil; Burgess, Paul J.; Morhart, Christopher; Paris, P.; Jablonowski, Nicolai David; Facciotto, G.; Bury, Michael; Martens, Reent; Nahm, Michael

doi:10.3390/agronomy10070928

Cited by 46 publications

(34 citation statements)

References 167 publications

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“…Under suboptimal conditions of water and phosphorous shortage a higher yield stability of the crop mixtures was demonstrated, which makes them a suitable agronomic alternative to sole cropped maize or sorghum. Similar positive results for intercropping the perennial energy crop S. hermaphrodita with perennial legume species was also demonstrated in earlier studies, and was highlighted in the review-article on this crop by Cumplido-Marin et al [3].…”

supporting

confidence: 85%

“…Both studies clearly identified beneficial effects of the biogenic residues on plant performance in the given experimental time in maize. Such positive effects of digestate application in sand and other soils were also described in earlier greenhouse and outdoor studies using the perennial plant S. hermaphrodita as a promising bioenergy carrier, as described and summarized in the review-article by Cumplido-Marin et al [3]. Overall, in terms of declining mineral phosphorus resources and to reduce the high energy demand for nitrogen and mineral fertilizers in general, nutrient recycling becomes an important issue particularly for bio-energy crop production.…”

mentioning

confidence: 68%

“…Alternative perennial second generation energy crops such as Virginia mallow (Sida hermaphrodita L. Rusby), cup plant (Silphium perfoliatum L.), and giant miscanthus (Miscanthus x giganteus) that do not directly compete with food or feed have received considerable research attention in recent years and continue to be investigated, as is also shown in this special issue [3][4][5]. Among the use of such crops solely as energy carriers, higher value, and in return energy savings, could be achieved by emphasizing more the use of its biomasses for material applications.…”

mentioning

confidence: 99%

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Bioenergy Crops: Current Status and Future Prospects

Jablonowski

Schrey

2021

Agronomy

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confidence: 85%

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confidence: 68%

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confidence: 99%

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Bioenergy Crops: Current Status and Future Prospects

Jablonowski

Schrey

2021

Agronomy

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“…In recent years, the majority of research on cup plant has focused on its potential as a substitute for maize in biogas production in Europe, especially Germany [197][198][199]. While maize is somewhat higher yielding than cup plant, diversification of bioenergy feedstocks in agricultural landscapes is generally desirable and cup plant is perceived as providing more ecosystem services than maize [198].…”

Section: Dual-use Oilseedsmentioning

confidence: 99%

Ecological Intensification of Food Production by Integrating Forages

et al. 2021

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Forage crops have the potential to serve multiple functions, providing an ecological framework to sustainably intensify food production, i.e., ecological intensification. We review three categories of forages (annual forages, perennial forages, and dual-use perennial crops/forages) we believe hold the greatest promise for ecologically intensifying food production. Annual cover crops can provide additional forage resources while mitigating nutrient losses from agricultural fields when they are intercropped with, interseeded into, or following an annual crop, for instance. The integration of perennial forages either temporally, such as annual crop rotations that include a perennial forage phase, or spatially, such as the intercropping of perennial forages with an annual cash crop, provide weed suppression, soil quality, and yield and crop quality benefits. Dual-use crops/forages can provide forage and a grain crop in a single year while providing multiple ecological and economic benefits. However, tradeoffs in balancing multiple functions and limitations in reducing the risks associated with these practices exist. Advancing our understanding of these systems so we can overcome some of the limitations will play a critical role in increasing food production while promoting positive environmental outcomes.

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“…As a result of the conducted study, it was determined that cup plant dry weight yield increased with the increase in the level of fertilization and irrigation ( Figure 2). Other cultivation studies have shown that irrigation increases yields by 50%, while fertilization does so by more than 25% [33]. The greatest yield, i.e., 15.12 Mg ha −1 , was obtained for object W(+)/N80, and the difference between objects W(−)/N80 and W(+)/N80 was only 7.6%, testifying to the minor impact of irrigation on the dry weight yield at this fertilization dose.…”

Section: The Mass and Energy Balance During Cup Plant Biomass Gasificmentioning

confidence: 96%

Gasification of Cup Plant (Silphium perfoliatum L.) Biomass–Energy Recovery and Environmental Impacts

et al. 2020

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Biomass from cup plant (Silphium perfoliatum L.) is considered a renewable energy source that can be converted into alternative fuel. Calorific syngas, a promising type of advanced fuel, can be produced through thermochemical biomass gasification. In this study, the suitability of cup plant biomass for gasification was assessed, including the process energy balance and environmental impacts of waste from syngas purification. Silphium perfoliatum L. was cultivated as a gasification feedstock in different conditions (irrigation, fertilization). The experiments were performed in a membrane gasifier. All obtained energy parameters were compared to the biomass yield per hectare. The toxic effects of liquid waste were assessed using tests analyzing germination/seed root elongation of Sinapsis alba. Leachates collected from condensation tanks of a gas generator were introduced to soil at the following doses: 100, 1000 and 10,000 mg kg−1 DM of soil. The usefulness of Silphium perfoliatum L. for gasification was confirmed. The factors of plant cultivation affected the biomass yield, the volume and calorific value of syngas and the amount of biochar. It was determined that the components found in condensates demonstrate a phytotoxic effect, restricting or inhibiting germination and root elongation of Sinapsis alba. Due to this potential hazard, the possibility of its release to the environment should be limited. Most of the biomass is only used for heating purposes, but the syngas obtained from the cup plant can be used to power cogeneration systems, which, apart from heat, also generate electricity.

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Two Novel Energy Crops: Sida hermaphrodita (L.) Rusby and Silphium perfoliatum L.—State of Knowledge

Cited by 46 publications

References 167 publications

Bioenergy Crops: Current Status and Future Prospects

Bioenergy Crops: Current Status and Future Prospects

Ecological Intensification of Food Production by Integrating Forages

Gasification of Cup Plant (Silphium perfoliatum L.) Biomass–Energy Recovery and Environmental Impacts

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