LTER Publications - Tejera-Nieves, M. D., et.al. 2025. Switchgrass (Panicum Virgatum) and miscanthus (Miscanthus × Giganteus) long-term yield patterns reveal consistent productivity declines. Global Change Biology Bioenergy 17:e70088.

Tejera-Nieves, M. D., S. C. Córdova, M. Sears, K. D. Thelen, G. P. Robertson, and B. J. Walker. 2025. Switchgrass (Panicum Virgatum) and miscanthus (Miscanthus × Giganteus) long-term yield patterns reveal consistent productivity declines. Global Change Biology Bioenergy 17:e70088.

Citable PDF link: https://lter.kbs.msu.edu/pub/4266

Perennial grasses like switchgrass (Panicum virgatum) and miscanthus (Miscanthus × giganteus) are expected to supply a substantial amount of the United States bioeconomy's feedstock demand. However, uncertainties around their long-term yields challenge the viability of their potential and limit their wider adoption. To resolve their long-term yield patterns, we analyzed over 200 plantings of switchgrass and miscanthus across Michigan and Wisconsin, USA, measured over 5–15 years. We found a consistent two-phase long-term yield dynamic; during a yield-building phase, peak yields occurred within 4–5 years after planting, followed by a yield-decline phase in which switchgrass and miscanthus lost 30%–47% and 14%–40% of peak yields, respectively. Among the potential drivers of this dynamic and the yield decline, we found that weather conditions had little impact, as the variation across years was not large enough to drive the observed yield differences. Added nitrogen increased peak yields by 10%–20% and attenuated the yield decline by 20%–50%. However, since fertilized stands still showed a yield decline, other factors became limiting as stands aged. This conserved long-term yield dynamic has direct implications on management. A farm-to-gate economic analysis suggests replanting switchgrass and miscanthus 5 and 9 years following their peak yields maximizes profit over a 30-year time horizon. Results call for further management and breeding strategies to mitigate the yield-decline phase, and for reparameterization of global bioenergy models with carbon capture and storage, which may overestimate yields and the economic and environmental benefits of crops grown for bioenergy feedstocks.

DOI: 10.1111/gcbb.70088

Associated Treatment Areas:

GLBRC Biofuel Cropping System Experiment
Switchgrass Variety Experiment I
ACSE Fields LTAR Scaleup Fields
Switchgrass Nitrogen Fixation Experiment Switchgrass Nitrogen Fixation Experiment
GLBRC Marginal Land Experiment

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