What question did this study set out to answer?

The study aims to compare belowground biomass characteristics and soil organic carbon accumulation in different bahiagrass-based forage systems with varying nitrogen inputs and legume integration.

March 27, 2026Open Access

Belowground biomass characteristics and soil organic C accumulation of bahiagrass‐based forage systems with or without legumes

Key Points

The study aims to compare belowground biomass characteristics and soil organic carbon accumulation in different bahiagrass-based forage systems with varying nitrogen inputs and legume integration.
Compared root–rhizome biomass and composition across three forage systems: bahiagrass monoculture with nitrogen, bahiagrass with legumes, and bahiagrass–rhizoma peanut mixture.
Assessed root accumulation and soil organic carbon stocks in a long-term grazing setup over 2 years.
Estimated decomposition dynamics and accumulation rates during warm and cool seasons.
BG–RP exhibited greater root–rhizome biomass compared to BG–N and BG–CL during summer.
BG–RP had 35% and 38% higher nitrogen and carbon stocks, respectively, compared to BG–N.
SOC stocks after 9 years were similar among all forage systems, indicating effective carbon accumulation even with lower nitrogen inputs.

Abstract

Abstract Grasslands are important terrestrial ecosystems that provide feed for livestock, support soil conservation and nutrient cycling, and store soil carbon (C). In many grazed grasslands, restricted nitrogen (N) inputs from fertilizers and minimal legume presence may constrain belowground biomass accumulation and soil C storage because of limited N. Our objective was to compare root–rhizome biomass and composition, root accumulation, and soil organic C (SOC) stocks for three grazed, year‐round forage systems based on bahiagrass ( Paspalum notatum Flügge). Systems included a bahiagrass monoculture during summer, overseeded with cool‐season grasses for winter, and receiving 224 kg N ha −1 year −1 (BG‐N bahiagrass during the warm season overseeded with ryegrass‐oats mixtures during the cool season, with 224 kg N ha −1 divided equally in cool and warm seasons); a bahiagrass monoculture during summer, overseeded with a cool‐season grass–legume mixture for winter, and receiving 34 kg N ha −1 year −1 (BG‐CL bahiagrass (no N‐fertilized) during the warm season overseeded with ryegrass–oats–clovers mixture (34 kg N ha −1 ) during the cool season); and a bahiagrass–rhizoma peanut ( Arachis glabrata Benth.) mixture during summer, overseeded with a cool‐season grass–legume mixture for winter, and receiving 34 kg N ha −1 year −1 (BG‐RP bahiagrass and rhizoma peanut (no N‐fertilized) during the warm season overseeded with ryegrass–oats–clovers mixture (34 kg N ha −1 ) during the cool season). This study assessed belowground responses and estimated decomposition dynamics during 2 years in a long‐term grazing system. During summer, BG‐RP had greater root–rhizome biomass (9770 kg OM ha −1 where OM stands for organic matter) than BG‐N (6230 kg OM ha −1 ) and BG‐CL (7320 kg OM ha −1 ). Greater root–rhizome mass in BG‐RP increased N (35%) and C (38%) stocks compared with BG‐N, but root–rhizome accumulation rate was not different among forage systems (14.5–15.9 and 15.6–22.6 kg OM ha −1 day −1 during cool and warm seasons, respectively). Nine years after imposing forage systems, SOC stocks (0–90 cm) had increased and were similar (104 Mg ha −1 ) across forage systems. Integrating legumes with limited N fertilizer application for 9 years resulted in similar SOC as heavily N‐fertilized, grass‐only systems.

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