Do agricultural grasses bred for improved root systems provide resilience to machinery-derived soil compaction?

Research output: Contribution to journalArticlepeer-review

7 Citations (Scopus)
109 Downloads (Pure)

Abstract

The increasing frequency of droughts and floods on grasslands, due to climate change, increases the risk of soil compaction. Soil compaction affects both soil and forage productivity. Differing grasses may counteract some effects of compaction due to differences in their root architecture and ontogeny. To compare their resilience to soil compaction, three Festulolium (ryegrass and fescue species’ hybrids) forage grass cultivars comprising differing root architecture and ontogeny were compared in replicated field plots, together with a ryegrass and tall fescue variety as controls. Pre-compaction soil and forage properties were determined in spring using > four-year-old plots to generate baseline data. Half of each field plot was then artificially compacted using farm machinery. Forage dry matter yield (DMY) was determined over four cuts. After the final harvest, post compaction soil characteristics and root biomass (RB) were compared between grasses in the non-compacted and compacted soils. Pre-compaction data showed that soil under Festulolium and ryegrass had similar water infiltration rates, higher than soil under tall fescue plots. Tiller density of the Festulolium at this time was significantly higher than fescue but not the ryegrass control. Forage DMY was significantly lower (p <.001) with compacted soil at the first cut but, by the completion of the growing season, there was no effect of soil compaction on total DMY. Tall fescue had a higher total DMY than other grasses, which all produced similar annual yields. Soil bulk density and penetration resistance were higher, and grass tiller density was lower in compacted soils. Root biomass in compacted soils showed a tendency for Festulolium cv Lp × Fg to have higher RB than the ryegrass at 0–15 cm depth. Overall, findings showed alternative grass root structures provide differing resilience to machinery compaction, and root biomass production can be encouraged without negative impacts on forage productivity.

Original languageEnglish
Article numbere227
Number of pages12
JournalFood and Energy Security
Volume9
Issue number3
Early online date05 Jul 2020
DOIs
Publication statusPublished - 25 Aug 2020

Keywords

  • Festulolium
  • forage yield
  • roots
  • ryegrass
  • soil compaction

Fingerprint

Dive into the research topics of 'Do agricultural grasses bred for improved root systems provide resilience to machinery-derived soil compaction?'. Together they form a unique fingerprint.

Cite this