Biomass production and nitrogen accumulation and remobilisation by Miscanthus × giganteus as influenced by nitrogen stocks in belowground organs

► This study illustrates the key role of belowground biomass nitrogen stocks for biomass production and nitrogen accumulation. ► Belowground biomass nitrogen stocks provide a significant part of the nitrogen accumulated in aboveground biomass via spring remobilisation. ► The variability in spring re...

Full description

Saved in:
Bibliographic Details
Published in:Field crops research 2011-04, Vol.121 (3), p.381-391
Main Authors: Strullu, L., Cadoux, S., Preudhomme, M., Jeuffroy, M-H., Beaudoin, N.
Format: Article
Language:English
Subjects:
Apparent nitrogen fluxes
Biomass crop
Harvest date
Nitrogen fertilisation
Perennial reserves
Rhizome
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:► This study illustrates the key role of belowground biomass nitrogen stocks for biomass production and nitrogen accumulation. ► Belowground biomass nitrogen stocks provide a significant part of the nitrogen accumulated in aboveground biomass via spring remobilisation. ► The variability in spring remobilisation is explained by initial belowground biomass nitrogen stocks. ► Autumn remobilisation is significant but may depend on many factors such as environment, photoperiod or harvest date. ► In case of early harvests, the needs for nitrogen fertiliser are enhanced. The nitrogen (N) requirement of dedicated crops for bioenergy production is a particularly significant issue, since N fertilisers are energy-intensive to make and have environmental impacts on the local level (NO 3 leaching) and global level (N 2O gas emissions). Nitrogen nutrition of Miscanthus × giganteus aboveground organs is assumed to be dependent on N stocks in belowground organs, but the precise quantities involved are unknown. A kinetic study was carried out on the effect of harvest date (early harvest in October or late harvest in February) and nitrogen fertilisation (0 or 120 kg N ha −1) on aboveground and belowground biomass production and N accumulation in established crops. Apparent N fluxes within the crop and their variability were also studied. Aboveground biomass varied between 24 and 28 t DM ha −1 in early harvest treatments, and between 19 and 21 t DM ha −1 in late harvest treatments. Nitrogen fertilisation had no effect on crop yield in late harvest treatments, but enhanced crop yield in early harvest treatments due to lower belowground biomass nitrogen content. Spring remobilisation, i.e. nitrogen flux from belowground to aboveground biomass, varied between 36 and 175 kg N ha −1, due to the variability of initial belowground nitrogen stocks in the different treatments. Autumn remobilisation, i.e. nitrogen flux from aboveground to belowground organs, varied between 107 and 145 kg N ha −1 in late harvest treatments, and between 39 and 93 kg N ha −1 in early harvest treatments. Autumn remobilisation for a given harvest date was linked to aboveground nitrogen accumulation in the different treatments. Nitrogen accumulation in aboveground biomass was shown to be dependent firstly on initial belowground biomass nitrogen stocks and secondly on nitrogen uptake by the whole crop. The study demonstrated the key role of belowground nitrogen stocks on aboveground biomass nitrogen requirem
ISSN:0378-4290
1872-6852
DOI:10.1016/j.fcr.2011.01.005