First vs. second rotation of a poplar short rotation coppice: leaf area development, light interception and radiation use efficiency

First vs. second rotation of a poplar short rotation coppice: leaf area development, light interception and radiation use efficiency

Given the high expectations for lignocellulosic biomass as one of the potential solutions for energy security and climate change mitigation, commercial scale studies over several rotations are crucial to assess the potential and the sustainability of short rotation coppice (SRC) cultures for bioener...

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Bibliographic Details
Published in:IForest (Viterbo) Vol. 8; no. 5; pp. 565 - 573
Main Authors: Broeckx, LS, Vanbeveren, SP, Verlinden, MS, Ceulemans, R
Format: Journal Article
Language:English
Published: Potenza The Italian Society of Silviculture and Forest Ecology (SISEF) 01-10-2015
Italian Society of Silviculture and Forest Ecology (SISEF)
Subjects:
Aboveground Woody Biomass Productivity
Alternative energy sources
Bioenergy
Biomass
Climate change
Climate change mitigation
Coppicing
Efficiency
Energy security
Genotype & phenotype
Genotypes
Genotypic Variation
Harvest
Interception
Land use
Leaf area
Leaf Area Index
Leaves
Light
Light interception
Lignocellulose
Photosynthesis
Plantations
POPFULL
Poplar
Populus
Precipitation
Productivity
Radiation
Renewable energy
Rotation
Seasons
Sustainability
Trees
Yield
Oregon
Netherlands
Iowa
Belgium
United States > US
Europe
Illinois
Japan
Italy
France
Michigan
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Summary:Given the high expectations for lignocellulosic biomass as one of the potential solutions for energy security and climate change mitigation, commercial scale studies over several rotations are crucial to assess the potential and the sustainability of short rotation coppice (SRC) cultures for bioenergy. The first and the second rotation of the SRC poplar (Populus) plantation of the present study differed significantly in biomass yield and in productivity determinants and their relationships. Coppicing enhanced leaf area development, radiation interception and woody biomass productivity. High total leaf area and radiation use efficiency (RUE) equally contributed to the high biomass yield during the establishment rotation, while RUE became the most important determinant of biomass yield after coppice. The study confirmed the significant genotypic variation in biomass productivity and its underlying determinants, also among more recently selected poplar genotypes. The absence of a correlation between intercepted radiation and RUE suggests the potential of selecting for genotypes combining high total leaf area and photosynthetic carbon uptake in future breeding programs for yield maximization towards sustainable bioenergy cultivation.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
ISSN:1971-7458
1971-7458
DOI:10.3832/ifor1457-008