Estimation of Genetic Parameters of Biomass Production and Composition Traits in Miscanthus sinensis Using a Staggered-Start Design

[1]  M. Brancourt-Hulmel,et al.  Linkage Mapping of Biomass Production and Composition Traits in a Miscanthus sinensis Population , 2021, BioEnergy Research.

[2]  B. Mary,et al.  Miscanthus Sinensis is as Efficient as Miscanthus × Giganteus for Nitrogen Recycling in spite of Smaller Nitrogen Fluxes , 2021, BioEnergy Research.

[3]  M. Brancourt-Hulmel,et al.  Estimating the Genetic Parameters of Flowering Time-Related Traits in a Miscanthus sinensis Population Tested with a Staggered-Start Design , 2021, BioEnergy Research.

[4]  M. Brancourt-Hulmel,et al.  Variability of stem solidness among miscanthus genotypes and its role on mechanical properties of polypropylene composites , 2021, GCB Bioenergy.

[5]  V. Méchin,et al.  A Comparative Study of Maize and Miscanthus Regarding Cell-Wall Composition and Stem Anatomy for Conversion into Bioethanol and Polymer Composites , 2021, BioEnergy Research.

[6]  L. Trindade,et al.  Genetic Variability of Morphological, Flowering, and Biomass Quality Traits in Hemp (Cannabis sativa L.) , 2020, Frontiers in Plant Science.

[7]  E. Sacks,et al.  Field Performance of Saccharum × Miscanthus Intergeneric Hybrids (Miscanes) Under Cool Climatic Conditions of Northern Japan , 2019, BioEnergy Research.

[8]  S. Long,et al.  Biomass yield in a genetically diverse Miscanthus sinensis germplasm panel evaluated at five locations revealed individuals with exceptional potential , 2019, GCB Bioenergy.

[9]  P. Dixon,et al.  Multi-year and Multi-site Establishment of the Perennial Biomass Crop Miscanthus × giganteus Using a Staggered Start Design to Elucidate N Response , 2019, BioEnergy Research.

[10]  P. Dixon,et al.  Multi-year and Multi-site Establishment of the Perennial Biomass Crop Miscanthus × giganteus Using a Staggered Start Design to Elucidate N Response , 2019, BioEnergy Research.

[11]  A. Hastings,et al.  Breeding progress and preparedness for mass‐scale deployment of perennial lignocellulosic biomass crops switchgrass, miscanthus, willow and poplar , 2018, Global change biology. Bioenergy.

[12]  S. Sharma,et al.  Genetic mapping of biomass yield in three interconnected Miscanthus populations , 2018 .

[13]  E. Heaton,et al.  Description and Codification of Miscanthus × giganteus Growth Stages for Phenological Assessment , 2017, Front. Plant Sci..

[14]  B. Chabbert,et al.  Saccharification Performances of Miscanthus at the Pilot and Miniaturized Assay Scales: Genotype and Year Variabilities According to the Biomass Composition , 2017, Front. Plant Sci..

[15]  L. Trindade,et al.  Genetic complexity of miscanthus cell wall composition and biomass quality for biofuels , 2017, BMC Genomics.

[16]  R. Hatfield,et al.  Grass Cell Walls: A Story of Cross-Linking , 2017, Front. Plant Sci..

[17]  L. Trindade,et al.  Stability of Cell Wall Composition and Saccharification Efficiency in Miscanthus across Diverse Environments , 2017, Frontiers in plant science.

[18]  M. Brancourt-Hulmel,et al.  Miscanthus stem fragment – Reinforced polypropylene composites: Development of an optimized preparation procedure at small scale and its validation for differentiating genotypes , 2016 .

[19]  Junhua Peng,et al.  Ecological characteristics and in situ genetic associations for yield-component traits of wild Miscanthus from eastern Russia. , 2016, Annals of botany.

[20]  Xiaoqing Yu,et al.  Marker-Trait Association for Biomass Yield of Potential Bio-fuel Feedstock Miscanthus sinensis from Southwest China , 2016, Front. Plant Sci..

[21]  T. Hodkinson,et al.  New Breeding Collections of Miscanthus sinensis , M. sacchariflorus and Hybrids from Primorsky Krai, Far Eastern Russia , 2016 .

[22]  T. Voigt,et al.  Characterizing a Miscanthus Germplasm Collection for Yield, Yield Components, and Genotype × Environment Interactions , 2015 .

[23]  J. Juvik,et al.  Mapping the genome of Miscanthus sinensis for QTL associated with biomass productivity , 2015 .

[24]  Kenji Suzuki,et al.  Evaluation of morphological traits, winter survival and biomass potential in wild Japanese Miscanthus sinensis Anderss. populations in northern Japan , 2015 .

[25]  Junhua Peng,et al.  Genetic structure of Miscanthus sinensis and Miscanthus sacchariflorus in Japan indicates a gradient of bidirectional but asymmetric introgression , 2015, Journal of experimental botany.

[26]  Facundo Muñoz,et al.  breedR: Statistical methods for forest genetic resources analysts , 2015 .

[27]  M. Brancourt-Hulmel,et al.  Miscanthus clones for cellulosic bioethanol production: Relationships between biomass production, biomass production components, and biomass chemical composition , 2015 .

[28]  M. Brancourt-Hulmel,et al.  A Review on Miscanthus Biomass Production and Composition for Bioenergy Use: Genotypic and Environmental Variability and Implications for Breeding , 2015, BioEnergy Research.

[29]  M. Jones,et al.  Miscanthus: a case study for the utilization of natural genetic variation , 2014, Plant Genetic Resources.

[30]  J. Juvik,et al.  Plant morphology, genome size, and SSR markers differentiate five distinct taxonomic groups among accessions in the genus Miscanthus , 2014 .

[31]  M. Brancourt-Hulmel,et al.  A Review on Miscanthus Biomass Production and Composition for Bioenergy Use: Genotypic and Environmental Variability and Implications for Breeding , 2014, BioEnergy Research.

[32]  S. Long,et al.  A footprint of past climate change on the diversity and population structure of Miscanthus sinensis. , 2014, Annals of botany.

[33]  Iris Lewandowski,et al.  Inter-annual variation in biomass combustion quality traits over five years in fifteen Miscanthus genotypes in south Germany , 2014 .

[34]  G. Richard,et al.  Paving the way for sustainable bioenergy in Europe: Technological options and research avenues for large-scale biomass feedstock supply , 2014 .

[35]  Kerrie Farrar,et al.  Genome-wide association studies and prediction of 17 traits related to phenology, biomass and cell wall composition in the energy grass Miscanthus sinensis , 2013, The New phytologist.

[36]  Lígia Regina Lima Gouvêa,et al.  Simultaneous selection of rubber yield and girth growth in young rubber trees , 2013 .

[37]  John Clifton-Brown,et al.  Accelerating the domestication of a bioenergy crop: identifying and modelling morphological targets for sustainable yield increase in Miscanthus , 2013, Journal of experimental botany.

[38]  Gordon G. Allison,et al.  Contrasting geographic patterns of genetic variation for molecular markers vs. phenotypic traits in the energy grass Miscanthus sinensis , 2013 .

[39]  Hadi Quesneville,et al.  GnpIS: an information system to integrate genetic and genomic data from plants and fungi , 2013, Database J. Biol. Databases Curation.

[40]  J. Juvik,et al.  The Gene Pool of Miscanthus Species and Its Improvement , 2013 .

[41]  M. Brancourt-Hulmel,et al.  Shoot organogenesis in three Miscanthus species and evaluation for genetic uniformity using AFLP analysis , 2013, Plant Cell, Tissue and Organ Culture (PCTOC).

[42]  H. Monod,et al.  An Index of Competition Reduces Statistical Variability and Improves Comparisons between Genotypes of Miscanthus , 2012, BioEnergy Research.

[43]  Gordon G. Allison,et al.  Genotypic variation in cell wall composition in a diverse set of 244 accessions of Miscanthus , 2011 .

[44]  S. Carpenter,et al.  Solutions for a cultivated planet , 2011, Nature.

[45]  R. Arundale,et al.  Growth and agronomy of Miscanthus × giganteus for biomass production , 2011 .

[46]  K. Głowacka,et al.  Variation on biomass yield and morphological traits of energy grasses from the genus Miscanthus during the first years of crop establishment , 2011 .

[47]  Thomas B. Voigt,et al.  Growth and agronomy of Miscanthus x giganteus for biomass production , 2011 .

[48]  Hicran Açıkel The use of miscanthus (Giganteus) as a plant fiber in concrete production , 2011 .

[49]  H. Zub,et al.  Key traits for biomass production identified in different Miscanthus species at two harvest dates. , 2011 .

[50]  Qiang Sun,et al.  A taxonomic revision of Miscanthus s.l. (Poaceae) from China , 2010 .

[51]  John Clifton-Brown,et al.  Genotypic and environmentally derived variation in the cell wall composition of Miscanthus in relation to its use as a biomass feedstock , 2010 .

[52]  A. Hastings,et al.  Future energy potential of Miscanthus in Europe , 2009 .

[53]  M. Walsh,et al.  Miscanthus : For Energy and Fibre , 2009 .

[54]  Evelyne Costes,et al.  Dissecting apple tree architecture into genetic, ontogenetic and environmental effects: mixed linear modelling of repeated spatial and temporal measures. , 2008, The New phytologist.

[55]  Sébastien Lê,et al.  FactoMineR: An R Package for Multivariate Analysis , 2008 .

[56]  Wilfred Vermerris,et al.  Miscanthus: Genetic resources and breeding potential to enhance bioenergy production , 2008 .

[57]  S. Jeżowski,et al.  Yield traits of six clones of Miscanthus in the first 3 years following planting in Poland , 2008 .

[58]  Evelyne Costes,et al.  Dissecting apple tree architecture into genetic, ontogenetic and environmental effects: QTL mapping , 2008, Tree Genetics & Genomes.

[59]  Dželetović Željko,et al.  Miscanthus: European experience with a novel energy crop , 2007 .

[60]  Thomas M. Loughin,et al.  Improved Experimental Design and Analysis for Long‐Term Experiments , 2006 .

[61]  MICHAEL B. Jones,et al.  Miscanthus for Renewable Energy Generation: European Union Experience and Projections for Illinois , 2004 .

[62]  J. Clifton-Brown,et al.  Miscanthus biomass production for energy in Europe and its potential contribution to decreasing fossil fuel carbon emissions , 2004 .

[63]  J. Scurlock,et al.  The development and current status of perennial rhizomatous grasses as energy crops in the US and Europe , 2003 .

[64]  John Clifton-Brown,et al.  Screening Miscanthus genotypes in field trials to optimise biomass yield and quality in Southern Germany , 2002 .

[65]  Gw Dutkowski,et al.  Analysis of early tree height in forest genetic trials is enhanced by including a spatially correlated residual , 2001 .

[66]  D. G. Christian,et al.  Performance of 15 Miscanthus genotypes at five sites in Europe , 2001 .

[67]  J. Davis,et al.  Quantitative genetics of bud phenology, frost damage, and winter survival in an F2 family of hybrid poplars , 2000, Theoretical and Applied Genetics.

[68]  J. Greef,et al.  Syntaxonomy of Miscanthus x giganteus Greef et Deu , 1993 .

[69]  I. Warrington,et al.  Corn Growth Response to Temperature: Rate and Duration of Lead Emergence , 1989 .

[70]  M. Appleyard,et al.  Cereal development guide. 2nd Edition. , 1984 .

[71]  C. R. Henderson Applications of linear models in animal breeding , 1984 .

[72]  M. Appleyard,et al.  Cereal development guide. , 1981 .

[73]  H. Akaike A new look at the statistical model identification , 1974 .

[74]  P. V. Soest,et al.  Use of Detergents in the Analysis of Fibrous Feeds. IV. Determination of Plant Cell-Wall Constituents , 1967 .

[75]  Van Soest Use of Detergents in the Analysis of Fibrous Feeds. II. A Rapid Method for the Determination of Fiber and Lignin , 1963 .

[76]  H. Grüneberg,et al.  Introduction to quantitative genetics , 1960 .

[77]  J. Scurlock,et al.  Miscanthus : European experience with a novel energy crop , 2000 .