Selection of optimal conversion path for willow biomass assisted by near infrared spectroscopy
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Jakub Sandak | Anna Sandak | B Waliszewska | J. Sandak | Anna Sandak | M. Mleczek | B. Waliszewska | Mirosław Mleczek | Magdalena Zborowska | M. Zborowska
[1] N. Rascio,et al. Heavy metal hyperaccumulating plants: how and why do they do it? And what makes them so interesting? , 2011, Plant science : an international journal of experimental plant biology.
[2] Jakub Sandak,et al. Solid state NMR and IR characterization of wood polymer structure in relation to tree provenance. , 2015, Carbohydrate polymers.
[3] K. Novotná,et al. Biomass production of Populus nigra L. clones grown in short rotation coppice systems in three different environments over four rotations. , 2014 .
[4] Michelle J. Serapiglia,et al. Yield and Woody Biomass Traits of Novel Shrub Willow Hybrids at Two Contrasting Sites , 2012, BioEnergy Research.
[5] Angela Karp,et al. Genetic strategies for dissecting complex traits in biomass willows (Salix spp.). , 2014, Tree physiology.
[6] M. Stolarski,et al. Willow biomass as feedstock for an integrated multi-product biorefinery , 2014 .
[7] C. Patrick Doncaster,et al. Potential benefits of commercial willow Short Rotation Coppice (SRC) for farm-scale plant and invertebrate communities in the agri-environment , 2011 .
[8] Laigeng Li,et al. Rapid characterization of woody biomass digestibility and chemical composition using near-infrared spectroscopy. , 2011, Journal of integrative plant biology.
[9] M. J. Effland. Modified procedure to determine acid-insoluble lignin in wood and pulp. , 1977 .
[10] I. Pulford,et al. Phytoremediation of heavy metal-contaminated land by trees--a review. , 2003, Environment international.
[11] J. Sandak,et al. Differences in wood properties of Picea abies L. Karst. in relation to site of provenance and population genetics , 2015 .
[12] Hans Hartmann,et al. Moisture content determination in solid biofuels by dielectric , 2006 .
[13] Nick Scott,et al. The potential benefits , 2012 .
[14] J. Sandak,et al. Fourier Transform near Infrared Assessment of Biomass Composition of Shrub Willow Clones (Salix sp.) for Optimal Bio-Conversion Processing , 2011 .
[15] R. Tognetti,et al. Shaping the multifunctional tree: the use of Salicaceae in environmental restoration , 2013 .
[16] M. R. Ravi,et al. Modelling of Pyrolysis in Wood: A Review , 2004 .
[17] Ian Shield,et al. Genetic improvement of willow for bioenergy and biofuels. , 2011, Journal of integrative plant biology.
[18] M. Manley. Near-infrared spectroscopy and hyperspectral imaging: non-destructive analysis of biological materials. , 2014, Chemical Society reviews.
[19] M. Stolarski,et al. Productivity of willow coppice plants grown in short rotations. , 2018 .
[20] John L. Field,et al. Biomass for thermochemical conversion: targets and challenges , 2013, Front. Plant Sci..
[21] Kevin McDonnell,et al. Prediction of biomass gross calorific values using visible and near infrared spectroscopy , 2012 .
[22] Mark F. Davis,et al. Rapid analysis of the chemical composition of agricultural fibers using near infrared spectroscopy and pyrolysis molecular beam mass spectrometry , 2004 .
[23] Fred E. Gouker,et al. Ploidy Level Affects Important Biomass Traits of Novel Shrub Willow (Salix) Hybrids , 2014, BioEnergy Research.
[24] Shahab Sokhansanj,et al. Fast classification and compositional analysis of cornstover fractions using Fourier transform near-infrared techniques. , 2008, Bioresource technology.