Cellulose microfibril angle in the cell wall of wood fibres.
about
Genetically engineered trees for plantation forests: key considerations for environmental risk assessmentNew Insights on Wood Dimensional Stability Influenced by Secondary Metabolites: The Case of a Fast-Growing Tropical Species Bagassa guianensis AublCellulose synthesis and its regulationTranscriptome profiling of Pinus radiata juvenile wood with contrasting stiffness identifies putative candidate genes involved in microfibril orientation and cell wall mechanicsCellulose microfibril orientation of Picea abies and its variability at the micron-level determined by Raman imaging.Characterization of cellulose synthase complexes in Populus xylem differentiation.Plasticity, elasticity, and adhesion energy of plant cell walls: nanometrology of lignin loss using atomic force microscopy.Sugarcane cell wall structure and lignin distribution investigated by confocal and electron microscopy.Characterization and expression analysis of a fiber differentially expressed Fasciclin-like arabinogalactan protein gene in Sea Island cotton fibersThe evolutionary fate of phenotypic plasticity and functional traits under domestication in manioc: changes in stem biomechanics and the appearance of stem brittleness.Capturing spiral radial growth of conifers using the superellipse to model tree-ring geometric shape.Comparative structure and biomechanics of plant primary and secondary cell walls.Out-of-plane orientation of cellulose elementary fibrils on spruce tracheid wall based on imaging with high-resolution transmission electron microscopy.Non-invasive imaging of cellulose microfibril orientation within plant cell walls by polarized Raman microspectroscopy.A Review on Grafting of Biofibers for Biocomposites.The fasciclin-like arabinogalactan protein family of Eucalyptus grandis contains members that impact wood biology and biomechanics.Stem-righting mechanism in gymnosperm trees deduced from limitations in compression wood development.Calcite crystal growth by a solid-state transformation of stabilized amorphous calcium carbonate nanospheres in a hydrogel.The dynamic pipeline: hydraulic capacitance and xylem hydraulic safety in four tall conifer species.Wood-Based Nanotechnologies toward Sustainability.Functional Specialization of Cellulose Synthase Isoforms in a Moss Shows Parallels with Seed Plants.Rotational 3D printing of damage-tolerant composites with programmable mechanics.Pontamine fast scarlet 4B bifluorescence and measurements of cellulose microfibril angles.Anisotropic, Transparent Films with Aligned Cellulose Nanofibers.Probing crystal structure and mesoscale assembly of cellulose microfibrils in plant cell walls, tunicate tests, and bacterial films using vibrational sum frequency generation (SFG) spectroscopy.Exploring new strategies for cellulosic biofuels productionTop ten fundamental challenges of biomass pyrolysis for biofuelsMultivariate unmixing approaches on Raman images of plant cell walls: new insights or overinterpretation of results?Vibrational sum-frequency-generation (SFG) spectroscopy study of the structural assembly of cellulose microfibrils in reaction woodsFTIR Measurement of Cellulose Microfibril Angle in Historic Scots Pine Wood and Its Use to Detect Fungal DecayThe tensile behavior of off-axis loaded plant fiber composites: An insight on the nonlinear stress-strain responseUltrastructural features affecting mechanical properties of wood fibresModelling microfibril angle variation in New Zealand-grown radiata pineIsolation and handedness of helical coiled cellulosic thickenings from plant petiole tracheary elements
P2860
Q27005696-9D23FAA9-57F5-4E07-8CDB-46D068330EA1Q28550970-C0F74F60-1A58-406E-8325-2C4EE9E0ACABQ28660545-C4A946EA-E2A1-4D3C-8DAB-512CB78F104FQ30472761-FD7D257A-0F23-4A32-8D50-A009743D47DAQ33518238-A8351672-E588-4A2B-B34A-74E59F4D8479Q33603560-E50CECEB-FCBA-4E3A-8A5A-42CE7638C23AQ33670132-C6CFB1A5-D6B9-42A4-A4D8-AFA1C3F7A309Q34754919-139642B8-9F72-46D4-9223-AD8237B970BCQ34854884-D0715C44-4748-4196-8225-EFDCA53DEC99Q34984751-96E218D4-98B3-48F2-BC99-03BAAC4F2708Q36162480-565DFF80-DEBB-410B-A0FF-71C214ED8A4AQ39560391-5666991D-ACFD-4C72-8A1F-BF1B173A387EQ40203075-EBFFCEC5-5F21-4C82-8D78-5457F6DA2178Q40773482-05362D54-49FE-4560-A4B8-6D1781F203BDQ40967737-2127ECF1-F13D-4444-B676-DA7CA575D96CQ41444321-0A5F3E28-85F3-4D4C-9E77-5BAB1A0084D8Q41862932-57788F39-6C3B-41FA-A7A4-52F4B8D61A18Q45684982-BA56164D-38D1-45ED-88CB-A2DED8C0B760Q46965506-19B742B5-9244-41AA-B6D2-E93A9B54265EQ47283762-BB535EC4-4294-40CE-882C-2DC45EFD84C4Q47851786-B732655F-E693-4CD9-B5EC-45A3EDBA8CB9Q48216647-C26DA4B7-58EA-48C9-AB3D-AA9D3C2BA49FQ48217205-1D399AA6-9D45-410F-8661-2CEBF87CE47BQ50204692-1DEECF4D-BB77-47DC-B7AD-B86EC43FC713Q53284979-71A503BF-8493-4802-9F28-53017E5C6FF6Q55898045-53534E0E-040F-4732-BDE0-A1C7AFBF7559Q56040878-4EECD3A4-012B-485D-95E1-1E6DB5DDEC18Q57140970-35C30989-55BA-4691-9070-96E9AF5EC17CQ57441621-2939BA01-23F4-4C3D-8E35-04257D1A13C3Q58526248-5B62F1F1-E2AD-4F21-B374-E38DAFE23D53Q58642103-C6AE0803-6BD3-41BE-9AEC-E69066C61DAFQ58952255-88A6FBAA-94CC-4E1B-A1F3-45F94E8284DFQ59320307-61966E57-11BC-4D2A-87E6-3D88D0735727Q59323071-7FEC51DC-7C32-4E7D-9FA5-3CECC0B86D94
P2860
Cellulose microfibril angle in the cell wall of wood fibres.
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Cellulose microfibril angle in the cell wall of wood fibres.
@ast
Cellulose microfibril angle in the cell wall of wood fibres.
@en
type
label
Cellulose microfibril angle in the cell wall of wood fibres.
@ast
Cellulose microfibril angle in the cell wall of wood fibres.
@en
prefLabel
Cellulose microfibril angle in the cell wall of wood fibres.
@ast
Cellulose microfibril angle in the cell wall of wood fibres.
@en
P1433
P1476
Cellulose microfibril angle in the cell wall of wood fibres.
@en
P2093
J R Barnett
Victoria A Bonham
P304
P356
10.1017/S1464793103006377
P577
2004-05-01T00:00:00Z