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Multiscale wood micromechanics and size effects study via nanoindentation
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作者 Yuri I.Golovin Alexander A.Gusev +6 位作者 dmitry yu.golovin Sergey M.Matveev Alexander I.Tyrin Alexander A.Samodurov Viktor V.Korenkov Inna A.Vasyukova Maria A.Yunack 《Journal of Bioresources and Bioproducts》 EI CSCD 2023年第3期246-264,共19页
Wood as a material is a natural composite with a complex hierarchically arranged structure.All scale levels of wood structure contribute to its macroscopic mechanical properties.The nature of such characteristics and ... Wood as a material is a natural composite with a complex hierarchically arranged structure.All scale levels of wood structure contribute to its macroscopic mechanical properties.The nature of such characteristics and deformation modes differs radically at different scale levels.Wood macroscopic properties are well studied,and the relevant information can be easily found in the literature.However,the knowledge of the deformation mechanisms at the mesoscopic level corresponding to the cellular structure of early and late wood layers of annual growth rings is insufficient.It hinders building the comprehensive multiscale model of how wood mechanical properties are formed.This paper described the results of scanning of mechanical properties of softwood and hardwood samples,such as common pine,small-leaf lime,and pedunculate oak,by means of nanoindentation(NI).The NI technique allows varying the size of deformed region within a wide range by altering maximal load(P max)applied to the indenter so that one can re-peatedly and non-destructively test wood structural components at different scale levels on the same sample without changing the technique or equipment.It was discovered that the effective microhardness(H eff)and Young’s modulus(E eff)decreased manifold with P max growing from 0.2 to 2000 mN.This drop in H effwas observed when the locally deformed region grew,and re-sulting from P max increase generally follows the rule similar to the Hall-Petch relation for yield stress,strength,and hardness initially established for metals and alloys,though obviously in those cases the underlying internal mechanisms are quite different.The nature and micromechanisms of such size effect(SE)in wood revealed using NI were discussed in this study.At P max<0.2 mN,the deformed area under the pyramidal Berckovich indenter was much smaller than the cell wall width.Hence,in this case,NI measured the internal mechanical properties of the cell wall material as long as free boundaries impact could be neglected.At P max>200 mN,the indentation encompassed several cells.The measured mechanical properties were significantly affected by bending deformation and buckling collapse of cell walls,reducing H effand E effsubstantially.At P max≈1-100 mN,an indenter interacted with different elements of the cell structure and capillary network,resulting in intermediate values of H effand E eff.Abrupt changes in H effand E effat annual growth ring boundaries allow accurate measuring of rings width,while smoother and less pronounced changes within the rings allow identification of earlywood and latewood layers as well as any finer changes during vegetation season.The values of ring width measured using NI and standard optical method coincide with 2%−3%accuracy.The approaches and results pre-sented in this study could improve the understanding of nature and mechanisms lying behind the micromechanical properties of wood,help to optimize the technologies of wood farming,subse-quent reinforcement,and utilization,as well as to develop new highly informative techniques in dendrochronology and dendroclimatology. 展开更多
关键词 Nano/microhardness Scanning nanoindentation Annual growth ring Early and late wood Dendrochronology
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