http://imechanica.org/node/3159 Comments for "Poroelastic nanoindentation analysis" en http://imechanica.org/node/3159 <p> Just published in this month&#39;s Journal of Materials Research--a study on poroelastic nanoindentation characterization for hydrated bone samples.&nbsp; Poroelastic problems are notoriously difficult to incorporate into routine materials characterization due to the paucity of problems with closed-form solutions.&nbsp; However, in some cases, a master-curve does exist and parameter identification can be accomplished without requiring inverse finite element analysis and optimization for every condition.&nbsp; The abstract follows, linked from <a href="http://www.mrs.org/s_mrs/sec_subscribe.asp?CID=13819&amp;DID=210198&amp;action=detail" target="_blank">here</a> . </p> <p> Poroelastic nanoindentation responses of hydrated bone, J. Mater. Res. 23 (2008) 1307. </p> <p> Indentation techniques are used for the measurement of mechanical<br /> properties of a wide range of materials. Typical elastic analysis for<br /> spherical indentation is applicable in the absence of time-dependent<br /> deformation, but is inappropriate for materials with time-dependent<br /> creep responses active in the experimental time frame. In the current<br /> work, a poroelastic analysis&mdash;a mechanical theory incorporating fluid<br /> motion through a porous elastic network&mdash;is used to examine spherical<br /> indentation creep responses of hydrated biological materials. Existing<br /> analytical and finite element solutions for the poroelastic Hertzian<br /> indentation problem are reviewed, and a poroelastic parameter<br /> identification scheme is developed. Experimental data from<br /> nanoindentation of hydrated bone immersed in water and polar solvents<br /> (ethanol, methanol, acetone) are examined within the poroelastic<br /> framework. Immersion of bone in polar solvents with decreasing polarity<br /> results in increased stiffness, decreased Poisson&rsquo;s ratio, and<br /> decreased hydraulic permeability. Nanoindentation poroelastic analysis<br /> results are compared with existing literature for bone poroelasticity<br /> at larger length scales, and the effective pore size probed in<br /> indentation creep experiments was estimated to be 1.6 nm, consistent<br /> with the scale of fundamental collagen&ndash;apatite interactions. Results<br /> for water permeability in bone were compared with studies of water<br /> diffusion through fully dense bone. </p> <br class="clear" /> http://imechanica.org/node/3159#comments research biomechanics bone hydration poroelasticity Viscoelastic Tue, 06 May 2008 10:46:10 -0400 MichelleLOyen 3159 at http://imechanica.org