Experimental study on the mechanical properties of the horn sheaths from cattle
暂无分享,去创建一个
W. Guo | Sicong Shan | H. Zhao | X. Q. Feng | B. W. Li | H. P. Zhao | W. W. Guo | S. C. Shan | Bing-Wei Li | X. Feng | S. Shan | B. Li | H. Zhao | Xiangyu Feng | W. W. Guo
[1] Michael F. Ashby,et al. Chapter 4 – Material Property Charts , 2011 .
[2] J. B. Speakman,et al. Plasticity of Wool , 1953, Nature.
[3] C. Clark,et al. Fracture toughness of bovine claw horn from cattle with and without vertical fissures. , 2007, Veterinary journal.
[4] J. Hearle. A critical review of the structural mechanics of wool and hair fibres. , 2000, International journal of biological macromolecules.
[5] H. Tattersall,et al. The work of fracture and its measurement in metals, ceramics and other materials , 1966 .
[6] C. Chuong,et al. Evo-Devo of amniote integuments and appendages. , 2004, The International journal of developmental biology.
[7] M. Feughelman,et al. Some Mechanical Properties of Wool Fibers in the "Hookean" Region from Zero to 100% Relative Humidity , 1971 .
[8] K. Otagaki,et al. Estimation of Empty Body Weight of Beef Cattle , 1962 .
[9] R. Bonser,et al. Young's modulus varies with differential orientation of keratin in feathers. , 2003, Journal of structural biology.
[10] H. Baden. The physical properties of nail. , 1970, The Journal of investigative dermatology.
[11] Julian F. V. Vincent,et al. Composite theory and the effect of water on the stiffness of horn keratin , 1987 .
[12] Michael F. Ashby,et al. The mechanical efficiency of natural materials , 2004 .
[13] J. Barton,et al. A remarkably strong natural glassy rod: the anchoring spicule of theMonorhaphis sponge , 1989 .
[14] A. Kitchener. Effect of water on the linear viscoelasticity of horn sheath keratin , 1987 .
[15] T. Z. Rizvi,et al. Temperature-dependent dielectric properties of slightly hydrated horn keratin. , 2008, International journal of biological macromolecules.
[16] S. Acatincăi,et al. Social behaviour in cattle. , 2010 .
[17] J. Bertram,et al. Functional design of horse hoof keratin: the modulation of mechanical properties through hydration effects. , 1987, The Journal of experimental biology.
[18] Andrew C. Kitchener,et al. Fracture toughness of horns and a reinterpretation of the horning behaviour of bovids , 1987 .
[19] T. Huang,et al. Analysis of α-keratins in the horns of rhinoceros and buffalo by non-native capillary isoelectric focusing , 1997 .
[20] R. Latham,et al. Stiffness as a function of moisture content in natural materials:Characterisation of hoof horn samples , 1998 .
[21] G. King. Permeability of keratin membranes to water vapour , 1945 .
[22] Horacio Dante Espinosa,et al. An Experimental Investigation of Deformation and Fracture of Nacre–Mother of Pearl , 2007 .
[23] Michael F. Ashby,et al. The mechanical properties of natural materials. I. Material property charts , 1995, Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences.
[24] V. Geist. The Evolution of Horn-Like Organs , 1966 .
[25] A. Boyde,et al. Structure and mineralisation density of antler and pedicle bone in red deer (Cervus elaphus L.) exposed to different levels of environmental fluoride: a quantitative backscattered electron imaging study , 2000, Journal of anatomy.
[26] L. Witmer,et al. Structure of white rhinoceros (Ceratotherium simum) horn investigated by X‐ray computed tomography and histology with implications for growth and external form , 2006, Journal of morphology.
[27] J. Gosline,et al. The mechanical design of spider silks: from fibroin sequence to mechanical function. , 1999, The Journal of experimental biology.
[28] Yasuaki Seki,et al. Biological materials: Structure and mechanical properties , 2008 .
[29] Richard H. C. Bonser,et al. The Young's modulus of ostrich claw keratin , 2000 .
[30] A. P. Jackson,et al. The mechanical design of nacre , 1988, Proceedings of the Royal Society of London. Series B. Biological Sciences.
[31] K. Vecchio,et al. Mechanical properties and structure of Strombus gigas, Tridacna gigas, and Haliotis rufescens sea shells: A comparative study , 2006 .
[32] J. Aizenberg,et al. Skeleton of Euplectella sp.: Structural Hierarchy from the Nanoscale to the Macroscale , 2005, Science.
[33] Bharat Bhushan,et al. Nanomechanical characterization of human hair using nanoindentation and SEM. , 2005, Ultramicroscopy.
[34] A. Kitchener. An analysis of the forces of fighting of the blackbuck (Antilope cervicapra) and the bighorn sheep (Ovis canadensis) and the mechanical design of the horn of bovids , 1988 .
[35] Himadri S. Gupta,et al. Tough Lessons From Bone: Extreme Mechanical Anisotropy at the Mesoscale , 2008 .
[36] J. Thomason,et al. The modulus of elasticity of equine hoof wall: implications for the mechanical function of the hoof. , 1996, The Journal of experimental biology.
[37] A. R. Ennos,et al. Tensile and shear properties of fingernails as a function of a changing humidity environment. , 2009, Journal of biomechanics.
[38] C. Phillips,et al. The locomotion of dairy cows on floor surfaces with different frictional properties. , 2001, Journal of dairy science.
[39] E. Gaino,et al. Biomimetic model of a sponge-spicular optical fiber—mechanical properties and structure , 2001 .
[40] Mehmet Sarikaya,et al. Mechanical Property-Microstructural Relationships in Abalone Shell , 1989 .
[41] R O Ritchie,et al. Effect of orientation on the in vitro fracture toughness of dentin: the role of toughening mechanisms. , 2003, Biomaterials.
[42] D. Parry. Hard alpha-keratin intermediate filaments: an alternative interpretation of the low-angle equatorial X-ray diffraction pattern, and the axial disposition of putative disulphide bonds in the intra- and inter-protofilamentous networks. , 1996, International journal of biological macromolecules.
[43] Yasuaki Seki,et al. Structure and mechanical behavior of a toucan beak , 2005 .
[44] J. Bertram,et al. Fracture toughness design in horse hoof keratin. , 1986, The Journal of experimental biology.
[45] J. Gosline,et al. Molecular design of the α–keratin composite: insights from a matrix–free model, hagfish slime threads , 2004, Proceedings of the Royal Society of London. Series B: Biological Sciences.
[46] M. Kasapi,et al. Micromechanics of the equine hoof wall: optimizing crack control and material stiffness through modulation of the properties of keratin. , 1999, The Journal of experimental biology.
[47] H. Maeda. Water in keratin. Piezoelectric, dielectric, and elastic experiments. , 1989, Biophysical journal.
[48] Laurent Kreplak,et al. Biomechanical properties of intermediate filaments: from tissues to single filaments and back , 2007, BioEssays : news and reviews in molecular, cellular and developmental biology.
[49] D. Parry,et al. Intermediate filaments in alpha-keratins. , 1986, Proceedings of the National Academy of Sciences of the United States of America.
[50] J. W. Farrent,et al. The influence of hydration on the tensile and compressive properties of avian keratinous tissues , 2004 .
[51] D. Arola,et al. A method for characterizing the mechanical behaviour of hoof horn , 2007 .
[52] H. Höcker,et al. Hair--the most sophisticated biological composite material. , 2007, Chemical Society reviews.
[53] N. Belie,et al. Biomechanical Properties of Bovine Claw Horn , 2006 .