QUASI-STATIC TORSIONAL DEFORMATION OF SINGLE HAIR FIBERS 395 (8) J. A. Swift, The cuticle controls bending stiffness of hair, J. Cosmet. Sci, 51, 37–38 (2000). (9) F. I. Bell and S. Watson, Analytical modelling of the mechanical properties of single hair fi bres, 11th International Wool Conference, Sept 4-9, Leeds, 2005. (10) S. B. Warner, Fibre Science (Prentice Hall, Upper Saddle River, NJ, 1995), pp. 150–155. (11) J. M Gere, Mechanics of Materials, 6th Ed. (Thomson Brooks/Cole, Belmont, USA, 2004). (12) D. Persaud and Y. K. Kamath, Torsional method for evaluating hair damage and performance of hair care ingredients, J. Cosmet. Sci., 55(Suppl.), S65–S77 (2004). (13) Y. Masaaki, S. Atsushi, and A. Noda, Physical properties of human hair 2 evaluation of human hair torsional stress and a mechanism of bending and torsional stress, J. Soc. Cosmet. Chem. Japan, 36, 262–272 (2002). (14) D. L Harper and Y. K Kamath, The effect of treatments on the shear modulus of human hair measured by single fi bre torsion pendulum, J. Cosmet. Sci., 58, 329–337 (2007). (15) J. B. Speakman, The rigidity of wool and it’s change with adsorption of water vapour, Trans. Faraday Soc., 25, 92–103 (1929). (16) A. C. Goodings, A method for the measurement of the rigidity of fi bres immersed in liquids: the torsion double pendulum, Text. Res. J., 45, 123–129 (1968). (17) R. Meredith, The torsional rigidity of textile fi bres, J. Textile Inst. Trans., 45, T489–T503 (1954). (18) P. Nordon, Some torsional properties of wool, Text. Res. J., 32, 560–568 (1962). (19) T. W. Mitchell and M. Feughelman, The torsional properties of single wool fi bres part I: torque twist relationships and torsional relaxation of wet and dry fi bres, Text. Res. J., 30, 662–667 (1960). (20) L. J. Wolfam and L. Albrecht, Torsional behavior of human hair, J. Soc. Cosmet. Chem., 36, 87–99 (1985). (21) S. B. Ruetsch, Y. K. Kamath, and H. D Weigmann, The role of cationic compounds in the reinforce- ment of the cuticula, J. Cosmet. Sci., 54, 63–83 (2003). (22) H. Bogarty, Torsional properties of hair in relation to permanent waving and setting, J. Soc. Cosmet. Chem., 18, 575–589 (1967). (23) F.-J. Wortmann, G. Wortmann, H.-M. Haake, and W. Eisfeld, Analysis of the torsional modulus of hu- man hair and its relation to hair morphology and cosmetic processing, J. Cosmet. Sci., 65, 59–68 (2014). (24) L. J. Wolfram and M. K. Lindermann, Some observations on the hair cuticle, J. Soc. Cosmet. Chem., 22, 839–850 (1971). (25) M. M. Breuer, The binding of small molecules of hair I. The hydration of hair and the effect of water on the mechanical properties of hair, J. Soc. Cosmet. Chem., 23, 447–470 (1970). (26) P. Zuidema, L. E. Govaert, F. P. Baaijens, P. A. Ackermans, and S. Asvadi, The infl uence of humidity on the viscoelastic behavior of human hair, Biorheology, 40, 431–439 (2003). (27) M. Feughelman and M. S. Robinson, The relationship between some mechanical properties of single wool fi bres and relative humidity, Text. Res. J., 37, 441–446 (1967). (28) M. Feughelman, A two-phase structure for keratin fi bres, Text. Res. J., 29, 223–228 (1959). (29) C. R. Robbins, Chemical and Physical Behavior of Human Hair, 5th Ed. (Springer, Berlin, Germany 2012), pp. 570–571. (30) H. Zahn, Chemische vorgange bein bleichen von wolle und menschenhaar mit wassertroffperoxid und peroxysauren, J. Soc. Cosmet. Chem., 17, 687–701 (1966).
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