Properties of wool                                                101

           R€ omer G, Berendt H-U, Fierz H, Lauton A: Reaction behaviour of wool protective agents during
               HT dyeing of wool and polyester/wool blends, Textilveredlung 15:465e472, 1980.
           Ross DA: Wool crimping, Appl Polym Symp 18:1455e1466, 1971.
           Sasser PE, Shofner FM, Chu YT, Shofner CK, Townes MG: Interpretations of single fibre,
               bundle and yarn tenacity data, Text Res J 61:681e690, 1991.
           Schlink AC, Peterson A, Huson MG, Thompson AN: Components of staple strength. In AAAP-
               ASAP year 2000 international congress, Sydney, July 2000.
           Schmidt A, Bach E, Schollmeyer E: Damage to natural and synthetic fibers treated in super-
               critical carbon dioxide at 300 bar and temperatures up to 160 C, Text Res J 72:1023e1032,

               2002. https://doi.org/10.1177/004051750207201115.
           Schmidt H, Wortmann F-J: High-pressure differential scanning calorimetry and wet bundle
               tensile-strength of weathered wool, Text Res J 64:690e695, 1994.
           Shah SMA, Whiteley KJ: Variations in the stress-strain properties of wool fibres, J Text Inst 57:
               T286eT293, 1966.
           Shahid M, Mohammad F, Chen G, Tang R-C, Xing T: Enzymatic processing of natural fibres:
               white biotechnology for sustainable development, Green Chem 18:2256e2281, 2016.
               https://doi.org/10.1039/c6gc00201c.
           Shorter SA: An investigation of the nature of the elasticity of fibres, J Text Inst 15:T207eT229,
               1924.
           Simpson WS: Physics and chemistry of wool yellowing. In WRONZ report R217, Christchurch,
               1999, Wool Research Organisation of New Zealand (WRONZ), pp 7e12.
           Smith GJ, Miller IJ, Daniels V: Phototendering of wool sensitized by naturally occurring
               polyphenolic dyes, J Photochem Photobiol A Chem 169:147e152, 2005.
           Speakman JB: The intracellular structure of the wool fibre, J Text Inst 18:T431eT453, 1927.
           Speakman JB, Hirst MC: The constitution of the keratin molecule, Trans Faraday Soc 29:
               148e165, 1933. https://doi.org/10.1039/TF9332900148.
           Speakman JB, Cooper CA: The adsorption of water by wool, part 1 e adsorption hysteresis,
               J Text Inst 27:T183eT185, 1936.
           Stana K, Ivana S, Brnada S: Changes in properties of wool fibres and yarns through the phases of
               the process of spinning and weaving in different weaves, Tekstil ve Konfeksiyon 25(2):
               148e152, 2015.
           Stani  c V, Bettini J, Montoro FE, Stein A, Evans-Lutterodt K: Local structure of human hair
               spatially resolved by sub-micron X-ray beam, Sci Rep 5:17347, 2015. https://doi.org/10.
               1038/srep17347.
           Sweetman BJ: The hydrothermal degradation of wool keratin part I: chemical changes associ-

               ated with the treatment of wool keratin with water at 50-100 C, Text Res J 37:834e844,
               1967a.
           Sweetman BJ: The hydrothermal degradation of wool keratin part II: chemical changes asso-
               ciated with the treatment of wool with water or steam at temperatures above 100 C, Text

               Res J 37:844e851, 1967b.
           Swift JA: The cuticle controls bending stiffness of hair, J Cosmet Sci 51:37e38, 2000.
           TEAM: Report on trials evaluating additional measurements, 1981e1988, to the raw wool
               measurement advisory committee of the Australian wool corporation, Melbourne, 1988,
               Australian Wool Corporation.
           Tester DH: Fracture planes of fibers from Martindale abraded wool fabrics, Text Res J 54:
               75e76, 1984.
           Thompson AN: Intrinsic strength of Merino wool fibres (Ph.D.). Adelaide, 1998, University of
               Adelaide.