Experimental characterization of contact angle and surface energy on aramid fibers

Journal of Adhesion Science and Technology

Volumn 27, Issue 9, 2013, Pages 1012-1022

  Hao, Wenfeng ^a   Yao, Xuefeng ^a   Ke, Yuchao ^a   Ma, Yinji ^a   Li, Faxin ^b  

^a TSINGHUA UNIVERSITY   (China)

^b PEKING UNIVERSITY   (China)

Author keywords

aramid fiber; contact angle; liquid droplet; surface energy; surface treatment

Indexed keywords

ENERGY COMPONENTS; EXPERIMENTAL CHARACTERIZATION; FIBER-REINFORCED COMPOSITE; INTERFACIAL STRENGTH; LIQUID DROPLET METHOD; LIQUID DROPLETS; MATRIX RESIN;

CONTACT ANGLE; INTERFACIAL ENERGY; SURFACE TREATMENT; TEXTILE FIBERS;

ARAMID FIBERS;

EID: 84876386710     PISSN: 01694243     EISSN: 15685616     Source Type: Journal    
DOI: 10.1080/01694243.2012.727172     Document Type: Article

References (30)

1. Goren SL. Shape of thread of liquid undergoing break-up. Journal of Colloid Science. 1964;19:81.
2. Yamaki JI, Katayama Y. New method of determining contact angle between monofilament and liquid. Journal of Applied Polymer Science. 1975;19:2897-909.
3. Carroll BJ. The accurate measurement of contact angle, phase contact areas, drop volume, and Laplace excess pressure in drop-on-fiber systems. Journal of Colloid and Interface Science. 1976;57:488-95.
4. Song BH, Springer J. Determination of interfacial tension from the profile of a pendant drop using computer-aided image processing. 1. Theoretical. Journal of Colloid and Interface Science. 1996;184:64-76.
5. Song BH, Springer J. Determination of interfacial tension from the profile of a pendant drop using computer-aided image processing. 2. Experimental. Journal of Colloid and Interface Science. 1996;184:77-91.
6. Song BH, Bismarck A, Tahhan R, Springer J. A generalized drop length-height method for determination of contact angle in drop-on-fiber systems. Journal of Colloid and Interface Science. 1998;197:68-77.
7. Hsieh YL, Yu BL. Liquid wetting, transport, and retention properties of fibrous assemblies. 1. Water wetting properties of woven fabrics and their constituent single fibers. Textile Research Journal. 1992;62:677-85.
8. Hsieh YL, Yu BL, Hartzell MM. Liquid wetting, transport, and retention properties of fibrous assemblies. 2. Water wetting and retention of 100-percent and blended woven fabrics. Textile Research Journal. 1992;62:697-704.
9. Liu L, Huang YD, Zhang ZQ, Jiang ZX, Wu LN. Ultrasonic treatment of aramid fiber surface and its effect on the interface of aramid/epoxy composites. Applied Surface Science. 2008;254:2594-9.
10. Jia C, Chen P, Liu W, Li B, Wang Q. Surface treatment of aramid fiber by air dielectric barrier discharge plasma at atmospheric pressure. Applied Surface Science. 2011;257:4165-70.
11. Kurniawan D, Kim BS, Lee HY, Lim JY. Atmospheric pressure glow discharge plasma polymerization for surface treatment on sized basalt fiber/polylactic acid composites. Composites Part B: Engineering. 2012;43:1010-4.
12. Zhang S, He G, Liang G, Cui H, Zhang W, Wang B. Comparison of F-12 aramid fiber with domestic armid fiber III on surface feature. Applied Surface Science. 2010;256:2104-9.
13. Miller B, Muri P, Rebenfeld L. A microbond method for determination of the shear-strength of a fiber-resin interface. Composites Science and Technology. 1987;28:17-32.
14. Gaur U, Miller B. Microbond method for determination of the shear-strength of a fiber resin interface-evaluation of experimental parameters. Composites Science and Technology. 1989;34:35-51.
15. Hodzic A, Kalyanasundaram S, Lowe A, Stachurski ZH. The microdroplet test: experimental and finite element analysis of the dependance of failure mode on droplet shape. Composite Interfaces. 1999;6:375-89.
16. Valadez-Gonzalez A, Cervantes-Uc JM, Olayo R, Herrera-Franco PJ. Effect of fiber surface treatment on the fiber-matrix bond strength of natural fiber reinforced composites. Composites Part B: Engineering. 1999;30:309-20.
17. Li J, Sun FF. The effect of maleic anhydride graft on the interfacial adhesion of carbon fiber reinforced thermoplastic polystyrene composite. Journal of Composite Materials. 2009;43:2717-25.
18. Chou CT, Miller B. Liquid/fiber and solidified-liquid/fiber contact angles compared. Journal of Adhesion. 1998;65:81-90.
19. Hodzic A, Stachurski ZH. Droplet on a fibre: surface tension and geometry. Composite Interfaces. 2001;8:415-25.
20. Good RJ. Contact-angle, wetting, and adhesion-a critical-review. Journal of Adhesion Science and Technology. 1993;7:1015.
21. Fowkes FM. Contact angle, wettability and adhesion. Washington (DC): American Chemical Society; 1964. p. 99.
22. Vanoss CJ. Acid-base interfacial interactions in aqueous-media. Colloid Surface A. 1993;78:1-49.
23. Gassan J, Gutowski VS, Bledzki AK. About the surface characteristics of natural fibres. Macromolecular Materials and Engineering. 2000;283:132-9.
24. Luber P, Toussaint AF. The wetting properties of hydrophobically modified cellulose surface. In: Proceedings of the 10th Cellulose Conference; 1988; New York. p. 1515-30.
25. Le CV, Ly NG, Stevens MG. Measuring the contact angles of liquid droplets on wool fibers and determining surface energy components. Textile Research Journal. 1996;66:389-97.
26. Sprang N, Theirich D, Engemann J. Plasma and ion beam surface treatment of polyethylene. Surface and Coatings Technology. 1995;74-75:689-95.
27. Sinha E, Panigrahi S. Effect of plasma treatment on structure, wettability of jute fiber and flexural strength of its composite. Journal of Composite Materials. 2009;43:1791-802.
28. Chen P, Zhang C, Zhang X, Wang B, Li W, Lei Q. Effects of oxygen plasma treatment power on surface properties of poly(p-phenylene benzobisoxazole) fibers. Applied Surface Science. 2008;255:3153-8.
29. Xu Z, Chen L, Huang Y, Li J, Wu X, Li X. Wettability of carbon fibers modified by acrylic acid and interface properties of carbon fiber/epoxy. European Polymer Journal. 2008;44:494-503.
30. Berim GO, Ruckenstein E. Cylindrical droplet on nanofibers: a step toward the clam-shell drop description. Journal of Physical Chemistry B. 2005;109:12515-24.