Effects of the degree of crosslinking and test rate on the tensile properties of a crosslinked polyacrylic pressure-sensitive adhesive and vulcanized rubber
暂无分享,去创建一个
Shigeki Hikasa | Yoshinobu Nakamura | Satoshi Makuta | Y. Urahama | Satoshi Makuta | Syuji Fujii | S. Fujii | Yusuke Kashihara | Shun Okada | Yoshiaki Urahama | Kazuko Fujiwara | Kazuko Fujiwara | Yusuke Kashihara | S. Hikasa | Shun Okada | Y. Nakamura
[1] F. Bueche. The Tensile Strength of Elastomers According to Current Theories , 1959 .
[2] Y. Urahama,et al. Effects of the compatibility of a polyacrylic block copolymer/tackifier blend on the phase structure and tack of a pressure‐sensitive adhesive , 2012 .
[3] M. Madani,et al. Influence of thermal aging on crosslinking density of boron carbide/natural rubber composites , 2003 .
[4] A. Khokhlov,et al. Study of the Mechanisms of Filler Reinforcement in Elastomer Nanocomposites , 2014 .
[5] Z. Jia,et al. Preparation of Halloysite Nanotubes–Silica Hybrid Supported Vulcanization Accelerator for Enhancing Interfacial and Mechanical Strength of Rubber Composites , 2017 .
[6] Y. Urahama,et al. Tack and viscoelastic properties of an acrylic block copolymer/tackifier system , 2009 .
[7] P. Flory. Statistical Mechanics of Swelling of Network Structures , 1950 .
[8] Zhaoxia Jin,et al. Tough, Swelling-Resistant, Self-Healing, and Adhesive Dual-Cross-Linked Hydrogels Based on Polymer–Tannic Acid Multiple Hydrogen Bonds , 2018 .
[9] Liqun Zhang,et al. Interface Engineering toward Promoting Silanization by Ionic Liquid for High-Performance Rubber/Silica Composites , 2015 .
[10] Chuanhui Xu,et al. Fabrication of High Performance Magnetic Rubber from NBR and Fe3O4 via in Situ Compatibilization with Zinc Dimethacrylate , 2017 .
[11] R. Rivlin. Torsion of a Rubber Cylinder , 1947 .
[12] W. Kuhn,et al. Über die Gestalt fadenförmiger Moleküle in Lösungen , 1934 .
[13] P. Flory. Network Structure and the Elastic Properties of Vulcanized Rubber. , 1944 .
[14] S. Schlögl,et al. Entanglement Effects in Elastomers: Macroscopic vs Microscopic Properties , 2014 .
[15] R. Rivlin. LARGE ELASTIC DEFORMATIONS OF ISOTROPIC MATERIALS. I. FUNDAMENTAL CONCEPTS , 1997 .
[16] M. Mooney. A Theory of Large Elastic Deformation , 1940 .
[17] P. Flory,et al. Stress-Strain Isotherm for Polymer Networks , 1959 .
[18] A. Tobolsky,et al. Rubber elasticity and chain configuration , 1961 .
[19] P. Flory,et al. Dependence of tensile strength of vulcanized rubber on degree of cross‐linking , 1949 .
[20] W. Kuhn,et al. Beziehungen zwischen Molekülgröße, statistischer Molekülgestalt und elastischen Eigenschaften hochpolymerer Stoffe , 1936 .
[21] R. S. Rivlin,et al. Large elastic deformations of isotropic materials. I. Fundamental concepts , 1948, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.
[22] M. Tse. Studies of triblock copolymer-tackifying resin interactions by viscoelasticity and adhesive performance , 1989 .
[23] Henry Yang. Water‐based polymers as pressure‐sensitive adhesives—viscoelastic guidelines , 1995 .
[24] A. Klein,et al. Molecular parameters and their relation to the adhesive performance of acrylic pressure‐sensitive adhesives , 2001 .
[25] Megan L. Robertson,et al. Thiol–Ene Elastomers Derived from Biobased Phenolic Acids with Varying Functionality , 2016 .