Progress in Adhesion and Adhesives by K. L. Mittal

By K. L. Mittal

This e-book relies at the thirteen evaluate articles written through topic specialists and released in 2014 within the Journal stories of Adhesion and Adhesives. The purpose for e-book of this booklet is that presently the RAA has constrained move, so this e-book presents wide publicity and dissemination of the concise, serious, illuminating, and thought-provoking evaluate articles.

The topics of the experiences fall into four common areas:

              1. Polymer floor modification

              2. Biomedical, pharmaceutical and dental fields

              three. Adhesives and adhesive joints

             four. common Adhesion Aspects         

The subject matters coated contain: Adhesion of condensed our bodies at microscale; presenting adhesion estate to silicone fabric; functionally graded adhesively bonded joints; artificial adhesives for wooden panels; adhesion theories in wooden adhesive bonding; adhesion and floor matters in biocomposites and bionanocomposites; adhesion phenomena in pharmaceutical items and functions of AFM; cyanoacrylate adhesives in surgical functions; how one can generate monosort functionalized polyolefin surfaces; nano-enhanced adhesives; bonding varied fabrics in dentistry; flame remedy of polymeric materials—relevance to adhesion; and mucoadhesive polymers for reinforcing retention of ocular drug delivery.

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185, 215–225 (2006). 80. L. H. Lee, Self-folding of a slender microbeam and thin film: An elastica model. J. Mech. Mater. Struct. 8, 169–183 (2013) 81. C. Majidi, Remarks on formulating an adhesion problem using Euler’s elastica. Mech. Res. Commu. 34, 85–90 (2007) 82. J. Buehler, Y. J. Gao and Y. Huang, Self-folding and unfolding of carbon nanotubes. J. Eng. Mater. Technol. 128, 3–10 (2006). 83. W. Zhou, Y. Huang, B. C. M. J. J. Gao, Self-folding of single- and multiwall carbon nanotubes. Appl.

Dalhaimer, S. Cai, T. Richard, T. Manorama, M. E. Discher, Shape effects of filaments versus spherical particles in flow and drug delivery. Nature Nanotechnol. 2, 249–255 (2007). 52. E. Sackmann, Supported membranes: Scientific and practical applications. Science 271, 43–48 (1996). 53. S. Swain and D. Andelman, Supported membranes on chemically structured and rough surfaces. Phys. Rev. E 63, 051911 (2001). 54. J. Engler, S. L. E. Discher, Matrix elasticity directs stem cell lineage specification.

B. Wang, M. L. Wang, Cell movement is guided by the rigidity of the substrate. Biophys. J. 79, 144–152 (2000). 102. T. C. A. Flanagan, B. Marg, M. Ortiz, M. Funaki, N. Zahir, W. Ming, V. A. Janmey, Effects of substrate stiffness on cell morphology, cytoskeletal structure, and adhesion. Cell. Motility Cytoskel. 60, 24–34 (2005). 103. P. P. T. L. W. Q. Feng, Elasticity-driven droplet movement on a microbeam with gradient stiffness: A biomimetic self-­propelling mechanism. J. Colloid Interface Sci.

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