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Structural behavior

Stephen W. Tsai, Structural Behavior of Composite Materials, NASA CR-71, July... [Pg.185]

J. C. Ekvall, Structural Behavior ot Monofilament Composites, Proceedings of the AIAA 6th Structures and Materials Conference, Palm Springs, California, 5-7 April... [Pg.185]

In general, structural behaviors emerging from random value states under typical Fs can be grouped into four representative categories ... [Pg.454]

Develop suitably simplified concept of structural behavior to permit approximate determination of structural response—reactions, stress resultants, stability and stiffness requirements. Make appropriate assumptions within confines of laws of statics... [Pg.7]

Ylid structure, behavior of thiazolium salts in basic medium, 31 of 3,4-dimethy 1-5-0-hydroxy-ethylthia-zolium iodide, in basic medium, 35 of nitrophenacy] group, in basic medium, 33... [Pg.336]

Vol. 18. Organic Complexing Reagents Structure, Behavior, and Application to Inorganic Analysis. By D. D. Perrin... [Pg.443]

The Zintl-Klemm concept evolved from the seminal ideas of E. ZintI that explained the structural behavior of main-group (s-p) binary intermetaUics in terms of the presence of both ionic and covalent parts in their bonding description [31, 37]. Instead of using Hume-Rother/s idea of a valence electron concentration, ZintI proposed an electron transfer from the electropositive to the electronegative partner (ionic part) and related the anionic substructure to known isoelectronic elemental structures (covalent part), e.g., TK in NaTl is isoelectro-nic with C, Si and Ge, and consequenUy a diamond substructure is formed. ZintI hypothesized that the structures of this class of intermetallics would be salt-like [16b, 31 f, 37e]. [Pg.160]

Such differences in the secondary structure behavior with respect to temperature can be explained by suggesting that molecular close packing of proteins in the film is the main parameter responsible for the thermal stability. In fact, as in the case of BR, we have close packing of molecules even in the solution (membrane fragments) there are practically no differences in the CD spectra of BR solution at least tiU 75°C (denaturation takes place only for the sample heated to 90°C). RC in solution begins to be affected even at 50°C and is completely denatured at 75°C, for the solution contains separated molecules. [Pg.154]

Born in 1965 in Utrecht, the Netherlands, Marjolein van der Meulen received her Bachelors degree in mechanical engineering from the Massachusetts Institute of Technology in 1987. Thereafter, she received her MS (1989) and PhD (1993) from Stanford University. She spent three years as a biomedical engineer at the Rehabilitation R D Center of the Department of Veterans Affairs in Palo Alto, CA. In 1996, Marjolein joined the faculty of Cornell University as an Assistant Professor in the Sibley School of Mechanical and Aerospace Engineering. She is also an Assistant Scientist at the Hospital for Special Surgery, New York. She received a FIRST Award from the National Institutes of Health in 1995 and a Faculty Early Career Development Award from the National Science Foundation in 1999. Her scientific interests include skeletal mechanobiology and bone structural behavior. [Pg.190]

Answering these questions requires a better operational understanding of fhe funda-menfal processes driving the expected evolution of an indication marketplace — a process that uhlizes the structure/behavior paradigm. [Pg.628]

In our consulting practice we have developed a structure/behavior framework that provides a useful way to examine an indication marketplace, particularly when assessing commercial potential of a developmental compound, as shown in Figure 35.6. [Pg.628]

The structure/behavior framework of Case, Place, and Pace for a developmental compound is driven by a combination of d5mamics, which ultimately determine marketplace evolution. [Pg.630]

Lopez C, et al. Thermal and structural behavior of milk fat 3. Influence of cream cooling rate and droplet size. J Coll Interf Sci 2002 254 64. [Pg.109]

Structure-Behavioral Activity Relationships of Peptides Derived from ACTH... [Pg.153]

VAN NISPEN AND GREVEN Peptide Structure-Behavioral Activity... [Pg.155]

Organic Complexing Reagents Structure, Behavior, and Application to Inorganic... [Pg.626]

See other pages where Structural behavior is mentioned: [Pg.187]    [Pg.103]    [Pg.454]    [Pg.183]    [Pg.358]    [Pg.378]    [Pg.357]    [Pg.104]    [Pg.651]    [Pg.394]    [Pg.353]    [Pg.11]    [Pg.366]    [Pg.139]    [Pg.182]    [Pg.628]    [Pg.365]    [Pg.58]    [Pg.38]    [Pg.277]    [Pg.70]    [Pg.92]    [Pg.99]    [Pg.849]    [Pg.324]    [Pg.9]   
See also in sourсe #XX -- [ Pg.44 , Pg.45 , Pg.46 , Pg.47 , Pg.48 , Pg.49 , Pg.50 , Pg.51 , Pg.52 ]



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