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18 Frame and packet are terms that are used interchangeably and are pretty much synonymous. Another term that may be tossed about from time to time is datagram. All these terms refer to some sort of encapsulation that includes the data to be transferred along with addressing and type of service being requested. It is how data can traverse the Internet from one computer to another.
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Example 14-6. Estimate the dose equivalent rate 1 m from an unshielded 239Pu Be source that emits 3 107 neutrons/s with an average energy of 4.5 MeV. Solution. Point sources that emit S neutrons/s can be specified at a distance r (cm) in terms of a neutron flux f:
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Quantum Information Science and Technology Roadmap Part 1: Quantum Computation, Section 6.9, LA-UR-04-1777, Version 2.0, Apr. 2, 2004, produced for the Advanced Research and Development Activity (ARDA), [436] P. Peercy, The Drive to Miniaturization, Nature 406, 1023 (2000). [437] G. Timp, Nanotechnology, Springer, New York, 1999, pp. 161 206. [438] C. B. Murray, C. R. Kagan, and M. G. Bawendi, Self-Organization of CdSe Nanocrystallites into Three-Dimensional Quantum Dot Superlattices, Science 270, 1335 (1995). [439] C. A. Mirkin, R. L. Letsinger, R. C. Mucic, and J. J. Storho , A DNA-Based Method for Rationally Organizing Nanoparticles into Macroscopic Materials, Nature 382, 607 (1996). [440] A. P. Alivisatos et al., Organization of Nanocrystal Molecules Using DNA, Nature 382, 609 (1996). [441] J-M. Lehn and P. Ball, in The New Chemistry, N. Hall, Ed., Cambridge University Press, 2000, p. 347. [442] A. Cataldo, Intel Fabricates Next-Gen 65-nm and EUV Masks, EE Times, Jan. 16, 2003. [443] A. Hand, Nanoimprint Lithography: Plays Well with Others Semiconductor International, Sept. 1, 2004. [444] P. A. Houston, Quantum Wire Field E ect Transistor, Semiconductor Materials and Devices Group, J. Phys. D: Appl. Phys. 36, 3027 3033 (2003). Also, eee/smd. [445] Y. Huang et al., On Nanowire Building Blocks, Science 294, 1313 (2001). [446] C. N. Fleming et al., On the Design of Nanoscale Materials, J. Am. Chem. Soc. 123, 10336 (2001). [447] C. Wright-Smith and C. M. Smith, Atomic Force Microscopy in Biology, Scientist, Jan. 22, 2001. [448] G. A. Somorjai, in The New Chemistry, N. Hall, Ed., Cambridge University Press, 2000. [449] H. G. Craighead, On Micro- and Nanoelectromechanical Systems, Science 290, 1532 (2000). [450] T. Kouh, D. Karabacak, D. H. Kim, and K. L. Ekinci, Ultimate Limits to Optical Displacement Detection in Nanoelectromechanical Systems, 2004 NSTI Nanotechnology Conference and Trade Show, Nanotech 2004, Mar. 7 11, 2004, Boston, MA. [451] S. M. Blinder, Quantum Chemistry, Class Materials, Chemistry Class 461, 7: The Hydrogen Atom: Atomic Orbitals, Spring Term 2002, University of Michigan, Ann Arbor, MI, [452] Hilbert Spaces, Wikipedia, [453] J. P. Lowe, Quantum Chemistry, 2nd ed., Academic, New York, 1993; republished as NIH Guide to Molecular Modeling, Center for Molecular Modeling (CMM), Bethesda, MD. [454] C. Levit, A New Pictorial Approach to Molecular Structure and Reactivity, White Paper, NASA Nanotechnology Publications, NASA Advanced Supercomputing Division, NAS Systems Division O ce,
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The getsignal(signalnum) function returns the current handler for the specified signal. It returns a callable Python object, SIG_DFL, SIG_IGN, or None (for nonPython signal handlers). default_int_handler is the default Python signal handler. Except for handlers for SIGCHD, all signal handlers ignore the underlying implementation and continue to work until they are reset. Even though the signal handling happens asynchronously, Python dispatches the signals between bytecode instructions, so a long call into a C extension module could delay the arrival of some signals. On UNIX, you can call signal.pause() to wait until a signal arrives (at which time the correct handler receives it). signal.alarm(time) causes the system to send a SIGALRM signal to the current process after time seconds; it returns the number of seconds left until the previous alarm would have gone off (if any). alarm cancels any previous alarm, and a time of 0 removes any current alarm. You can also call os.kill(pid, sig) to send the given signal to the process with the ID of pid.
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The second important feature in photorefractive phase conjugation is the re ectivity rise time. A typical time evolution of the re ectivity is given in Fig. 8.13. It shows a sharp increase characterized by the time needed for the re ectivity to grow from 10% to 90% of its maximum value t90% 2 t10% ; tpc. To optimize this feature, a plane-wave model is used. Absorption may be neglected in BaTiO3:Rh at 1.06 mm (a 0.1 cm21). This model cannot take into account the spatial pro les of the interacting beams, like in three-dimensional numerical models [44], or the in uence of beam-fanning [45]. But for t . t10%, one may reasonably consider that the desired transmission grating is the only one remaining in the material. Consequently, this simpli ed model is suf cient to optimize the re ectivity rise time, using coupled-wave equations for a transmission grating only [Eq. (15)], along with the time evolution of the space-charge eld E1 [Eq. (16)]. @A1 (z, t) G i E1 (z, t)A4 (z, t) @z 4Esc @A (z, t) G 2 i E1 (z, t)A (z, t) 3 @z 4Esc @A3 (z, t) G i E1 (z, t)A2 (z, t) @z 4Esc @A (z, t) G 4 i E1 (z, t)A (z, t) 1 @z 4Esc A1, A2, A3, and A4 are the complex amplitudes of the plane waves, and Esc is the steady-state space-charge eld. As detailed in Section 8.2, the photorefractive effect in BaTiO3:Rh at 1.06 mm nds its origin in the three charge states of rhodium Rh3 , Rh4 , and Rh5 , and a three-
interference shielding for military applications and radar absorption. SWNT-based materials represent the future aerospace vehicle construction material of choice based on predicted strength-to-weight advantages and inherent multifunctionality [182]. SWNT-based composites are still in their infancy. Nanoparticles can be incorporated into polymeric coatings to facilitate measurable improvements in targeted properties, for example, scratch resistance, UV resistance, conductivity, and the like. Commercial-grade processing methods have been developed in the recent past to control the average particle size and particle size distribution of the dispersed nanoparticles; these integrated technologies allow transparent coatings containing nanoparticles to be formed in a plethora of resin formulations [183]. As pure carbon molecules, SWNTs o er a wide variety of derivatives for compatibilizing, dispersing, and coupling with a host polymer; furthermore, SWNTs can be considered a new type of polymer because the molecules can be modi ed chemically and regarded as a backbone polymer the basis of new classes of block-andgraft copolymers [89]. Nanotubes are especially promising for biomedical applications because one is able to tailor them for speci c parts of the body. For example, nanotubes that assemble themselves using the same chemistry as DNA may be used for creating better arti cial joints and other body implants. Researchers have discovered that the self-assembling nanotubes represent an entirely new and potentially superior material to use for arti cial body parts [184, 185]. Bone cells (osteoblasts) attach better to nanotubecoated titanium (Ti) than they do to conventional titanium used to make arti cial joints. Bone cells and cells from other parts of the body attach better to various materials that possess surface bumps about as wide as 100 nm; conventional titanium used in arti cial joints has surface features on the scale of microns, causing the body to recognize them as foreign and prompting a rejection response. Helical rosette nanotubes (HRN) are a new class of self-assembled organic nanotubes possessing biologically inspired nanoscale dimensions. Because of their chemical and structural similarity with naturally occurring nanostructured constituent components in bone such as collagen and hydroxyapatite, researchers believe that an HRN-coated surface may simulate an environment that bone cells are accustomed to interacting with [184, 185]. Other applications envisioned include the following [2]: solar cells in roo ng tiles and siding that provide electricity for homes and facilities; this can result in a much cleaner environment due to greater use of solar energy. Prototype tires exist today that provide improved skid resistance, reduced abrasion, and resulting longer wear, although a date for market introduction had not been announced as of press time. The nanocomposites being used in tires can be used in other consumer products such as high-performance footwear, exercise equipment, and car parts (belts, wiper blades, and seals). (Nanocomposites, not just SWNT-based nanocomposites are discussed further in a subsection that follows.) New commercial applications of nanotechnology that are expected within 5 years in the pharmaceutical and chemical industries include advanced drug delivery systems (e.g., implantable devices that automatically administer drugs and sense drug levels) and medical diagnostic tools, such as cancer tagging mechanisms. Finally, some researchers also contemplate nanoscale machines comprised of gears built with nanotubes and close variants, as illustrated in Figure 4.10.
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