1,582 research outputs found

    Dr. Mike Davison – Faculty Author Interview

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    Dr. Mike Davison, Professor of Music, discusses his documentary film, Cuba: Rhythm in Motion. This dynamic film captures the joy of making music in Cuba, an island that Dr. Davison has visited numerous times with his students. The contrasting yet intertwined histories of Cuban and American music are traced and illustrated with extensive performance footage. A DVD of Cuba: Rhythm in Motion is available in Parsons Music Library

    Arthur Davison Ficke

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    An obituary for author Arthur Davison Ficke

    Arthur Davison Ficke

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    An obituary for author Arthur Davison Ficke

    Arthur Davison Ficke

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    An obituary for author Arthur Davison Ficke

    Surface density of states in the many-neighbor approximation

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    PT: J; CR: DAVISON SG, 1969, CHEM PHYS LETT, V3, P424 DAVISON SG, 1972, INT J QUANTUM CHEM, V6, P387 DAVISON SG, 1976, INT J QUANTUM CHEM, V10, P867 ECONOMOU EN, 1983, SOLID STATE SCI SER, V7 KALKSTEIN D, 1971, SURF SCI, V26, P85 LAVIS DA, UNPUB LAVIS DA, 1985, J PHYS C SOLID STATE, V18, P1387; NR: 7; TC: 4; J9: J PHYS CHEM; PG: 4; GA: A0336Source type: Electronic(1

    Portrait of Frank Dalby Davison [picture] /

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    Title from label on back of photograph.; Part of the collection: Portraits of eminent Australians 1968; Also available in an electronic version via the Internet at: http://nla.gov.au/nla.pic-an12151251; P523/4

    Multisite bond and overlap treatment of polymer-chain band structure

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    The usual tight-binding (TB) approximation, employed in electronic structure calculations, is extended to include the more-distant neighbor sites than the first. In doing so, a simple power law is adopted to describe the bond and overlap contributions, which enables the energy dispersion relation to be obtained in a closed analytic form. The resulting energy band structure has markedly different features from its TB Counterpart to which it reduces in the appropriate limits. In particular, local extrema always occur at the TB stationary values, although these may not both be band edges. Another intermediate critical point may arise, which is one of the band edges, the other being located at one of the TB extrema. (C) 2003 Wiley Periodicals, Inc.PT: J; CR: ALSTRUP I, 1968, PHYS STATUS SOLIDI, V28, P555 ANDRE JM, 1990, INT J QUANTUM CHEM S, V24, P65 DAVISON SG, 1967, J SURF SCI, V6, P323 DAVISON SG, 1969, CHEM PHYS LETT, V3, P424 DAVISON SG, 1970, SOLID STATE PHYS, V25, P1 DAVISON SG, 1972, INT J QUANTUM CHEM, V6, P387 DAVISON SG, 1976, INT J QUANTUM CHEM, V10, P867 DAVISON SG, 1986, J PHYS CHEM-US, V90, P652 DAVISON SG, 1996, BASIC THEORY SURFACE DAVISON SG, 2002, ACTA PHYS CHIM DEBRE, V189, P34 FAIRBAIRN WM, 1968, SURF SCI, V9, P439 FUJIMOTO H, 1987, CHEM PHYS LETT, V141, P485 GILBERT TL, 1962, J MATH PHYS, V3, P107 HOFFMANN R, 1991, MACROMOLECULES, V24, P3725 KARPFEN A, 1982, PHYS SCR T, V1, P79 KOSTER GF, 1954, PHYS REV, V95, P1167 LAVIS DA, 1986, J PHYS C SOLID STATE, V19, P3125 LOWDIN PO, 1950, J CHEM PHYS, V18, P365 LOWDIN PO, 1951, J CHEM PHYS, V19, P1579 MCKINNON BA, 1995, PHYS REV B, V52, P14531 MIRABELLA DA, 1994, AM J PHYS, V62, P162 MIRABELLA DA, 1994, PHYS REV B, V50, P12152 MIRABELLA DA, 1998, INT J QUANTUM CHEM, V68, P285 MISKOVIC ZL, 1996, CHEM PHYS LETT, V260, P647 RUEDENBERG K, 1961, J CHEM PHYS, V34, P1878 SLATER JC, 1930, PHYS REV, V35, P509 SPRINGBORG M, 1989, PHYS REV B, V40, P3333 SPRINGBORG M, 2000, INT J QUANTUM CHEM, V77, P843 TAFERNER WT, 1997, CHEM PHYS LETT, V269, P171 TOMASEK M, 1960, J CZECH J PHYS B, V10, P268; NR: 30; TC: 0; J9: INT J QUANTUM CHEM; PG: 6; GA: 717VPSource type: Electronic(1

    Surface states in electrochemisorption

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    The recursive Green function (RGF) method is used to obtain the surface and adatom RGFs for an electrified substate. The electrochemisorption (ECS) process is described, by invoking the Anderson-Newns (AN) model, whereby a self-consistent treatment of the ECS energy and charge transfer is provided. The role of the electric field, and the presence of surface states (SS), in governing magnetic and non-magnetic ECS is discussed in the case of H-Cr. (C) 2001 Elsevier Science Ltd. All rights reserved.PT: J; CR: ANDERSON PW, 1961, PHYS REV, V124, P41 DAVISON SG, 1988, SURF SCI, V200, P265 DAVISON SG, 1996, BASIC THEORY SURFACE DAVISON SG, 1997, J PHYS-CONDENS MAT, V9, P6371 ENGLISH RA, 1996, PROG SURF SCI, V53, P323 ENGLISH RA, 1997, PROG SURF SCI, V54, P241 ENGLISH RA, 1998, SURF SCI, V397, P251 MUSCAT JP, 1978, PROG SURF SCI, V9, P1 NEWNS DM, 1969, PHYS REV, V178, P1123; NR: 9; TC: 0; J9: PROG SURF SCI; PG: 11; GA: 460QCSource type: Electronic(1

    Curing the authorless void: protecting computer-generated works following IceTV and Phone Directories

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    This article examines and evaluates three possible reform options to ensure copyright protection for computer-generated works. Abstract This article builds on the author’s recent article ‘The Vanishing Author in Computer- Generated Works: A Critical Analysis of Recent Australian Case Law’. That article explained how recent Australian case law has seriously undermined copyright protection for works which are substantially shaped by software such that they lack a human author. The article argued that such works, if otherwise original, should not be denied copyright protection solely because they are computer-generated. This article thoroughly examines and evaluates three possible reform options: (1) deeming authorship of computer-generated works; (2) classifying computer-generated materials as subject matter other than works; and (3) sui generis protection. This article will also explore the sometimes difficult issues these options generate
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