102,485 research outputs found
Burnell, N G, 409289
This record was harvested from a previous catalogue system and will be withdrawn in 2025. Information in this record may be superseded or incomplete. Visit this record in UMA's new catalogue at: https://archives.library.unimelb.edu.au/nodes/view/374878Surname: BURNELL
Given Name(s) or Initials: N G
Military Service Number or Last Known Location: 409289
Missing, Wounded and Prisoner of War Enquiry Card Index Number: 53439186259
Item: [2016.0049.07186] "Burnell, N G, 409289
A review of the book 'Aquaponics Food Production Systems' (Editors S. Goddek, A. Joyce, B. Kotzen, G. M. Burnell)
This paper summarizes the views of the author on the new book 'Aquaponics Food Production Systems' (editors S. Goddek, A. Joyce, B. Kotzen, G. M. Burnell)
Coping with traumatic memories: second world war veterans' experiences of social support in relation to the narrative coherence of war memories
This paper reports a qualitative study that used narrative analysis to explore how social support helps many armed-services veterans cope with traumatic memories.The analysis was carried out on two levels, that of narrative form (level of narrative coherence), argued to be indicative of reconciliation, and narrative content(themes of social support), which allowed exploration of the types of social support experienced by veterans with coherent, reconciled and incoherent narratives.Ten British male Second World War veterans were interviewed regarding their war experiences, presence of traumatic memories, and experiences of social support from comrades, family and society. Different patterns of support were qualitatively related to coherent, reconciled and incoherent narratives. Veteranswith coherent narratives were no less likely to have experienced traumatic events than those with reconciled or incoherent narratives, but they reported more positiveperceptions of their war experience and of the war’s outcomes, more positive experiences of communication with family in later life, and more positive perceptionsof societal opinion. The results are discussed in relation to how veteranscan be supported by family and friends to reconcile their traumatic memories, thus to lessen the burden in later life when vital support resources may be unavailable
Acton Burnell, Shropshire
'ACTON BURNELL, SHROPSHIRE. Drawn by J. P. Neale. Engraved by T. Jeavons. London. Pub. Octr. 1, 1825, by J. P. Neale, 16, Bennett St. Blackfriars Road & Sherwood, Jones & Co. Paternoster Row. Printed by J. & G. Bishop.' Accompanied by notes
Conformational equilibrium and orientational ordering: 1H‐nuclear magnetic resonance of butane in a nematic liquid crystal
In this study we use multiple-quantum H-1-NMR spectroscopy to study butane, the simplest flexible alkane, dissolved in a nematic solvent. An analysis of the highly accurate H-1 dipolar coupling constants gives important information about conformational and orientational behavior, including the hans-gauche energy difference, E(tg), and the conformer probabilities and order parameters. An essential component of the analysis involves the use of mean-field models to describe the orientational ordering of solutes in a nematic solvent. Several models were found to adequately describe the molecular ordering, including the chord model of Photinos et al. [D. J. Photinos, E. T. Samulski, and H. Toriumi, J. Phys. Chem. 94, 4688 (1990)] and recent versions of a model proposed by Burnell and co-workers [D. S. Zimmerman and E. E. Burnell, Mel. Phys. 78, 687 (1993)]. It was found that E(tg) lies in the range 2.1-3.0 kJ/mol, which is significantly below most experimental estimates of the gas-phase value. An attempt to describe more realistically the conformational states by including torsional fluctuations about the rotational isomeric states did not significantly improve the quality of the fits or alter the results. Finally the anisotropic component of the solute-solvent interaction was found to perturb only marginally the conformational probabilities from the isotropic values. (C) 1995 American Institute of Physics.PT: J; CR: AKSNES DW, 1970, ACTA CHEM SCAND, V24, P3764 ALEJANDRE J, 1994, J CHEM PHYS, V10, P7027 ALMARZA NG, 1990, MOL PHYS, V70, P1 BARKER PB, 1984, CHEM PHYS LETT, V107, P426 BARNHOORN JBS, 1993, LIQ CRYST, V13, P319 BENSHAUL A, 1983, J CHEM PHYS, V78, P4303 BRADFORD WF, 1977, J MOL STRUCT, V38, P185 BROWN D, 1990, J CHEM PHYS, V92, P3062 BURNELL EE, 1980, J MAGN RESON, V39, P461 BURNELL EE, 1982, J MAGN RESON, V50, P188 BURNELL EE, 1982, PHYS REV A, V25, P2339 CATES DA, 1991, J PHYS CHEM-US, V95, P2209 COLOMBO L, 1980, J CHEM PHYS, V73, P2013 COMPTON DAC, 1980, J PHYS CHEM-US, V84, P3587 CREAMER DB, 1985, J CHEM PHYS, V84, P476 DIEHL P, 1971, MOL PHYS, V20, P139 DURIG JR, 1979, J PHYS CHEM-US, V83, P265 EDBERG R, 1986, J CHEM PHYS, V84, P6933 ENCISO E, 1989, J CHEM PHYS, V90, P413 FERRARINI A, 1992, MOL PHYS, V77, P1 FLORY PJ, 1969, STATISTICAL MECHANIC GASSLER G, 1990, Z NATURFORSCH A, V45, P113 GOCHIN M, 1986, J AM CHEM SOC, V108, P6813 GOCHIN M, 1987, CHEM PHYS LETT, V137, P51 GOCHIN M, 1987, MOL PHYS, V60, P205 GOCHIN M, 1990, MOL PHYS, V69, P671 HEENAN RK, 1983, J CHEM PHYS, V78, P1270 JANIK B, 1987, J PHYS CHEM-US, V91, P1842 JORGENSEN WL, 1981, J AM CHEM SOC, V103, P677 JORGENSEN WL, 1982, J CHEM PHYS, V77, P5757 JORGENSEN WL, 1983, J PHYS CHEM-US, V87, P5304 KINT S, 1980, J CHEM PHYS, V73, P1599 LI KYZ, 1993, MOL PHYS, V78, P673 MARCELJA S, 1974, J CHEM PHYS, V60, P3599 PHOTINOS DJ, 1990, J PHYS CHEM-US, V94, P4688 PHOTINOS DJ, 1990, J PHYS CHEM-US, V94, P4694 PHOTINOS DJ, 1991, MOL PHYS, V72, P333 PHOTINOS DJ, 1992, J PHYS CHEM-US, V96, P6979 POLSON JM, 1994, J MAGN RESON SER A, V106, P223 PRATT LR, 1978, J CHEM PHYS, V68, P4202 PRATT LR, 1978, J CHEM PHYS, V68, P4213 REBERTUS DW, 1979, J CHEM PHYS, V70, P3395 RENDELL JCT, 1995, J MAGN RESON SER A, V112, P1 ROSEN ME, 1993, J PHYS CHEM-US, V97, P3858 RYCKAERT JP, 1975, CHEM PHYS LETT, V30, P123 RYCKAERT JP, 1978, FARADAY DISCUSS, V66, P95 SNIJDERS JG, 1983, ISRAEL J CHEM, V23, P269 STRALEY JP, 1974, PHYS REV A, V10, P1881 TERZIS AF, 1994, MOL PHYS, V83, P847 TOBIAS DJ, 1990, J CHEM PHYS, V92, P2582 VANDEREST AJ, 1987, MOL PHYS, V60, P397 VANDEREST AJ, 1988, J CHEM SOC F2, V84, P1095 VERMA AL, 1974, J CHEM PHYS, V60, P1540 WEBER TA, 1978, J CHEM PHYS, V69, P2347 WIBERG KB, 1988, J AM CHEM SOC, V110, P8029 WIELOPOLSKI PA, 1986, J CHEM PHYS, V84, P6940 WOKAUN A, 1977, CHEM PHYS LETT, V52, P407 ZIMMERMAN DS, 1990, MOL PHYS, V69, P1059 ZIMMERMAN DS, 1991, MOL CRYSTALS LIQ CRY, V203, P61 ZIMMERMAN DS, 1993, MOL PHYS, V78, P687; NR: 60; TC: 20; J9: J CHEM PHYS; PG: 12; GA: TA441Source type: Electronic(1
Intermolecular potentials in liquid crystals: comparison between simulations and NMR experiments
The anisotropic intermolecular forces responsible for the orientational ordering in liquid crystals are probed by comparing Monte Carlo (MC) simulations with experimental nuclear magnetic resonance (NMR) results for solutes in nematic liquid crystals. In a special liquid crystal mixture where all long-range interactions are assumed to be minimized, the models for short-range interactions which best fit NMR experimental solute order parameters also best fit solute order parameters from MC simulations of hard ellipsoids. This is taken as an indication that in this special mixture the intermolecular potential is dominated by short-range forces. However, for liquid crystals where long-range interactions are important, simulations of hard ellipsoids with point quadrupoles cannot reproduce even the gross effects observed with experimental NMR data.PT: J; CR: BURNELL EE, 1982, PHYS REV A, V25, P2339 BURNELL EE, 1998, CHEM REV, V98, P2359 CELEBRE G, 1997, MOL PHYS, V92, P1039 DIEHL P, 1974, J MAGN RESON, V14, P260 EMSLEY JW, 1983, MOL PHYS, V49, P1321 EMSLEY JW, 1991, LIQ CRYST, V9, P643 FERRARINI A, 1992, MOL PHYS, V77, P1 KOK MY, 1988, LIQ CRYST, V3, P485 PATEY GN, 1983, CHEM PHYS LETT, V99, P271 PHOTINOS DJ, 1992, J PHYS CHEM-US, V96, P8176 PHOTINOS DJ, 1993, J CHEM PHYS, V98, P10009 POLSON JM, 1996, MOL PHYS, V88, P767 POLSON JM, 1997, PHYS REV E, V55, P4321 SYVITSKI RT, IN PRESS SYVITSKI RT, 1997, CHEM PHYS LETT, V281, P199 TERZIS AF, 1994, MOL PHYS, V83, P847 VANDEREST AJ, 1985, MOL PHYS, V56, P161 VANDEREST AJ, 1987, MOL PHYS, V60, P397 VANDEREST AJ, 1988, J CHEM PHYS, V89, P4657 VANDEREST AJ, 1988, J CHEM SOC F2, V84, P1095 ZIMMERMAN DS, 1993, MOL PHYS, V78, P687; NR: 21; TC: 7; J9: INT J MOD PHYS C; PG: 11; GA: 222HPSource type: Electronic(1
A multiple-quantum H-1 NMR study of conformational biasing of biphenyl in a nematic liquid crystal
Multiple-quantum H-1 NMR spectroscopy was used to simplify the analysis of the complicated one-quantum spectrum of the 10-spin molecule biphenyl dissolved in a nematic solvent. An eight-quantum spectrum was analyzed to obtain estimates of all dipolar coupling constants and chemical shifts, which were used as a starting point to solve the one-quantum spectrum, The dipolar couplings from the one-quantum spectrum were used, in combination with those determined in a previous study using different liquid-crystal solvents, to obtain vibrationally corrected geometrical parameters and orientational order parameters, The effective internal rotational potential was found to be shifted slightly toward a more planar configuration relative to the gas-phase potential, with an equilibrium dihedral angle of 37 degrees. (C) 1996 Academic Press, Inc.PT: J; CR: ALMENNINGEN A, 1985, J MOL STRUCT, V128, P59 BARKER PB, 1984, CHEM PHYS LETT, V107, P426 BARRETT RM, 1972, J MOL STRUCT, V11, P105 BASTIANSEN O, 1949, ACTA CHEM SCAND, V3, P408 BASTIANSEN O, 1985, J MOL STRUCT, V128, P115 BODENHAUSEN G, 1981, PROG NMR SPECTROSC, V14, P137 BROCK CP, 1989, J AM CHEM SOC, V111, P4586 BURNELL EE, 1980, CHEM PHYS LETT, V76, P268 BURNELL EE, 1980, J MAGN RESON, V39, P461 BURNELL EE, 1987, CHEM PHYS LETT, V136, P87 CELEBRE G, 1991, J CHEM SOC FARADAY T, V87, P2623 CYVIN SJ, 1968, MOL VIBRATIONS MEAN, CH13 DIEHL P, 1969, NMR BASIC PRINC PROG, V1 DIEHL P, 1971, MOL PHYS, V20, P139 DIEHL P, 1972, NMR BASIC PRINCIPLES, V6, P1 DIEHL P, 1973, J MAGN RESON, V9, P495 DROBNY G, 1979, FARADAY DIV CHEM SOC, V13, P49 EATON VJ, 1973, J CHEM SOC F2, V2, P1601 ERNST RR, 1988, PRINCIPLES NUCLEAR M FIELD LD, 1981, J AM CHEM SOC, V103, P738 FIELD LD, 1986, J MAGN RESON, V69, P176 FIELD LD, 1992, J MAGN RESON, V97, P451 HARGREAVES A, 1962, ACTA CRYSTALLOGR, V15, P365 HILDERBRANDT RL, 1971, J CHEM PHYS, V55, P4648 LUCAS NDJ, 1972, MOL PHYS, V22, P233 LUCAS NDJ, 1972, MOL PHYS, V23, P835 MANNFORS B, 1994, J MOL STRUCT, V328, P287 MAYO RE, 1966, MOL PHYS, V10, P301 NIEDERBERGER W, 1973, MOL PHYS, V26, P571 POLSON JM, 1994, J MAGN RESON SER A, V106, P223 POLSON JM, 1995, J CHEM PHYS, V103, P6891 PULLHAM RJ, 1984, J RAMAN SPECTROSC, V15, P211 RENDELL JCT, 1995, J MAGN RESON SER A, V112, P1 SINTON S, 1980, CHEM PHYS LETT, V76, P263 SINTON SW, 1984, MOL PHYS, V53, P333 SLICHTER CP, 1990, PRINCIPLES MAGNETIC TROTTER J, 1961, ACTA CRYSTALLOGR, V14, P1135 WARREN WS, 1981, J AM CHEM SOC, V103, P1613 WEITEKAMP DP, 1983, ADV MAGN RESON, V11, P111 WOKAUN A, 1977, CHEM PHYS LETT, V52, P407 WONG TC, 1976, J MAGN RESON, V22, P227 ZIMMERMAN DS, 1993, MOL PHYS, V78, P687; NR: 42; TC: 15; J9: J MAGN RESONANCE SER A; PG: 8; GA: TZ082Source type: Electronic(1
Developing a model of narrative analysis to investigate the role of social support in coping with traumatic war memories
Within clinical and health psychology, narrative is used to understand how people make meaning of events that challenge one's believes about the self and the world e.g. the diagnosis of an illness or the experience of a traumatic event. This paper introduces a model of narrative analysis that can provide insight into the ways in which people make meaning of traumatic events and the types of resources that aid or hinder this process. The model, an adaptation of grounded narrative analysis (Murray, 2003), was applied at two levels (narrative form and narrative content) to the narratives of British male veterans of World War II (WWII) and post WWII veterans up to and including the Iraq war (2003-). Narrative form concerned the coherence of the narrative, which was defined as an oriented, structured, affectively consistent, and integrated narrative, indicative of the reconciliation. Narrative content focused on the social support experiences of the veterans. Through this two level analysis, it was possible to make theoretical links between the types of social support that aid the meaning making process and help veterans to reconcile their experiences. <br/
Critical current oscillations in strong ferromagnetic pi junctions
We report magnetic and electrical measurements of Nb Josephson junctions with strongly ferromagnetic barriers of Co, Ni, and Ni80Fe20 (Py). All these materials show multiple oscillations of critical current with a barrier thickness implying repeated 0-pi phase transitions in the superconducting order parameter. We show, in particular, that the Co barrier devices can be accurately modeled using existing clean limit theories and that, despite the high exchange energy (309 meV), the large IcRN value in the pi state means Co barriers are ideally suited to the practical development of superconducting pi-shift devices.</p
CCDC 1424602: Experimental Crystal Structure Determination
Related Article: Kenneth J. Broadley, Maxime G. P. Buffat, Erica Burnell, Robin H. Davies, Xavier Moreau, Stephen Snee, Eric J. Thomas|2016|Org.Biomol.Chem.|14|2057|doi:10.1039/C5OB02588
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