ANSTO Publications Online

Welcome to the ANSTO Institutional Repository known as APO.

The APO database has been migrated to version 7.5. The functionality has changed, but the content remains the same.

ANSTO Publications Online is a digital repository for publications authored by ANSTO staff since 2007. The Repository also contains ANSTO Publications, such as Reports and Promotional Material. ANSTO publications prior to 2007 continue to be added progressively as they are in identified in the library. ANSTO authors can be identified under a single point of entry within the database. The citation is as it appears on the item, even with incorrect spelling, which is marked by (sic) or with additional notes in the description field.

If items are only held in hardcopy in the ANSTO Library collection notes are being added to the item to identify the Dewey Call number: as DDC followed by the number.

APO will be integrated with the Research Information System which is currently being implemented at ANSTO. The flow on effect will be permission to publish, which should allow pre-prints and post prints to be added where content is locked behind a paywall. To determine which version can be added to APO authors should check Sherpa Romeo. ANSTO research is increasingly being published in open access due mainly to the Council of Australian University Librarians read and publish agreements, and some direct publisher agreements with our organisation. In addition, open access items are also facilitated through collaboration and open access agreements with overseas authors such as Plan S.

ANSTO authors are encouraged to use a CC-BY licence when publishing open access. Statistics have been returned to the database and are now visible to users to show item usage and where this usage is coming from.

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Communities in ANSTO Publications Online

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Now showing 1 - 5 of 5

Recent Submissions

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Status of the compactlight design study
(JACoW Publishing, 2019-05-19) D'Auria, G; Mitri, SD; Rochow, RA; Latina, A; Liu, X; Rossi, C; Schulte, D; Stapnes, S; Wu, X; Castañeda Cortes, HM; Clarke, J; Dunning, DJ; Thompson, N; Fang, W; Gazis, E; Gazis, N; Tanke, E; Trachnas, E; Goryashko, V; Jacewicz, M; Ruber, R; Taylor, G; Dowd, RT; Zhu, D; Aksoy, A; Nergiz, Z; Apsimon, R; Burt, G; Castilla, A; Priem, H; Janssen, X; Luiten, J; Mutsaers, P; Stragier, X; Alesini, D; Bellaveglia, M; Buonomo, B; Cardelli, F; Croia, M; Diomede, M; Ferrario, M; Gallo, A; Giribono, A; Piersanti, L; Scifo, J; Spataro, B; Vaccarezza, C; Geometrante, R; Kokole, M; Arnesano, J; Bosco, F; Ficcadenti, L; Mostacci, A; Palumbo, L; Dattoli, G; Nguyen, F; Petralia, A; Marcos, J; Marín, E; Muñoz Horta, R; Perez, F; Faus-Golfe, A; Han, Y; Bernhard, A; Gethmann, J; Calvi, M; Schmidt, T; Zhang, K; Esperante, D; Fuster, J; Gimeno, B; Gonzalez-Iglesias, D; Aicheler, M; Hoekstra, R; Cross, AW; Nix, L; Zhang, L
CompactLight (XLS) is an International Collaboration of 24 partners and 5 third parties, funded by the European Union through the Horizon 2020 Research and Innovation Programme. The main goal of the project, which started in January 2018 with a duration of 36 months, is the design of an hard X-ray FEL facility beyond today’s state of the art, using the latest concepts for bright electron photo-injectors, high-gradient accelerating structures, and innovative shortperiod undulators. The specifications of the facility and the parameters of the future FEL are driven by the demands of potential users and the associated science cases. In this paper we will give an overview on the ongoing activities and the major results achieved until now. © The Authors - CC-BY 3.0 licence
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On the design for a versatile imaging and hard x‐ray beamline at the Australian Synchrotron: implementation of in‐line phase‐contrast imaging
(American Institute of Physics, 2004-05-12) Wilkins, SW; Lewis, RA; Nesterets, Y; Garrett, RF; Mayo, SC; Nugent, KA; Parry, DJ; Siu, KKW; Stevenson, AS
We outline key design features for a versatile imaging and hard X‐ray beamline for operation at the Australian Synchrotron. Special attention is paid to the implementation of in‐line phase‐contrast imaging using both the plane‐wave and spherical‐wave cases. © 2004 American Institute of Physics.
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Development of the new Australian girth weld defect acceptance standards
(Welding Technology Institute of Australia, 1994) Bowie, G; Barbaro, F; Moss, CJ; Fletcher, L
The Australian pipeline code, in common with other areas of welded fabrication, has undertaken development of girth weld defect acceptance standards based on structural significance of the imperfection in addition to the traditional workmanship standards. The "fitness for purpose" approach adopted for the Australian pipeline code is related to that originating from the European pipeline Research Group (EPRF) which has compiled an extensive database of failure conditions of both real and artificial defects. The present paper reviews the relationship of EPRG guidelines and Standards Australia ME38 Committee, Welding Working Group draft revisions to Australian Standard AS2885,1987 hearinafter referred to as the draft AS2885.2. Attention is also drawn to the mechanical property requirements necessary to ensure girth weld integrity as well as the proposed research sponsored by the Cooperative Research Centre (CRC) to extend the pipe wall thickness range for the Australian pipeline industry.
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Evolution of an expert system for the engineering critical assessment of pipeline girth welds
(Welding Technology Institute of Australia, 1994) Moss, CJ; Fletcher, L; Barbaro, F; Bowie, G
AS2885 considers pipeline girth weld defect acceptance using and Tier Tier 1 (workmanship standards) 2 (fitness for purpose) and by Engineering Critical Assessment (ECA) as Tier 3. However, ECA is currently an unwieldy tool and unattractive to those who have only an occasional need to carry out assessment using fracture mechanics. A road map is described for the development of an ECA defect acceptance methodology. Input parameters to an ECA are also reviewed. The early stages in the evolution of an expert system, which aims to make the ECA route more accessible to the pipeline industry, are described.
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Weld repair of creep damaged steels
(Welding Technology Institute of Australia, 1994) Croker, ABL; Harrison, RP; Moss, CJ
A Cooperative Research Centre project "Welding of Thermally modified Structures" was commenced in June 1993 with support from ANSTO, CSIRO, BHP, University of Wollongong and the CRC for Materials, Welding and Joining. The main aims of the project are to quantify the effects of performing repair welds on materials which have operated for extended periods at elevated temperature. Welding is an increasingly used method for performing repairs, replacements, retrofits and modications to elevated temperature plant, however, the effects of these repairs on the ultimate life of a component are poorly understood. This paper presents details of the three ex-service materials chosen for the project, a carbon steel and two low alloy steels. Assessments have been made of their ex-service condition and a series of repair welds manufactured in preparation for a comprehensive testing and assessment program over the next 2 years. Work is also presented on development of new methods of assessing materials and components both destructively and non-destructively, along with new methods of modelling welded components in high temperature service.