Browsing by Author "Hogg, GR"
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- ItemThe AAEC ROTAMAK experiment description and preliminary results at low input power.(Australian Atomic Energy Commission, 1984-12) Durance, G; Hogg, GR; Tendys, JA description is given of the initial experiments on a rotamak device operating with 10 kW input power at a frequency of 1.85 MHz. The experimental apparatus and the diagnostic systems are also described. The matching of the radiofrequency power sources to the drive coils is discussed and details are given of the results from discharges in hydrogen, deuterium helium, and argon. The plasma/magnetic field configuration appears to be stable although under certain conditions fluctuations of the magnetic field structure have been observed.
- ItemANSTO's cooperation and collaboration program in the Asia Pacific Region(The Institution of Engineers Australia, 1994-05-01) Garnett, HM; Hogg, GRInternational collaboration and cooperation form an important part of the activities of the Australian Nuclear Science and Technology Organisation. They provide a mechanism which assists in the maintenance of a credible nuclear science and technology program at the forefront of science and technology endeavors. With countries in the Asia Pacific Region, ANSTO has developed a range of bilateral interactions to assist in the achievement of this goal. Furthermore on a multilateral level ANSTO has participated in activities sponsored by the International Atomic Energy Agency, particularly those funded by Australia.
- ItemThe dense plasma focus as a pulsed deuterium-tritium neutron source(Australian Atomic Energy Commission, 1973-04) Hogg, GRA dense plasma focus of the Mather type has been operated at a capacitor bank energy of 13 kJ with deuterium-tritium gas fillings. An average neutron yield of 1.1 x 10 11 neutrons per pulse was measured. The pulse width was 80 ± 5 nsec (FWHM) and the energy of the peak of the neutron pulse was determined by neutron time of flight to be 15.1 MeV in the 0º direction.
- ItemThe effect of an applied toroidal magnetic field on ROTAMAK discharges(Australian Atomic Energy Commission, 1984-12) Trowse, J; Durance, G; Hogg, GR; Jones, IR; Tendys, JThe effect of an applied toroidal magnetic field upon the rotamak configuration has been investigated. It has been found that the configuration can be maintained for at least several milliseconds but it has not been unambiguously established whether the addition of the toroidal field is beneficial or detrimental to the rotamak discharge.
- ItemEffects of rotating field frequency on the ROTAMAK configuration.(Australian Atomic Energy Commission, 1984-12) Durance, G; Hogg, GR; Tendys, JExperiments have been undertaken at three rotating field frequencies 1.0 1.85 and 3.5 MHz to determine the effect upon the rotamak configuration and the driven toroidal current. Toroidal current has been driven at all three rotating field frequencies for each of the gases studied. The results indicate that the 1.0 MHz frequency chosen for the rotating field in the high power AAEC rotamak experiments appears to be satisfactory.
- ItemSome x-ray and neutron measurements on the dense plasma focus(Australian Atomic Energy Commission, 1973-08) Hogg, GR; Tendys, JMeasurements of the X-ray and neutron emissions from a dense plasma focus device are given which include time integrated X-ray photographs of the focus, time dependent X-ray and neutron output characteristics and average neutron energy measurements determined by time of flight. The time of emission of X-rays and neutrons has been correlated with the time differential of the plasma current and the results of Bernstein et al. (1969) confirmed. When the focus was operated with a negative centre electrode, the X-ray and neutron emission was = 0.25% of that obtained under identical conditions with a positive centre electrode.
- ItemX-ray spectral measurements of a dense plasma focus(Australian Institute of Physics, 1974-05-21) Hogg, GR; Tendys, JThe tine resolved spectrum of the x-ray emission from the dense plasma focus has been measured over the energy range 1 to 5 keV using a four channel foil absorption spectrometer. The energy distribution of the electrons in the plasma can be calculated from these measurements and the electron temperature derived.