Publications

Tran, Hy D.; Mertes, Rick M.; Smelser, Ruth S.; kao, malia k.; abbott, patrick a.; lee, vincent l.

Abstract not provided.

Ruiz, Carlos L.; Chandler, Gordon A.; Hahn, Kelly D.; Smelser, Ruth S.; Nelson, Alan J.

Abstract not provided.

Review of Scientific Instruments

Hahn, Kelly D.; Ruiz, Carlos L.; Chandler, Gordon A.; Knapp, Patrick K.; Smelser, Ruth S.

We present a general methodology to determine the diagnostic sensitivity that is directly applicable to neutron-activation diagnostics fielded on a wide variety of neutron-producing experiments, which include inertial-confinement fusion (ICF), dense plasma focus, and ion beam-driven concepts. This approach includes a combination of several effects: (1) non-isotropic neutron emission; (2) the 1/r² decrease in neutron fluence in the activation material; (3) the spatially distributed neutron scattering, attenuation, and energy losses due to the fielding environment and activation material itself; and (4) temporally varying neutron emission. As an example, we describe the copper-activation diagnostic used to measure secondary deuterium-tritium fusion-neutron yields on ICF experiments conducted on the pulsed-power Z Accelerator at Sandia National Laboratories. Using this methodology along with results from absolute calibrations and Monte Carlo simulations, we find that for the diagnostic configuration on Z, the diagnostic sensitivity is 0.037% ± 17% counts/neutron per cm² and is ~ 40% less sensitive than it would be in an ideal geometry due to neutron attenuation, scattering, and energy-loss effects.

Ruiz, Carlos L.; Chandler, Gordon A.; Hahn, Kelly D.; Leeper, Ramon J.; Smelser, Ruth S.

There are several machines in this country that produce short bursts of neutrons for various applications. A few examples are the Zmachine, operated by Sandia National Laboratories in Albuquerque, NM; the OMEGA Laser Facility at the University of Rochester in Rochester, NY; and the National Ignition Facility (NIF) operated by the Department of Energy at Lawrence Livermore National Laboratory in Livermore, California. They all incorporate neutron time of flight (nTOF) detectors which measure neutron yield, and the shapes of the waveforms from these detectors contain germane information about the plasma conditions that produce the neutrons. However, the signals can also be %E2%80%9Cclouded%E2%80%9D by a certain fraction of neutrons that scatter off structural components and also arrive at the detectors, thereby making analysis of the plasma conditions more difficult. These detectors operate in current mode - i.e., they have no discrimination, and all the photomultiplier anode charges are integrated rather than counted individually as they are in single event counting. Up to now, there has not been a method for modeling an nTOF detector operating in current mode. MCNPPoliMiwas developed in 2002 to simulate neutron and gammaray detection in a plastic scintillator, which produces a collision data output table about each neutron and photon interaction occurring within the scintillator; however, the postprocessing code which accompanies MCNPPoliMi assumes a detector operating in singleevent counting mode and not current mode. Therefore, the idea for this work had been born: could a new postprocessing code be written to simulate an nTOF detector operating in current mode? And if so, could this process be used to address such issues as the impact of neutron scattering on the primary signal? Also, could it possibly even identify sources of scattering (i.e., structural materials) that could be removed or modified to produce %E2%80%9Ccleaner%E2%80%9D neutron signals? This process was first developed and then applied to the axial neutron time of flight detectors at the ZFacility mentioned above. First, MCNPPoliMi was used to model relevant portions of the facility between the source and the detector locations. To obtain useful statistics, variance reduction was utilized. Then, the resulting collision output table produced by MCNPPoliMi was further analyzed by a MATLAB postprocessing code. This converted the energy deposited by neutron and photon interactions in the plastic scintillator (i.e., nTOF detector) into light output, in units of MeVee%D1%84 (electron equivalent) vs time. The time response of the detector was then folded into the signal via another MATLAB code. The simulated response was then compared with experimental data and shown to be in good agreement. To address the issue of neutron scattering, an %E2%80%9CIdeal Case,%E2%80%9D (i.e., a plastic scintillator was placed at the same distance from the source for each detector location) with no structural components in the problem. This was done to produce as %E2%80%9Cpure%E2%80%9D a neutron signal as possible. The simulated waveform from this %E2%80%9CIdeal Case%E2%80%9D was then compared with the simulated data from the %E2%80%9CFull Scale%E2%80%9D geometry (i.e., the detector at the same location, but with all the structural materials now included). The %E2%80%9CIdeal Case%E2%80%9D was subtracted from the %E2%80%9CFull Scale%E2%80%9D geometry case, and this was determined to be the contribution due to scattering. The time response was deconvolved out of the empirical data, and the contribution due to scattering was then subtracted out of it. A transformation was then made from dN/dt to dN/dE to obtain neutron spectra at two different detector locations.

Proposed for publication in Review of Scientific Instruments.

Hahn, Kelly D.; Ruiz, Carlos L.; Leeper, Ramon J.; Chandler, Gordon A.; McWatters, Bruce R.; Smelser, Ruth S.

Abstract not provided.

Review of Scientific Instruments

Ruiz, Carlos L.; Chandler, Gordon A.; Cooper, G.W.; Fehl, D.L.; Hahn, K.D.; Leeper, Ramon J.; McWatters, Bruce R.; Nelson, A.J.; Smelser, Ruth S.; Snow, C.S.; Torres, J.A.

The 350-keV Cockroft-Walton accelerator at Sandia National laboratorys Ion Beam facility is being used to calibrate absolutely a total DT neutron yield diagnostic based on the 63Cu(n,2n) 62Cu(β+) reaction. These investigations have led to first-order uncertainties approaching 5 or better. The experiments employ the associated-particle technique. Deuterons at 175 keV impinge a 2.6 μm thick erbium tritide target producing 14.1 MeV neutrons from the T(d,n) 4He reaction. The alpha particles emitted are measured at two angles relative to the beam direction and used to infer the neutron flux on a copper sample. The induced 62Cu activity is then measured and related to the neutron flux. This method is known as the F-factor technique. Description of the associated-particle method, copper sample geometries employed, and the present estimates of the uncertainties to the F-factor obtained are given. © 2012 American Institute of Physics.

Review of Scientific Instruments

Nelson, A.J.; Ruiz, Carlos L.; Cooper, G.W.; Chandler, Gordon A.; Fehl, D.L.; Hahn, K.D.; Leeper, Ramon J.; Smelser, Ruth S.; Torres, J.A.

A novel method for modeling the neutron time of flight (nTOF) detector response in current mode for inertial confinement fusion experiments has been applied to the on-axis nTOF detectors located in the basement of the Z-Facility. It will be shown that this method can identify sources of neutron scattering, and is useful for predicting detector responses in future experimental configurations, and for identifying potential sources of neutron scattering when experimental set-ups change. This method can also provide insight on how much broadening neutron scattering contributes to the primary signals, which is then subtracted from them. Detector time responses are deconvolved from the signals, allowing a transformation from dN/dt to dN/dE, extracting neutron spectra at each detector location; these spectra are proportional to the absolute yield. © 2012 American Institute of Physics.

Hahn, Kelly D.; Ruiz, Carlos L.; Chandler, Gordon A.; Leeper, Ramon J.; McWatters, Bruce R.; Smelser, Ruth S.

Abstract not provided.

Ruiz, Carlos L.; Chandler, Gordon A.; Hahn, Kelly D.; Leeper, Ramon J.; McWatters, Bruce R.; Smelser, Ruth S.

Abstract not provided.

Ruiz, Carlos L.; Leeper, Ramon J.; Hahn, Kelly D.; Chandler, Gordon A.; Smelser, Ruth S.

Abstract not provided.

Ruiz, Carlos L.; Doyle, Barney L.; Leeper, Ramon J.; Chandler, Gordon A.; Hahn, Kelly D.; McWatters, Bruce R.; Smelser, Ruth S.; Snow, Clark S.

Abstract not provided.

Ruiz, Carlos L.; Leeper, Ramon J.; Chandler, Gordon A.; Cox, Carlos M.; Doyle, Barney L.; Hahn, Kelly D.; McWatters, Bruce R.; Smelser, Ruth S.; Snow, Clark S.

Abstract not provided.

Proposed for publication in Physical Review E.

Stygar, William A.; Matzen, M.K.; Mazarakis, Michael G.; McDaniel, Dillon H.; McGurn, John S.; Mckenney, John M.; Mix, L.P.; Muron, David J.; Ramirez, Juan J.; Ruggles, Larry R.; Stygar, William A.; Seamen, Johann F.; Simpson, Walter W.; Speas, Christopher S.; Spielman, Rick B.; Struve, Kenneth W.; Vesey, Roger A.; Wagoner, Tim C.; Gilliland, Terrance L.; Bennett, Guy R.; Ives, Harry C.; Jobe, Daniel O.; Lazier, Steven E.; Mills, Jerry A.; Mulville, Thomas D.; Pyle, John H.; Romero, Tobias M.; Seamen, Johann F.; Serrano, Jason D.; Smelser, Ruth S.; Fehl, David L.; Cuneo, M.E.; Bailey, James E.; Bliss, David E.; Chandler, Gordon A.; Leeper, Ramon J.

Abstract not provided.