Open AccessParametric Explosion Spectral Model
Author(s) -
S. R. Ford,
W. R. Walter
Publication year - 2012
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/1034507
Subject(s) - parametric statistics , nuclear explosion , containment (computer programming) , spectral line , parametric model , attenuation , geology , source model , spectrum (functional analysis) , seismology , porosity , spectral analysis , physics , geotechnical engineering , mathematics , nuclear physics , computational physics , computer science , statistics , spectroscopy , optics , quantum mechanics , astronomy , programming language
Small underground nuclear explosions need to be confidently detected, identified, and characterized in regions of the world where they have never before occurred. We develop a parametric model of the nuclear explosion seismic source spectrum derived from regional phases that is compatible with earthquake-based geometrical spreading and attenuation. Earthquake spectra are fit with a generalized version of the Brune spectrum, which is a three-parameter model that describes the long-period level, corner-frequency, and spectral slope at high-frequencies. Explosion spectra can be fit with similar spectral models whose parameters are then correlated with near-source geology and containment conditions. We observe a correlation of high gas-porosity (low-strength) with increased spectral slope. The relationship between the parametric equations and the geologic and containment conditions will assist in our physical understanding of the nuclear explosion source
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