Flash radiography with 24 GeV/c protons

C L Morris,D M Wright,R P Liljestrand,J Scaduto,R A Soltz,M D Wilke,A E Schach Von Wittenau,G E Hogan,E Ables,F E Merrill,P D Barnes,K Kwiatkowski,E P Hartouni,J J Gomez,Peter Pazuchanics ,Fesseha Mariam ,S M Sterbenz ,R Terry Thompson ,Alexander Saunders ,K.b Morley ,Eric N Ferm ,G.a Greene ,Deborah J Clark ,John Sarracino ,James E Pearson ,K.l Buescher ,D.j Cagliostro ,Maurice B Aufderheide ,M Murray ,S Gardner ,N.s.p King ,R Gallegos ,David Clark ,Д Морган ,A O Hanson ,K.r Alrick ,C.t Mottershead ,Kevin R Vixie ,C Espinoza ,John D Zumbro

doi:10.1063/1.3580262

Abstract

The accuracy of density measurements and position resolution in flash (40 ns) radiography of thick objects with 24 Gev/c protons is investigated. A global model fit to step wedge data is shown to give a good description spanning the periodic table. The parameters obtained from the step wedge data are used to predict transmission through the French Test Object (FTO), a test object of nested spheres, to a precision better than 1%. Multiple trials have been used to show that the systematic errors are less than 2%. Absolute agreement between the average radiographic measurements of the density and the known density is 1%. Spatial resolution has been measured to be 200 μm at the center of the FTO. These data verify expectations of the benefits provided by high energy hadron radiography for thick objects.

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