Alion Mangasi Marpaung, Zener Sukra Lie, Hideaki Niki, Kiichiro Kagawa, Ken-ichi Fukumoto, Muliadi Ramli, Syahrun Nur Abdulmadjid, Nasrullah Idris, Rinda Hedwig, May On Tjia, Marincan Pardede, Maria Margaretha Suliyanti, Eric Jobiliong, Koo Hendrik Kurniawan

This paper appears in:  Journal of Applied Physics 100

Issue Date :  19 September 2011
On page(s): 063301-1 – 063301-6

 

Abstract

An experimental study on picosecond laser induced plasma spectroscopy of a zircaloy sample with low-pressure surrounding helium gas has been carried out to demonstrate its potential applicability to three-dimensional quantitative micro-analysis of deuterium impurities in zircaloy. This was achieved by adopting the optimal experimental condition ascertained in this study, which is specified as 7 mJ laser energy, 1.3 kPa helium pressure, and 50 μs measurement window, and which was found to result in consistent D emission enhancement. Employing these operational parameters, a linear calibration line exhibiting a zero intercept was obtained from zircaloy-4 samples doped with various concentrations of D impurity, regarded as surrogates for H impurity. An additional measurement also yielded a detection limit of about 10 μg/g for D impurity, well below the acceptable threshold of damaging H concentration in zircaloy. Each of these measurements was found to produce a crater size of only 25 μm in diameter, promising its application for performing less-destructive measurements. The result of this study has thus paved the way for conducting a further experiment with hydrogen-doped zircaloy samples and the further technical development of a three-dimensional quantitative micro-analysis of detrimental hydrogen impurity in zircaloy vessels used in nuclear power plants.