The recent release of contaminated water from the Fukushima Daiichi Nuclear Power Plant highlights the need for accurate tritium measurement, particularly near the minimum detectable activity (MDA) of 5 Bq·L−1 set by South Korea’s Nuclear Safety and Security Commission. This study aims to improve low-level tritium measurement accuracy by optimizing the region of interest (ROI) for quench curve determination. These adjustments are crucial for separating tritium signals from background noise. Quench standards were prepared and measured using a liquid scintillation counter (LSC). Three ROIs were analyzed to assess the impact of channel selection on measurement precision: A 20-148 channel range optimized via figure of merit (FOM) analysis, a 20-250 channel range covering tritium’s full beta spectrum, and a broad 1-1024 channel range. Quench curves were obtained by fitting the counting efficiency of each ROI to the quench standards. Tritium samples with six different activity levels were prepared, and their radioactivity was calculated using the quench curves. Selecting appropriate ROIs for quench curve determination is critical for measuring low-concentration tritium accurately. This approach reduces uncertainty and emphasizes reliable methods to improve the precision and consistency of tritium measurements.

염산매질에서 산화/환원제를 사용하여 Pu 산화수를 조절한 후, UV-Visible-Near IR 분광기를 이용하여 Pu(III, IV, V, VI) 산화수에 대한 흡수스펙트럼을 측정하여 그 분광학적 특성을 고찰하였다. Pu(III)으로 조절하기 위하여 환원제인 HCl를 사용하였으며, Pu(IV)와 Pu(VI)로 조절하기 위하여 산화제인 및 를 각각 사용하였다. 또한 Pu(VI)로 조절된 용액에 환원제인 HCl를 사용하여 Pu(V)로 조절하였다. Pu(III)와 Pu(IV)의 대표적인 흡수피크는 470 nm 및 600 nm에서 각각 관찰되었고, Pu(VI)와 Pu(V)의 특성피크는 830 nm 및 1135nm에서 각각 관찰되었다. Pu(III, IV, VI) 산화상태의 시간 경과에 따른 흡수스펙트럼 변화는 관찰되지 않았으나 Pu(V)의 경우 매우 불안정하여 생성되자 마자 Pu(III)로 변화되었다.