Grain-growth behavior in the 95Na1/2Bi1/2TiO3-5BaTiO3 (mole fraction, NBT-5BT) system has been investigated with the addition of Na2CO3. When Na2CO3 is added to NBT-5BT, the growth rate is higher than desired and grains are already impinging each other during the initial stage of sintering. The grain size decreases as the sintering temperature increases. With the addition of Na2CO3, a liquid phase infiltrates the interfaces between grains during sintering. The interface structure can be changed to be more faceted and the interface migration rate can increase due to fast material transport through the liquid phase. As the sintering temperature increases, the impingement of abnormal grains increases because the number of abnormal grains increases. Therefore, the average grain size of abnormal grains can be decreased as the temperature increases. The phenomenon can provide evidence that grain coarsening in NBT-5BT with addition of Na2CO3 is governed by the growth of facet planes, which would occur via mixed control.

본 연구는 H2O2가 함유된 (Na2CO3-NaHCO3) 혼합 탄산염 계에서 사용후핵연료를 산화용해할 시 U과 함께 공용해 되는 Cs, Te, Tc, Mo 등의 핵분열생성물로부터 Cs과 Tc의 선택적 침전 제거 거동을 규명하였다. Cs과 Tc은 각각 장수명 핵종으로 지하에서의 빠른 핵종 이동성과 고방열성 등으로 최종 처분 시 처분 환경 을 저해하는 핵종으로 처분 안전성 제고 측면에서 이들의 제거는 중요한 과제 중의 하나이다. Cs과 Re (Tc대용원소)의 선택적 침전제로는 각각 NaTPB, TPPCl를 선정하였으며, NaTPB에 의한 Cs 침전 및 TPPCl에 의한 Re 침전 모두 5분 이내로 매우 빠르게 이루어졌으며, 온도를 50℃, 교반속도를 1000 rpm 까지 증가 시켜도 이들의 침전 속도에는 별 영향이 없었다. NaTPB 침전 및 TPPCl 침전에 있어 가장 중요한 요인은 침전 용액의 pH 이며, 특히 TPPCl에 의한 Re의 선택적 침전의 경우 낮은 pH 에서 Mo가 Re과 공침되므로 pH 9 이상에서 수행하는 것이 효과적이다. 그리고 [NaTPB]/[Cs] 및 [TPPCl]/[Re]의 몰 농도 비 1 이상에서 Cs 및 Re을 각각 99% 이상 선택적으로 침전 제거할 수 있었다.

Activated carbons with high surface area of 2,600 m2/g and high pore volume of 1.2 cc/g could be prepared by KOH activation of rice hulls at a KOH:char ratio of 4:1 and 850℃. In order to increase the adsorption capacity of hydrogen sulfide, which is one of the major malodorous component in the waste water treatment process, various contents of Na2CO3 and KIO3 were impregnated to the rice-hull activated carbon. The impregnated activated carbon with 5 wt.% of Na2CO3 showed improved H2S adsorption capacity of 75 mg/g which is twice of that for the activated carbon without impregnation and the impregnated activated carbon with 2.4 wt.% of KIO3 showed even higher H2S adsorption capacity of 97 mg/g. The improvement of H2S adsorption capacity by the introduction of those chemicals could be due to the H2S oxidation and chemical reaction with impregnated materials in addition to the physical adsorption of activated carbon.

In this study, zeolitic materials at Na2CO3/CFA ratio of 0.6 1.8 were synthesized from coal fly ash from a thermal power plant using a fusion/hydrothermal method. The zeolitic materials were found to have cubic crystals structure and X-ray diffraction (XRD) peaks of Na-A zeolite by XRD and SEM analysis. When the zeolitic materials were synthesized from the coal fly ash, the XRD peaks of the zeolitic materials at Na2CO3/CFA ratios of 0.9-1.8 had the same location as the XRD peaks of commercial Na-A zeolite. The XRD peaks of the Na-A zeolite (Na12Al12Si12O4827.4H2O) were confirmed in the 2θ in the range of 7.18-34.18. However, it was also confirmed that peaks of CaCO3, an impurity inhibiting synthesis of Na-A zeolite from CaO and Na2CO3 in the coal fly ash, occurred in the XRD peaks of the zeolitic materials at Na2CO3/CFA ratio of 1.5-1.8. The crystallinities of the zeolitic materials tended to increase gradually within the Na2CO3/CFA ratio range of 0.6-1.8.