본 연구는 차세대 랫드에서 혈액 지질 감소에 관한 식이 내 오메가 6와 3 지방산 비율의 생 화학적 메카니즘을 조사하였다. 실험처리군은 오메가 6:오메가 3비율 0 (대조구), 1:1, 8:1, 19:1로 구 분하였다. 혈액 중성지방, 총콜레스테롤, 저밀도지질단백질(LDL-C), aspartate aminotransferase (AST), alanine aminotransferase (ALT), glucose의 수준은 오메가 6:오메가 3 비율 1:1 그룹에서 가장 낮았다. 혈액 고밀도지질단백질(HDL-C), 인지질의 수준은 오메가 6:오메가 3 비율 1:1 그룹이 가장 높았다. HMG-CoA reductase activity는 전체 저리구 가운데 오메가 6:오메가 3 비율 1:1, 8:1 그룹에서 가장 강하게 억제되었으나 분을 통한 스테롤의 배설량은 촉진되었다. 혈액 오메가 6:오메가 3 비율은 섭취한 식이 내 오메가 6:오메가 3 비율 증가에 따른 농도 의존적으로 감소하였다. 본 연구결과는 부모 세대로 부터 차세대 랫드에 이르기까지 오메가 6:오메가 3 비율이 8:1 이하로 낮아진 식이를 섭취하면 영양소 대사작용 활성화 메카니즘에 의한 혈액 중 유해지질 감소, 간 기능 유지 및 성장을 자극한다는 새로운 사실을 나타낸다.

This study was performed to improve the foaming generated in the effluent of wastewater treatment plant from March 2015 to July 2016. The main cause of foaming was air entrainment by an impinging jet and the internal accumulation by the diffusion barrier. Particularly, the foam growth was most active when there is low tide and larger discharge. To solve this problem, we experimented after installing fine mesh screen and the artificial channel device with underwater discharging outlet in the treated wastewater discharge channel and the outlet, respectively. As a result, the effects of foam reduction by devices ranged 85.0~92.0% and 70.7~85.6%, respectively. In addition, the foam and the noise were easily solved, first of all look to contribute to the prevention of complaints. Our device studies were applied to a single wastewater treatment plant. However, it is considered to be able to apply in other similar cases of domestic sewage treatment plants.

The reduction mechanism of the composite powders mixed with and CuO has been studied by using thermogravimetry (TG), X-ray diffraction, and microstructure analyses. The composite powders were made by simple Turbula mixing, spray drying, and ball-milling in a stainless steel jar with the ball to powder ratio of 32 to 1 at 80 rpm for 1 h without process controlling agents. It is observed that all the oxide composite powders are converted to W-coated Cu composite powder after reducing treatment under hydrogen atmosphere. For the formation mechanism of W-coated Cu composite powder, the sequential reduction steps are proposed as follows: CuO contained in the ball-milled composite powder is initially reduced to Cu at the temperature range from 20 to 30. Then, powder is reduced to W via W and W at higher temperature region. Finally, the gaseous phase of formed by reaction of with water vapour migrates to previously reduced Cu and deposits on it as W reduced by hydrogen. The proposed mechanism has been proved through the model experiment which was performed by using Cu plate and powder.der.

The ammonium salt of N-Nitrosophenylhydroxiamine, namely Cupferron, is a well-known analytical reagent which precipitates a great number of metal ions in acid medium. Various structures of electrode reduction for N-Nitrosophenylhydroxiamine have been suggested in acid and alkaline media by many researchers, but not in neutral medium. So the mechanism of electrode reaction of Cupferron was investigated by both chronopotentiometric and polarographic methods. It was estimated that the reduction of Cupferron occurs in a three-step mechanism through which a chemical step is interposed between two charge transfer, the ECE (charge transfer-chemical reaction-charge transfer) mechanism, over a range of neutral and alkaline media. The chemical reaction of the process was assumed to be acid-base catalyzed from the fact that kapp (over all rate constant) of chemical reaction is pH dependent.

본 연구에서는 고온의 LiCl-LlO 용융염계에서 우라늄 산화물의 금속전환과 LiO의 전해반응이 동시에 진행되는 통합 반응 메카니즘을 기초로 한 전기화학적 금속전환기술을 제안하였다. 본 실험에서는 전기화학적 환원반응에 의해 생성된 Li 금속이온이 음극에 전착과 동시에 우라늄 산화물과 반응하여 금속전환율 99 % 이상의 우라늄 감속을 생성하는 통합 반응 메카니즘을 확인할 수 있었다. 또한 전기화학적 금속전환기술의 공정 적용성 평가 일환으로 우라늄 산화물의 금속전환성, 반응 메카니즘 규명, LiO의 closed recycle rate 및 물질전달 특성 등의 기초 데이터를 확보하였다 향후 전기화학적 금속전환기술은 LiCl-Li 용융염계의 금속전환공정의 반응조건 제한성 해소, 금속전환율 향상 및 공정의 단순화 등의 기술성과 경제성 향상 측면에서 획기적인 방안으로 고려될 수 있을 것으로 판단된다.