In this study, we aimed to compare the mycelial growth of Pleurotus ostreatus after medium supplementation with various amino acids at different concentrations to select the optimal medium nutrient composition for mycelial growth. The mycelial growth of P. ostreatus was investigated after adding four amino acids (tryptophan, threonine, methionine, and lysine) at 0.5% or 1% to the medium.The rate of P. ostreatus mycelial growthwas faster in the potato dextrose agar (PDA) medium supplemented with threonine at 0.5% or 1% than that of the control, whereas it was inhibited by tryptophan treatment. Supplementation of sawdust mediumwith all amino acids, except tryptophan, at 0.5% did not alter the mycelial growth, compared to the controls. However, addition of any amino acid to sawdust medium at a higher concentration (1%) inhibited the mycelial growth. The laccase acitivity of P. ostreatus mycelium cultured in PDA medium was the highest when threonine was added, and the lowest when tryptophane was added, consistent with the results of the mycelial growth. Therefore, the addition of threonine, methionine, or lysine to PDA medium at a concentration of 0.5-1%was effective for increasing the mycelial growth of P. ostreatus; however, it inhibited mycelial growth insawdust medium, suggesting that the effects of amino acids dependedon the medium nutrient composition.
LiMn2O4 catalyst for CO2 decomposition was synthesized by oxidation method for 30 min at 600℃ in an electric furnace under air condition using manganese(II) nitrate (Mn(NO3)2·6H2O), Lithium nitrate (LiNO3) and Urea (CO(NH2)2). The synthesized catalyst was reduced by H2 at various temperatures for 3 hr. The reduction degree of the reduced catalysts were measured using the TGA. And then CO2 decomposition rate was measured using the reduced catalysts. Phase-transitions of the catalysts were observed after CO2 decomposition reaction at an optimal decomposition temperature. As the result of X-ray powder diffraction analysis, the synthesized catalyst was confirmed that the catalyst has the spinel structure, and also confirmed that when it was reduced by H2, the phase of LiMn2O4 catalyst was transformed into Li2MnO3 and Li1-2δMn2-δO4-3δ-δ' of tetragonal spinel phase. After CO2 decomposition reaction, it was confirmed that the peak of LiMn2O4 of spinel phase. The optimal reduction temperature of the catalyst with H2 was confirmed to be 450℃(maximum weight-increasing ratio 9.47%) in the case of LiMn2O4 through the TGA analysis. Decomposition rate(%) using the LiMn2O4 catalyst showed the 67%. The crystal structure of the synthesized LiMn2O4 observed with a scanning electron microscope(SEM) shows cubic form. After reduction, LiMn2O4 catalyst became condensed each other to form interface. It was confirmed that after CO2 decomposition, crystal structure of LiMn2O4 catalyst showed that its particle grew up more than that of reduction. Phase-transition by reduction and CO2 decomposition ; Li2MnO3 and Li1-2δMn2-δO4-3δ-δ' of tetragonal spinel phase at the first time of CO2 decomposition appear like the same as the above contents. Phase-transition at 2~5 time ; Li2MnO3 and Li1-2δMn2-δO4-3δ-δ' of tetragonal spinel phase by reduction and LiMn2O4 of spinel phase after CO2 decomposition appear like the same as the first time case. The result of the TGA analysis by catalyst reduction ; The first time, weight of reduced catalyst increased by 9.47%, for 2~5 times, weight of reduced catalyst increased by average 2.3% But, in any time, there is little difference in the decomposition ratio of CO2. That is to say, at the first time, it showed 67% in CO2 decomposition rate and after 5 times reaction of CO2 decomposition, it showed 67% nearly the same as the first time.
The spinel Fe3O4 powders were synthesized using 0.2 M-FeSO4·7H2O and 0.5 M-NaOH by oxidation in air and the spinel LiMn2O4 powders were synthesized at 480 ℃ for 12 h in air by a sol-gel method using manganese acetate and lithium hydroxide as starting materials. The synthesized LiMn2O4 powders were mixed at portion of 5, 10, 15 and 20 wt% of Fe3O4 powders using a ball-mill. The mixed catalysts were dried at room temperature for 24 hrs. The mixed catalysts were reduced by hydrogen gas at 350 ℃ for 2 h. The carbon dioxide decomposition rates of the mixed catalysts were 90% in all the mixed catalysts but the decomposition rate of carbon dioxide was increased with adding LiMn2O4 powders to Fe3O4 powders.
ZnxFe3-xO4(0.00.<X<0.08) was synthesized by air oxidation method for the decomposition of carbon dioxide. We investigated the characteristics of catalyst, the form of methane by gas chromatograph after decomposition of carbon dioxide and kinetic parameter. ZnxFe3-xO4(0.00.<X<0.08) was spinel type structure. The surface areas of catalysts(ZnxFe3-xO4(0.00.<X<0.08)) were 15~27 m2/g. The shape of Zn0.003Fe2.997O4 was sphere. The optimum temperature for the decomposition of carbon dioxide into carbon was 350℃. Zn0.003Fe2.997O4 showed the 85% decomposition rate of carbon dioxide and the degree of reduction by hydrogen(δ) of Zn0.003Fe2.997O4 was 0.32. At 350℃, the reaction rate constant and activation energy of Zn0.003Fe2.997O3.68 for the decomposition of carbon dioxide into carbon were 3.10 psi1-α/min and 0.98 kcal/mole respectively. After the carbon dioxide was decomposed, the carbon which was absorbed on the catalyst surface was reacted with hydrogen and it became methane.
자연발생포장 및 톱다리개미허리노린재 접종구에서 협 피해 및 수량 감소가 적었던 품종은 풍산나물콩, 소백나물콩, 두유콩, 신팔달콩 2호로 다른 품종에 비해 노린재 선호도가 낮은 품종으로 생각되었고, 명주나물콩, 만리콩, 황금콩은 피해가 심한 품종으로 분류되었다. 콩 품종간 톱다리개미허리노린재 선호성으로 모용색이 회백색인 품종군의 피해율이 13.0%인데 비해 갈색모용의 품종군은 8.2%로 피해율이 낮았으며, 제색도 황색에 비해 담갈색>갈색>회갈색 순으로 제