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김면섭,Myun Sup Kim 대한화학회 1973 대한화학회지 Vol.17 No.1
우리나라 영산일 bentonite를 KF, $NH_{4}Cl$등의 염과 혼합하여 $200-500^{\circ}C$로 가열처리하여 수세 건조한 시료의 methylene blue 흡착능을 조사하였다. $NH_{4}Cl$를 혼합하여 처리하였을 경우에는 methylene blue 흡착능이 다소 개선되었다. KF를 혼합하여 처리하였을 경우에는$200-300^{\circ}C$의 처리에서 methylene blue의 흡착능이 원시료의 약1.7배까지 개선되었다. $FeSO_4$ 나 $Na_{2}CO_4$등의 염과 혼합하여 처리하였을 경우에는 오히려 methylene blue 흡착능이 감소되었다. The adsorptivity of Methylene Blue on Korean Yeongil bentonite which was premixed with a salt of KF or $NH_{4}Cl$ etc., treated at $200-500^{\circ}C$, washed and dried, was studied. In case of treatment with$NH_{4}Cl$, slight improvement of the adsorptivity of methylene blue on the products was observed. With KF, treated at$200-300^{\circ}C$, the best results was obtained. The adsorption capacity of the products was improved about 1.7 times than that of original bentonite. With $FeSO_4$ or $Na_{2}CO_3$ etc. improvement of the adsorption capacity on the products was not observed.
국산 Bentonite의 수산화나트륨 수용액 처리에 의한 결정의 변화
김면섭,Myun Sup Kim 대한화학회 1973 대한화학회지 Vol.17 No.1
우리나라 영일산 Bentonite를 0.5-6 N NaOH로 $70-90^{\circ}C$에서 $Na_2:SiO_2$의 비율로 $1:1{\sim}4:1$로 2-30일의 범위에서 처리하여 그 겨정성의 변화를 X선회절법으로 조사하였다. 그 결과 2N NaOH로 $70^{\circ}C$에서 Zeolite Species가 좋은 수율로 생성되었다. 그러나 NaOH의 농도가 더 크고 온도가 더 높으면 이 Zeolite는 Hydrozysodalite로 변한다. 이 결정 외에도 처리조건에 따라서는 raujasite, sodium A zeolite, mordemite등의 결정도 소량 생겼다. Korean bentonite was treated with aqueous NaOH solution under the reaction conditions such as concentration of NaOH, 0.5-6N; ratio of $Na_{2}O$ to $SiO_2$, 1-4; reaction time, 2-30 days; reaction temperature, $70^{\circ}C-90^{\circ}C$. The products were examined by X-ray diffraction patterns. When it was treated with 2N NaOH at $70^{\circ}C$, zeolite species $P_1$ was formed with good yield. In higher concentration and at higher temperature than above, zeolite species $P_1$ was converted to hyeroxysodalite. Together with these crystals, some faujasite type zeolite, sodium A zeolite, mordenite type zeolite etc. was formed depending upon reaction conditions.
영일산 Bentonite의 화학적 처리에 의한 흡착력 개선
김면섭,Kim Myun Sup 대한화학회 1972 대한화학회지 Vol.16 No.4
영일 bentonite를 여러 농도의 NaOH, $Na_2SO_4 또는 NaHSO_4 용액으로 처리온도와 처리 시간을 달리하여 처리한 시료의 Methylene Blue 흡착력을 조사하였다. NaHSO_4용액으로 처리했을 경우에는 Methylene Blue 흡착력이 거의 개선되지 않았다. Na_2SO_4$ 용액으로 처리했을 경우에는 1N 용액으로 $100^{\circ}C$에서 2시간 처리했을 경우가 가장 좋았으며, 원시료의 3배의 흡착력을 나타내었다. 더 높은 농도와 더 높은 온도로 처리하면 Faujasite이 생성됨을 알았다. NaOH용액으로 처리했을 경우의 가장 좋은 처리조건은 1N, 1hr, $100^{\circ}C$이고 원시료의 3.3배의 흡착력을 나타내었다. 더 높은 농도와 더 높은 온도인 경우에는 hydroxysodalite이 생성됨을 알았다. The adsorption of Methylene Blue on Yeong-Il bentonite which was treated by aqueous NaOH, $Na_2SO_4 or NaHSO_4 solution respectively, varying concentrations, temperature and time, was studied. In case of treatment with NaHSO_4 solution, slight improvement of the adsorption of Methylene Blue on bentonite was observed. With Na_2SO_4$ solution, the best results obtained when bentonite was treated with 1 N of the solution for 2hr at $100^{\circ}C$, and the adsorption capacity of the product was 3 times better than that of original bentonite. At the higher concentration and the higher temperature than above, faujasite was formed. With NaOH solution, the best condition was in 1N solution for 1hr at $100^{\circ}C$ and the adsorption capacity of the product was 3.3 times better than that of original bentonite. At the higher concentration of the treating agent and at the higher temperature than above, hydroxysodalite was formed.
김면섭 ( Myun Sup Kim ) 한국화학공학회 1981 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.19 No.2
In these days, it is interested that amorphous materials are known to have special properties as catalyst, corrosion resistance, properties as semiconductor and mechanical properties that have an difficulty of obtaining from crystalline solids. Amorphous materials is not yet well-known, for the study of its structure is difficult in comparison with it of crystalline materials. As amorphous materials are in the nonequilibrium state, they have the weak point of the nonduration of structure. But it is expected that the future uses are various because of special properties by only amorphous materials. For last ten years, according as technique of preparation of amorphous materials was developed, they had become succesively prepared by the method of solidification by rapid cooling from fused state. Amorphos materials which have strength equal to piano wire, better corrosion resistance than stainless steel and properties for light memory are now known. Here, the properties, preparations and uses of amorphous materials were reviewed.