• 분석과학
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• 제6권1호
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• pp.107-119
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• 1993

본 연구에서는 백금족 금속-아세틸아세톤 킬레이트들의 역상 액체 크로마토그래피에서 용리 거동을 조사하여 머무름 메카니즘을 연구하고 이들의 최적 분리 조건을 알아내었다. 중성의 백금족 금속-아세틸아세톤 킬레이트들의 머무름에 소용매성 효과가 크게 영향을 준다는 것을 알았다. 또한, 백금족 금속-아세틸아세톤 킬레이트들의 기하학적 구조가 머무름에 많은 영향을 준다는 것을 알았다. 팔면체 구조인 $Rh(acac)_3$, $Ir(acac)_3$보다는 평면 사각형 구조인 $Pd(acac)_2$, $Pt(acac)_2$가 비극성 정지상과 상호 작용할 수 있는 표면적이 더 크므로 더 늦게 용리된다. 컬럼의 온도를 $25{\sim}45^{\circ}C$까지 변화시키면서 각 이동상 조성에서 van't Hoff plot를 구한 결과 온도에 따른 머무름 메카니즘은 일정함을 알 수 있었다. 이동상의 조성변화에 따라 용질의 머무름 메카니즘이 변화하는가를 알아보기 위하여 엔탈피-엔트로피 상쇄 현상을 조사하였다. 메탄올-물 용매의 조성이 40~70%로 변할 때 팔면체 구조인 $Rh(acac)_3$, $Ir(acac)_3$와 평면 사각형 구조인 $Pd(acac)_2$, $Pt(acac)_2$는 각각 엔탈피-엔트로피 상쇄 현상이 관찰되었으므로 머무름 메카니즘이 킬레이트의 구조에 따라 일정함을 알았다. 아세토니트릴-물 용매 조성이 30~60%로 변할 때는 엔탈피-엔트로피 상쇄 형상이 관찰되지 않았으므로 머무름 메카니즘이 복잡함을 알았다. 백금족 금속-아세틸아세톤 킬레이트들의 최적 분리 조건은 40% 메탄올, polymeric C18 컬럼, $45^{\circ}C$이다.

• Advances in nano research
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• 제2권2호
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• pp.77-88
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• 2014

Solvothermal treatment of late transition metal acetylacetonates in a novel medium composed either of pure acetophenone or acetophenone mixtures with amino alcohols offers a general approach to uniform hydrophilic metal nanoparticles with high crystallinity and low degree of aggregation. Both pure metal and mixed-metal particles can be accesses by this approach. The produced materials have been characterized by SEM-EDS, TEM, FTIR in the solid state and by Nanoparticle Tracking Analysis in solutions. The chemical mechanisms of the reactions producing nanoparticles has been followed by NMR. Carrying out the process in pure acetophenone produces palladium metal, copper metal with minor impurity of $Cu_2O$, and NiO. The synthesis starting from the mixtures of Pd and Ni acetylacetonates with up to 20 mol% of Pd, renders in minor yield the palladium-based metal alloy along with nickel oxide as the major phase. Even the synthesis starting from a mixed solution of $Cu(acac)_2$ and $Ni(acac)_2$ produces oxides as major products. The situation is improved when aminoalcohols such as 2-aminoethanol or 2-dimethylamino propanol are added to the synthesis medium. The particles in this case contain metallic elements and pairs of individual metals (not metal alloys) when produced from mixed precursor solutions in this case.

• Advances in Energy Research
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• 제4권2호
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• pp.177-187
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• 2016

Ammonia borane $NH_3BH_3$ solubilized in organic solvent is a potential liquid-state chemical hydrogen storage material. In this study, metal acetylacetonates like $Fe(O_2C_5H_7)_3$, $Co(O_2C_5H_7)_2$, $Ni(O_2C_5H_7)_2$, $Pd(O_2C_5H_7)_2$, $Pt(O_2C_5H_7)_2$ and $Ru(O_2C_5H_7)_3$ are considered for assisting dehydrocoupling of ammonia borane in diglyme (0.135 M) at $50^{\circ}C$. The molar ratio between ammonia borane and metal acetylacetonate is fixed at 100. A protocol for the separation of the soluble and insoluble fractions present in the slurry is proposed; it consists in using acetonitrile to make the precipitation of metal-based compounds easier and to solubilize boron-based intermediates/products. The nature of the metal does not affect the dehydrocoupling mechanisms, the $^{11}B\{^1H\}$ NMR spectra showing the formation of the same reaction intermediates. The aforementioned metal acetylacetonates do mainly have effect on the kinetics of dehydrocoupling. Dehydrocoupling takes place heterogeneously and dehydrogenation of ammonia borane in these conditions leads to the formation of polyborazylene via intermediates like e.g., B-(cyclodiborazanyl) amine-borane and borazine. Our main results are reported and discussed herein.

• 대한금속재료학회지
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• 제49권1호
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• pp.46-51
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• 2011

Real-time formation of $L1_0$ phase of FePt nanoparticles in the gas phase during ultrasonic-spray pyrolysis is first discussed in the present study. Without any post heat treatment, $L1_0$ phase of FePt nanoparticles appeared at the temperature above $900^{\circ}C$ in the gas phase synthesis. X-ray diffractometry (XRD) and transmission electron microscopy (TEM) studies revealed that FePt nanoparticles less than 10 nm in size contained small volume of $L1_0$ fct phase. However, in other samples obtained at the temperature below $900^{\circ}C$, iron oxide phase co-existed and no evidence of phase transformation was found. Thus, it is anticipated that the time of flight of particles required for crystallization and phase transformation was extended according to the increase of the collision rate. Finally, magnetic properties represented by coercivity and saturation magnetization and functional groups on the particle surface were discussed based on VSM and FT-IR results.