• 한국환경보건학회지
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• 제21권2호
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• pp.68-74
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• 1995

The optimum conditions was synthesized for the formation of Magnetite ($Fe_3O_4$) by air bubbling with the suspensions obtained by mixing Ferrous sulfate ($FeSO_4\cdot 7H_2O$) and Sodium Hydroxide (NaOH) solution in various values equivalent ratio($R=2NaOH/FeSO_4$) were studied. The changes of the structure were measured with XRD, $EM and BET. Equivalent ratio R: 0.65 was synthesized Goethite ($\alpha$-FeOOH), which becomes Maghemite ($\gamma=Fe_2O_3$) by dehydration, reduction and oxidation process. At the equivalent ratio over 1 (R>1), Magnetite ($Fe_3O_4$) was synthesized directly. The oxygen-deficient Magnetite ($Fe_3O_{4-\delta}$), which is obtained by flowing $H_2$ gas(100 ml/min) through the synthesis Magnetite at 350$\circ$C for 4 hr. By using it, was researched the decomposition reaction of $CO_2$. $CO_2$ was decomposed nearly 100% in 45 minutes by the oxygen-deficient Magnetite.

• Corrosion Science and Technology
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• 제14권1호
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• pp.19-24
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• 2015

지금까지 마그네타이트 전극의 제조 방법과 전기화학적 특성에 대해 살펴보았다. 마그네타이트 전극을 제조하는 방법은 프레스법, 페이스트법, 전기도금법 등이 있으며, 이들의 전기화학 특성은 다음과 같이 정리할 수 있다. 1. Cycle voltammetry 실험을 통하여 애노딕, 캐소딕 분극 방향으로 각각 2개의 peak가 관찰되고, 이것은 $Fe_3O_4$가 $Fe(OH)_2$, FeO 등의 중간 산화물 형태를 거쳐 $Fe^{2+}$로 용해되는 반응들이다. 2. 산성 및 중성 용액에서는 마그네타이트의 환원적 용해가, 염기성 용액에서는 헤마타이트로의 산화 반응이 나타난다. 3. 전기화학 실험 결과와 마그네타이트 용해도를 관련시키기 위해서는 마그네타이트 용해가 일어나는 전위에서 실험 후, 용액에서 $Fe^{2+}$, $Fe^{3+}$ 이온들에 대한 분석이 필요하다.

• 자원리싸이클링
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• 제2권2호
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• pp.9-15
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• 1993

본 연구에서는 광양제철소 전로 dust를 사용하여 자력산별 및 심강(분급) 실험을 통해서 산화철(magnetite)를 분리.회수하였다. 그리고 분리.회수한 산화철(magnetite)과 SrCO$_{#}$를 고상방응시켜 Sr-ferrite를 제조하고 그 자기적 특성은 조사하였으며, 이를 통하여 다음과 같은 결론을 얻었다. 1. 광양제철소 제동전로 Ep dust는 대부분 ${\alpha}$-Fe와 magnetite, wustite 등의 철산화물 상태로 존재하며 자력산별과 심강(분급)실험을 행한 결과 magnetite가 주된 구성물질인 산물을 얻을 수 있었다. 2. 전로 dust 정제를 통하여 얻어진 magnetite와 SrCO$_{4}$를 혼합한 후 하소를 행한 결과 magnetite의 산화배소과정 없이도 Sr-ferrite 생성이 가능함을 확인 하였으며, Sr-ferrite 생성 반응은 다음과 같다. I. $SrCO_3$ $+Fe_3$O$_4$+1/2(1-X)$O_2 $longrightarrow$\alpha$ $-Fe _2$$O_3$ $+SrFeO _3$\ulcorner+$CO_2$ II. $5.5\alpha$ $-Fe_2$$O_3$ $+SrFeO_3$\ulcornerlongrightarrowSrFe\ulcornerO\ulcorner+1/2(1/2-X)$O_2$ 3. 1150$^{\circ}C$에서 1시간동안 하소한 후 1250$^{\circ}C$에서 2시간 동안 산결하여 Br=3.75GK, $_{1}$Hc=1.7KOe, (B.H)$_{max}$=2.64 MGOe인 Sr-ferrite 이방성 영구자석을 제조하였다.

• 한국재료학회지
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• 제22권5호
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• pp.253-258
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• 2012

Activated magnetite ($Fe_3O_{4-{\delta}}$) was applied to reducing $CO_2$ gas emissions to avoid greenhouse effects. Wet and dry methods were developed as a $CO_2$ removal process. One of the typical dry methods is $CO_2$ decomposition using activated magnetite ($Fe_3O_{4-{\delta}}$). Generally, $Fe_3O_{4-{\delta}}$ is manufactured by reduction of $Fe_3O_4$ by $H_2$ gas. This process has an explosion risk. Therefore, a non-explosive process to make $Fe_3O_{4-{\delta}}$ was studied using $FeC_2O_4{\cdot}2H_2O$ and $N_2$. $FeSO_4{\cdot}7H_2O$ and $(NH_4)_2C_2O_4{\cdot}H_2O$ were used as starting materials. So, ${\alpha}-FeC_2O_4{\cdot}2H_2O$ was synthesized by precipitation method. During the calcination process, $FeC_2O_4{\cdot}2H_2O$ was decomposed to $Fe_3O_4$, CO, and $CO_2$. The specific surface area of the activated magnetite varied with the calcination temperature from 15.43 $m^2/g$ to 9.32 $m^2/g$. The densities of $FeC_2O_4{\cdot}2H_2O$ and $Fe_3O_4$ were 2.28 g/$cm^3$ and 5.2 g/$cm^3$, respectively. Also, the $Fe_3O_4$ was reduced to $Fe_3O_{4-{\delta}}$ by CO. From the TGA results in air of the specimen that was calcined at $450^{\circ}C$ for three hours in $N_2$ atmosphere, the ${\delta}$-value of $Fe_3O_{4-{\delta}}$ was estimated. The ${\delta}$-value of $Fe_3O_{4-{\delta}}$ was 0.3170 when the sample was heat treated at $400^{\circ}C$ for 3 hours and 0.6583 when the sample was heat treated at $450^{\circ}C$ for 3 hours. $Fe_3O_{4-{\delta}}$ was oxidized to $Fe_3O_4$ when $Fe_3O_{4-{\delta}}$ was reacted with $CO_2$ because $CO_2$ is decomposed to C and $O_2$.

• 한국분말재료학회지
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• 제14권4호
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• pp.256-260
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• 2007

The surface of magnetite ($Fe_{3}O_{4}$) nanoparticles prepared by coprecipitation method was modified by carboxylic acid group of poly(3-thiophenacetic acid (3TA)) and meso-2,3-dimercaptosuccinic acid (DMSA). Then the lysozyme protein was immobilized on the carboxylic acid group of the modification of the magnetite nanoparticles. The magnetite nanoparticles are spherical and the particle size is approximately 10 nm. We measured quantitative dispersion state by dispersion stability analyzer for each $Fe_{3}O_{4}$ nanoparticles with and without surface modification. The concentration of lysozyme on the modified magnetite nanoparticles was also investigated by a UV-Vis spectrometer and compared to that of magnetite nanoparticles without surface modification. The functionalized magnetite particles had higher enzymatic capacity and dispersion stability than non-functionalized magnetite nanoparticles.

• 한국세라믹학회지
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• 제37권6호
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• pp.559-563
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• 2000

To decompose carbon dioxide, magnetite was synthesized with 0.2M-FeSO4$.$7H2O and 0.5 M-NaOH by coprecipitation. The deoxidized magnetite was prepared from the magnetite by hydrogen reduction for 1, 1.5, 2 hr. The degree of hydrogen reduction and the decomposition rate of carbon dioxide were investigated with hydrogen reduction time. The crystal structure of the magnetite was identified spinel structute by the X-ray powder diffractions. After magnetite was reduced by hydrogen, magnetite reduced by hydrogen become new phae(${\alpha}$-Fe2O3, ${\alpha}$-Fe) and spinel type simultaneously. After decomposing of carbon dioxide at 350$^{\circ}C$, new phse(${\alpha}$-Fe2O3, ${\alpha}$-Fe) were removed and the spinel type only existed. The specific surface area of the synthesized magnetite was 46.69㎡/g. With the increase of the hydrogen reduction time, the grain size, the hydrogen reduction degree and the decomposition rate of carbon dioxide was increased.

• Bulletin of the Korean Chemical Society
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• 제30권6호
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• pp.1305-1308
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• 2009

The experimental particle samples included ($Mn_{0.1}Fe_{0.9}$)O-$Fe_2O_3$ and FeO-($Gd_{0.1}Fe_{0.9}$)$_2O_3$ with $Mn^{2+}\;and\;Gd^{3+}$ substitutions in inverse spinel $Fe_3O_4$. A lecithin surfactant was adsorbed onto the magnetic particles by ultrasonication. The samples prepared showed excellent dispersibility at the mean size of 13 nm; their saturation magnetization values were 63 emu/g for the bare and Mn-substituted magnetites, and 56 emu/g for the Gd-substituted magnetite. The crystal structure of the substituted magnetites was very similar to that of the bare magnetite, due to a small amount of 0.1 mole fraction substituted in synthesizing the magnetite. The magnetite fluids, according to T2-weighted MR images, effectively diminished the signal intensity in the liver and spleen of Sprague-Dawley rats.

• 한국응용과학기술학회지
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• 제15권4호
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• pp.79-85
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• 1998

$Cu_xFe_{3-x}O_4$ catalyst and $Zn_xFe_{3-x}O_4$ catalyst were synthesized by the air oxidation method with various C(II) and Zn(II) weights. Activated catalysts decomposed carbon dioxide to carbon at $350^{\circ}C$, $380^{\circ}C$, $410^{\circ}C$ and $440^{\circ}C$. The value of carbon dioxide decomposition rate for $Cu_{0.003}Fe_{2.997}O_4$ and $Zn_{0.003}Fe_{2.997}O_4$ catslysts than was better catalysts. The decomposed rate of the catalysts is about 85%${\sim}$90%. The reaction rate constant(4.00 $psi^{1-{\alpha}}/min$) and activation energy(2.62 kcal/mole) of $Cu_{0.003}Fe_{2.997}O_4$ catalyst are better than $Zn_{0.003}Fe_{2.997}O_4$

• 한국분말재료학회지
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• 제26권6호
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• pp.481-486
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• 2019

Iron oxides currently attract considerable attention due to their potential applications in the fields of lithiumion batteries, bio-medical sensors, and hyperthermia therapy materials. Magnetite (Fe₃O₄) is a particularly interesting research target due to its low cost, good biocompatibility, outstanding stability in physiological conditions. Hydrothermal synthesis is one of several liquid-phase synthesis methods with water or an aqueous solution under high pressure and high temperature. This paper reports the growth of magnetic Fe₃O₄ particles from iron powder (spherical, <10 ㎛) through an alkaline hydrothermal process under the following conditions: (1) Different KOH molar concentrations and (2) different synthesis time for each KOH molar concentrations. The optimal condition for the synthesis of Fe₃O₄ using Fe powders is hydrothermal oxidation with 6.25 M KOH for 48 h, resulting in 89.2 emu/g of saturation magnetization at room temperature. The structure and morphologies of the synthesized particles are characterized by X-ray diffraction (XRD, 2θ = 20°-80°) with Cu-kα radiation and field emission scanning electron microscopy (FE-SEM), respectively. The magnetic properties of magnetite samples are investigated using a vibrating sample magnetometer (VSM). The role of KOH in the formation of magnetite octahedron is observed.

• 폴리머
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• 제27권1호
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• pp.40-45
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• 2003

본 연구에서는 $Fe_3O_4$ (magnetite)의 함량 변화와 온도 변화가 NBR/$Fe_3O_4$ 혼합물의 전기걱도도 ($\sigma$)에 미치는 영향을 조사하였다. 최소 최적 혼합비 (percolation threshold, $P_c$) 개념이 본 연구에서 제조한 전도성 입자가 충전된 복합체에 적용되며, 혼합물내 $Fe_3O_4$의 농도가 22%를 초과할 때 $\sigma$가 급격히 증가함을 확인하였다. $\sigma$의 온도 의존성은 $P_c$ 또는 그 이하에서 열적으로 활성화되며, 마그네이트가 NBR 고무의 강화 및 전도성 충전제로서의 역할을 할 수 있음을 조사하였으며, 충전제 함량이 30 phr인 복합체는 실온에서 고전압을 걸어줄 경우 전류는 전압제곱에 비례한 것으로 나타났다. 또한, 50 pk의 마그네이트가 충전된 복합체가 최적의 물리적 가교점으로 인하여 가장 우수한 인장강도와 파단시 신장율을 보였으며 모듈러스가 마그네이트의 강화효과 및 혼합물의 토오크 곡선으로부터 얻은 점도와 관련이 있음을 확인하였다.