• Bulletin of the Korean Chemical Society
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• 제28권2호
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• pp.251-256
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• 2007

The crystal structure of fully dehydrated partially Cs+-exchanged zeolite X, [Cs52Na40Si100Al92O384], a = 24.9765(10) A, has been determined by single-crystal X-ray diffraction techniques in the cubic space group Fd3 at 21 °C. The crystal was prepared by flow method for 5 days using exchange solution in which mole ratio of CsOH and CsNO3 was 1 : 1 with total concentration of 0.05 M. The crystal was then dehydrated at 400 °C and 2 × 10-6 Torr for 2 days. The structure was refined to the final error indices, R1 = 0.051 and wR2 (based on F2) = 0.094 with 247 reflections for which Fo > 4σ (Fo). In this structure, about fifty-two Cs+ ions per unit cell are located at six different crystallographic sites with special selectivity; about one Cs+ ion is located at site I, at the centers of double oxygen-rings (D6Rs), two Cs+ ions are located at site I', and six Cs+ ions are found at site II'. This is contrary to common view that Cs+ ions cannot pass sodalite cavities nor D6Rs because six-ring entrances are too small. Ring-opening by the formation of ?OH groups and ring-flexing make Cs+ ions at sites I, I', and II' enter six-oxygen rings. The defects of zeolite frameworks also give enough mobility to Cs+ ions to enter sodalite cavities and D6Rs. Another six Cs+ ions are found at site II, thirty-six are located at site III, and one is located at site III' in the supercage, respectively. Forty Na+ ions per unit cell are located at two different crystallographic sites; about fourteen are located at site I, the centers of D6Rs and twenty-six are also located at site II in the supercage. Cs+ ions and Na+ ions at site II are recessed ca. 0.34(1) A and 1.91(1) A into the supercage, respectively. In this work, the highest exchange level of Cs+ ions per unit cell was achieved in zeolite X by conventional aqueous solution methods and it was also shown that Cs+ ion could pass through the sixoxygen rings.

• 한국자기학회지
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• 제14권6호
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• pp.219-223
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• 2004

L $i_{0.5}$F $e_{2.5-{\chi}}$Rhx $O_4$($\chi$= 0.25, 0.50, 0.75, 1.00)을 직접합성법으로 제조하고, 시료의 조성비에 따른 자기적 성질과 결정학적 구조를 연구하였다. x선 회절실험분석 결과 시료 모두 공간군 Fd3m에 해당하는 입방 스피넬구조를 가졌고, Rh을 치환함에 따라 Li이온이 팔면체 자리에서 사면체 자리로의 이동이 나타났다. 시료의 격자상수는 Rh을 치환함에 따라 8.3365 $\AA$에서 8.3932 $\AA$으로 증가하였다. Neel 온도 이하에서 외부자기장을 가하지 않은 상태에서의 뫼스바우어 스펙트림과 외부자기장 (6 T)을 인가한 뫼스바우머 스펙트럼을 여러 온도에 대하여 취하여 미시적 자성구조를 측정하였다. 외부자기장하의 뫼스바우어 스펙트럼 분석으로 각 시료의 정확한 면적비를 계산하여 수행한 Debye온도 분석결과 전체 시료에서 사면체와 팔면체 자리가 비슷한 정도의 결합 세기를 가졌음을 알았다. $\chi$=0.75의 경우는 외부자기장하에서 사면체와 팔면체 자리의 초미세 자기장의 부호가 바뀌는 것을 알았고, 이는 Li ion의 자리이동과 일치하는 결과를 보인다 4.2K에서 극저온 하에서 6 T를 인가한 외부자기장의 스펙트럼분석으로 전체 시료의 자기적 스핀구조가 collinear spin 모형을 따름을 알 수 있었다.

• 한국재료학회지
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• 제11권2호
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• pp.88-93
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• 2001

$N_2$처리에 의해 Si (001) 기판에 형성된 C49상의 구조를 갖는 에피택셜 $TiSi_2$상의 열적 거동과 결정학적 특성을 X선 회절법 (XRD)과 고분해능 투과전자현미경법 (HRTEM)으로 조사하였다. 에피택결 $C49-TiSi_2$상은 $1000^{\circ}C$ 정도의 고온에서도 안정상인 C54상으로 상변태하지 않고 형태적으로도 고온 특성이 우수하다는 것이 밝혀졌다. HRTEM 결과로부터 에피택결 $TiSi_2$상과 Si 사이의 결정학적 방위관계는 (060) [001]TiSi$_2$//(002) [110]Si임을 알 수 있었고 계면에서의 격자 변형에너지는 misfit 전위의 형성에 의하여 해소되는 것을 확인할 수 있었다. 또한 HRTEM상의 해석과 원자 모델링을 통하여 Si에서 에피택셜 C49-TiSi$_2$상의 형성기구와 C49상의 (020) 면에 존재하는 적층결함을 고찰하였다.

• Bulletin of the Korean Chemical Society
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• 제14권5호
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• pp.603-610
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• 1993

The crystal structure of dehydrated $Ag_{5.6}K_{6.4}-A$, zeolite A ion-exchanged with $K^+\;and\;Ag^+$ as indicated and dehydrated at 360$^{\circ}$C, has been determined by single-crystal X-ray diffraction techniques. Also determined were the structures of the products of the reactions of this zeolite with 0.1 Torr of Cs vapor at 250$^{\circ}$C for 48 h and 72 h, and with 0.1 Torr of Rb vapor at 250$^{\circ}$C for 24 h. The structures were solved and refined in the cubic space group Pm3m at 21(l)$^{\circ}$C (a= 12.255(l) ${\AA}$ , 12.367(l) ${\AA}$, 12.350(l) ${\AA}$, and 12.263(l) ${\AA}$, respectively). Dehydrated $Ag_{5.6}K_{6.4}$-A was refined to the final error indices $R_1= 0.044\;and\;R_2=0.037$ with 202 reflections for which I>3${\sigma}$(I). The crystal structures of the reaction products were refined to $R_1=0.087\;and\;R_2= 0.089$ with 157 reflections, $R_1=0.080\;and\;R_2= 0.087$ with 161 reflections, and $R_1= 0.071\;and\;R_2=0.061$ with 88 reflections, respectively. In the structure of $Ag_{5.6}K_{6.4}-A,\;K^+$ ions block all 8-oxygen rings, and one reduced Ag atom is found per sodalite cavity. Also, ca. 4.6 $Ag^+ ions\;and\;3.4 K^+ ions$ are found at 6-ring sites in the large cavity. The crystal structures of the reaction products show that all $K^+$ and $Ag^+$ ions have been reduced, and that all K^+$ atoms have left the zeolite. Cs or Rb species are found at three different crystallographic sites: 3.0 $Cs^+\;or\;3.0Rb^+$ ions per unit cell occupy 8-ring centers, ca. 8.0 $Cs^+ ions\;or\;5.7 Rb^+$ ions, are found on threefold axes opposite 6-rings deep in the large cavity, and ca. 2.5 $Cs^+\;or\;2.3 Rb^+ ions are found on threefold axes in the sodalite unit. Also, 1 $Rb^+$ ion lies opposite a 4-ring. Silver atoms, corresponding to 75% or 40% occupancy of hexasilver clusters stabilized by coordination to $Cs^+\;or\;Rb^+$ ions, are found at the centers of the large cavities. In the crystal structures of dehydrated Ag_{5.6}K_{6.4}-A$ reacted with Cs vapor, excess Cs atoms are absorbed and these form (locally) cationic clusters such as $(Cs_4)3^+\;and\;(Cs_6)4^+$.

• Bulletin of the Korean Chemical Society
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• 제22권2호
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• pp.164-170
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• 2001

The crystal structures of fully dehydrated Ni2+- and Tl+ -exchanged zeolite X (Ni17Tl58-X, and Ni12Tl68-X; X=Si100Al92O384) have been determined by single-crystal X-ray diffraction techniques in the cubic space group Fd3 at $21(1)^{\circ}C$ (a=24.380(4) $\AA$, 24.660(4) $\AA$, respectively). Their structures have been refined to the final error indices R1=0.037 and R2=0.043 with 485 reflections, and R1=0.039 and R2=0.040 with 306 reflections, respectively, for which I >36(I). In Ni17Tl58-X, 17 Ni2+ ions per unit cell were found at only two sites: 15 at site I at the center of the hexagonal prism (Ni-O=2.203(9) $\AA)$ and the remaining 2 at site II near single six-oxygen rings in the supercage (Ni-O=2.16(3) $\AA).$ Fifty-eight Tl+ ions were found at five crystallographic sites: 28 at site II (Tl-O=2.626(8) $\AA)$, 2 at site I' in the sodalite cavity near the hexagonal prism (Tl-O=2.85(1) $\AA)$, another 2 at site II' in the sodalite cavity (Tl-O=2.77(1) $\AA).$ The remaining 26 were found at two nonequivalent Ⅲ' sites with occupancies of 23 and 3. In Ni12Tl68-X, 12 Ni2+ ions per unit cell were found at two sites: 10 at site I (Ni-O=2.37(2) $\AA)$ and the remaining 2 at site II (Ni-O=2.13(2) $\AA).$ Sixty-eight Tl+ ions were found at five crystallographic sites: 28 at site II (Tl-O=2.63(1) $\AA)$, 12 at site I' (Tl-O=2.62(1) $\AA)$, 2 at site II' (Tl-O=3.01(2) $\AA)$, and the remaining 26 at two III' sites with occupancies of 23 and 3. It appears that Ni 2+ ions prefer to occupy site I and II, in that order. The large Tl+ ions occupy the remaining sites, I', II, II' and two different III' sites. In both crystals, only the Ni2+ ions at site II were reduced and migrated to the external surface of zeolite X when these crystals were treated with hydrogen gas.

• 대한화학회지
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• 제33권6호
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• pp.623-632
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• 1989

$Mn^{2+}$-치환 제올라이트 A는 가열 탈수되어도 그 구조가 열적을 안정하였다. $Mn_{4,5}Na_3-A$의 수화상태 및 탈수상태에 있어서의 골조원자, 이온 및 물분자들의 위치와 결합에너지를 몇가지 퍼텐셜 함수들을 써서 계산하여 구하였다. 탈수상태의 $Mn_{4,5}Na_3-A$에 있어서 골조원자들의 결합에너지는 열적으로 안정한 것으로 알려져 있는 탈수상태의 $Ca^{2+}$-치환 제올라이트 A($Ca_6$-A) 및 $Co^{2+}$- 치환제올라이트 A($Co_4Na_4-A$)의 그것과 비슷하였다. $Mn^{2+}$-치환 제올라이트 A 골조 내에는 결합에너지의 결합형식이 서로 다른 세 가지 그룹의 물분자들 즉 인접 물분자 또는 골조 산소원자와 수소결합을 하고 있는 물; W(I), $Na^+$이온에 배위되면서 인접 물 분자와 수소결합을 하는 물; W(II) 및 $Mn^{2+}$에 배위면서 수소결합을 하는 W(III)그룹의 물분자들이 존재하였으며 그들의 결합에너지 및 탈수반응의 활성화에너지의 크기 순서는 W(III) > W(II) > W(I)이였다.

• Bulletin of the Korean Chemical Society
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• 제28권10호
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• pp.1675-1682
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• 2007

Large colorless single crystals of faujasite-type zeolite with diameters up to 200 μm have been synthesized from gels with the composition of 3.58SiO2:2.08NaAlO2:7.59NaOH:455H2O:5.06TEA:1.23TCl. Two of these, colorless octahedron about 200 μm in cross-section have been treated with aqueous 0.1 M TlC2H3O2 and KNO3 in order to prepare Tl+- and K+-exchanged faujasite-type zeolites, respectively, and then determined the Si/Al ratio of the zeolite framework. The crystal structures of |Tl71|[Si121Al71O384]-FAU and |K53Na18|[Si121Al71O384]-FAU per unit cell, a = 24.9463(2) and 24.9211(16) A, respectively, dehydrated at 673 K and 1 × 10-6 Torr, have been determined by single-crystal X-ray diffraction techniques in the cubic space group Fd m at 294 K. The two single-crystal structures were refined using all intensities to the final error indices (using only the 905 and 429 reflections for which Fo > 4σ(Fo)) R1/R2 = 0.059/0.153 and 0.066/0.290, respectively. In the structure of fully Tl+-exchanged faujasite-type zeolite, 71 Tl+ ions per unit cell are located at four different crystallographic sites. Twenty-nine Tl+ ions fill site I' in the sodalite cavities on 3-fold axes opposite double 6-rings (Tl-O = 2.631(12) A and O-Tl-O = 93.8(4)o). Another 31 Tl+ ions fill site II opposite single 6-rings in the supercage (Tl-O = 2.782(12) A and O-Tl-O = 87.9(4)o). About 3 Tl+ ions are found at site III in the supercage (Tl-O = 2.91(6) and 3.44(3) A), and the remaining 8 occupy another site III (Tl-O = 2.49(5) and 3.06(3) A). In the structure of partially K+-exchanged faujasite-type zeolite, 53 K+ ions per unit cell are found at five different crystallographic sites and 18 Na+ ions per unit cell are found at two different crystallographic sites. The 4 K+ ions are located at site I, the center of the hexagonal prism (K-O = 2.796(8) A and O-K-O = 89.0(3)o). The 10 K+ ions are found at site I' in the sodalite cavity (K-O = 2.570(19) A and O-KO = 99.4(9)o). Twenty-two K+ ions are found at site II in the supercage (K-O = 2.711(9) A and O-K-O = 94.7(3)o). The 5 K+ ions are found at site III deep in the supercage (K-O = 2.90(5) and 3.36(3) A), and 12 K+ ions are found at another site III' (K-O = 2.55(3) and 2.968(18) A). Twelve Na+ ions also lie at site I' (Na-O = 2.292(10) and O-Na-O = 117.5(5)o). The 6 Na+ ions are found at site II in the supercage (Na-O = 2.390(17) A and O-Na-O = 113.1(11)o). The Si/Al ratio of synthetic faujasite-type zeolite is 1.70 determined by the occupations of cations, 71, in two single-crystal structures.

• 한국결정학회지
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• 제15권2호
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• pp.59-68
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• 2004

부분적으로 $Co^{2+}$ 이온으로 치환된 제올라이트 A를 진공 탈수한 후 $300^{\circ}C$에서 12시간, 6시간, 2시간 동안 각각 0.6 torr의 K증기로 반응시킨 3개의 구조$(a=12.181(1)\;{\AA},\; a=12.184(1)\;{\AA},\; a=12.215(1)\;{\AA})$를 $21^{\circ}C$에서 입방공간군 Pm3m를 사용하여 단결정 X-선 회절법으로 해석하고 정밀화한다. K 증기로 반응시킨 3개의 구조는 Full-matrix 최소자승법 정밀화 계산에서 $1>\sigma(I)$인 70, 82, 80개의 독립반사를 각각 사용하여 최종오차인자를 R (weight) = 0.090, 0.091, 0.090까지 각각 정밀화한다. 3개의 구조에서 4개의$Co^{2+}$이온과 4개의 $Na^+$이온모두 K증기에 의해서 환원되어 $Co^{2+}$ 이온과 $Na^+$ 이온은 제올라이트 내에 더 이상 생성되지 않는다. K종류는 5개의 다른 결정학적 자리에 위치하는데 3개의 $K^+$이온은 8-링의 평면에 완전히 채워져 위치하고 약 11.5개의 $K^+$ 이온은 3회 회전축상의 6-링에 위치하고 약 4개는 큰 동공, 4개는 소다라이트 동공, 0.5개는 큰 공동의 4-링과 마주보는 위치에 위치하고 3개의 $K^0$원자는 3회 회전축상의 큰 동공 깊숙이 위치한다. 이들 구조는 제올라이트 A의 소다라이트 동공에서 사면체 $K_4$ (혹은 삼각형 $K_3$) 클라스터를 이루고 있으며 $K_4$ 혹은 $K_3$ 클라스터는 6-링의 3개의 산소와 삼면체로 결합한다. 이들 클라스터의 부분적으로 환원된 이온은 제올라이트 골조 산소와 우선적으로 결합한다. 이들 구조에서 제올라이트 골조의 음전하를 상쇄시키는데 필요한 12개의 $K^+$ 이온보다 많은 단위세포당 14.5개의 K종류가 존재하는데 이들 결과로 $K^0$원자가 흡착되었음을 알 수 있다. 큰 동공 깊숙이 위치한 3개의 $K^0$ 원자는 4개의 큰 동공에 위치한 $K^+$ 이온 중 3개와 결합하여 $K_7^{4+}$클라스터를 형성하며$K_7^{4+}$ 클라스터는 골조산소와 우선적으로 결합한다.

• 한국광물학회지
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• 제4권1호
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• pp.22-31
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• 1991

세 개의 탈수한 $Ag^+$이온과 $Ca^{2+}$ 이온으로 치환한 제올라이트 $A(Ag_4Ca_4-A,\;Ag_^Ca_3-A,\;Ag_8Ca_2-A)$를 0.1 Torr의 Rb 증기로 처리한 결정구조를 공간군 Pm3m을 써서 단결정 X-선 회절법으로 결정하였다. (단위세포상수 a는 각각 $12.271(1){\AA},\;12.255(1){\AA}$ 및 $12.339(1){\AA}$이다). 이들 구조의 최종 오차인수 R(무게)는 $I>3{\rho}(I)$가 되는 130 회절반사로 0.072, 110 회절반사로 0.050 및 86 회절반사로 0.082이었다. 각각의 구조에서 Rb 종은 세개의 다른 결정학적 위치에 위치하고 있다. 즉 단위세포당 3개의 $Rb^+$이온은 8-링 중심에 위치하고 약 2.5개 내지 3.0개의 $Rb^+$이온은 소다라이트 동공내 3회 회전축상에 위치한다. 또 Ag 종이 두 개의 다른 결정학적 위치에 위치하고 약 0.7∼2.1개의 $Ag^+$이온은 4-링과 마주보는 위치에, 약 2.2∼4.8개의 Ag 원자는 큰 동공 중심 가까이에 위치한다. 이들 구조에서 단위 세포당 Ag 원자이 수는 각각 2.2, 2.4 및 4.8개이었고 이들은 큰 동공 중심에 헥사실버 클라스터를 만든다. $Rb^+$이온은 8-링을 막고 있어서 Ag가 골조 밖으로 이동하는 것을 막고 있고 각각의 헥사실버 클라스터는 13개의 $Rb^+$ 이온과 배위하여 안정화된다. 단위 세포당 약 0.8개의 Rb원자가 과잉으로 존재하여 삼각 대칭형의 $(Rb_3)^{2+}$클라스터가 소다라이트 동공내의 존재한다. 적어도 하나의 큰 동공의 6-링 $Rb^+$ 이온은 소다라이트 동공의 $(Rb_3)^{2+}$클라스터에 접근하므로 이들 클라스터는 $(Rb)_4^{3+}$, $(Rb)_5^{4+}$ 혹은 $(Rb)_6^{5+}$가 형성될 수도 있다.

• 대한치과보철학회지
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• 제45권1호
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• pp.85-97
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• 2007

Statement of problem: Recently, anodic oxidation of cp-titanium is a popular method for treatment of titanium implant surfaces. It is a relatively easy process, and the thickness, structure, composition, and the microstructure of the oxide layer can be variably modified. Moreover the biological properties of the oxide layer can be controlled. Purpose: In this study, the roughness, microstructure, crystal structure of the variously treated groups (current, voltage, frequency, electrolyte, thermal treatment) were evaluated. And the specimens were soaked in simulated body fluid (SBF) to evaluate the effects of the surface characteristics and the oxide layers on the bioactivity of the specimens which were directly related to bone formation and integration. Materials and methods: Surface treatments consisted of either anodization or anodization followed thermal treatment. Specimens were divided into seven groups, depending on their anodizing treatment conditions: constant current mode (350V for group 2), constant voltage mode (155V for group 3), 60 Hz pulse series (230V for group 4, 300V for group 5), and 1000 Hz pulse series (400V for group 6, 460V for group 7). Non-treated native surfaces were used as controls (group 1). In addition, for the purpose of evaluating the effects of thermal treatment, each group was heat treated by elevating the temperature by $5^{\circ}C$ per minute until $600^{\circ}C$ for 1 hour, and then bench cured. Using scanning electron microscope (SEM), porous oxide layers were observed on treated surfaces. The crystal structures and phases of titania were identified by thin-film x-ray diffractmeter (TF-XRD). Atomic force microscope (AFM) was used for roughness measurement (Sa, Sq). To evaluate bioactivity of modified titanium surfaces, each group was soaked in SBF for 168 hours (1 week), and then changed surface characteristics were analyzed by SEM and TF-XRD. Results: On basis of our findings, we concluded the following results. 1. Most groups showed morphologically porous structures. Except group 2, all groups showed fine to coarse convex structures, and the groups with superior quantity of oxide products showed superior morphology. 2. As a result of combined anodization and thermal treatment, there were no effects on composition of crystalline structure. But, heat treatment influenced the quantity of formation of the oxide products (rutile / anatase). 3. Roughness decreased in the order of groups 7,5,2,3,6,4,1 and there was statistical difference between group 7 and the others (p<0.05), but group 7 did not show any bioactivity within a week. 4. In groups that implanted ions (Ca/P) on the oxide layer through current and voltage control, showed superior morphology, and oxide products, but did not express any bioactivity within a week. 5. In group 3, the oxide layer was uniformly organized with rutile, with almost no titanium peak. And there were abnormally more [101] orientations of rutile crystalline structure, and bonelike apatite formation could be seen around these crystalline structures. Conclusion: As a result of control of various factors in anodization (current, voltage, frequency, electrolytes, thermal treatment), the surface morphology, micro-porosity, the 2nd phase formation, crystalline structure, thickness of the oxide layer could be modified. And even more, the bioactivity of the specimens in vitro could be induced. Thus anodic oxidation can be considered as an excellent surface treatment method that will able to not only control the physical properties but enhance the biological characteristics of the oxide layer. Furthermore, it is recommended in near future animal research to prove these results.