• 한국결정학회지
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• 제3권1호
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• pp.9-22
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• 1992

Cd2+ 이온으로 이온 교환된 제올라이트 A를 진공 탈수한 후 브롬을 흡착한 두개의 결정구조를 단결정 X-선 회절법으로 해석하였다. 이들 결정은 21℃에서 입방공간군 Pm3m을 사용하여 해석하고 정산(정산)하였다. 두 결정은 Cd(NO3)a와 Cd(OOCCH3)a의 물분율이 1 : 1이고 전체농도가 0.05M 되도록 만든 혼합용액을 이용하여 흐름법으로 이온교환하여 제조하였다. 첫번째 결정은 450℃에서 2 ×10-6 Torr의 진공하에서 2일간 탈수하였고, 두번째 결정은 650℃에서 2 ×10-sTorr 의 진공하에서 2일간 탈수하였다. 두 결정을 24℃에서 약 160Torr의 브롬증기로 반응시켰다. Fullmatrix 최소자승법 정산에서 첫번째 결정(a=12. 250(1) A)과 두번째 결정(a=12.204(2) k)의 마지막 오차인자는 I>3e(I)인 212개의 독립반사를 사용하여 Rl=0.075, R2=0.079이며 128개의 독립반사를 사용하여 Rl=0.089, R2=0.078까지 각각 정산하였다. 두 결정에서 단위세포당 6개의 Cd2+ 이온은 6-링 산소와 결합하면서 결정학적으로 서로 다른 2개의 3회 회전축상에 위치하고 있었다. 4.5개의 Cd2+이온은 Brs 혹은 Br3-의 이온과 착물을 형성하기 위해서 0(3)의 (111)평면에서 큰 동공쪽으로 약 0.441 차 들어가 있었다. 나머지 1.5개의 Cd2+이온은 0(3)의 (111)평면에서 Sodalite동공 깊숙히 약 0.678 입 들어간 자리에 위치하였다. 단위세포당 약 1.5개의 Brs-와 1.5 개의 Br3-이온이 흡착되었다. Brs-이온결합은 2 개의 Cd2+이온과 골조 산소이온과 착물을 이룸으로써 안정화되었다. Br3-이온은 한 개의 Cd2+이온 과 골조 산소이온과 결합하고 있었다. 생성된 Br3 -와 Brs-는 브롬 분자가 잔류하는 물분자와 반응하여 다음과 같이 생성할 수 있다.

• 광물과 암석
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• 제35권1호
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• pp.41-50
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• 2022

이온교환 용액내 Na⁺ 이온의 몰농도 증가에 따른 zeolite A의 Sr²⁺ 이온교환 특성을 연구하기 위하여, Sr²⁺ 및 Na⁺ 이온으로 교환된 4개의 zeolite A 단결정을 혼합 이온교환 용액을 이용하여 회분법으로 준비하였다. 이들 이온교환용액의 전체 몰농도는 0.05 M이며, Sr(NO₃)₂:NaNO₃ 몰비는 각각 1:1(crystal 1), 1:100(crystal 2), 1:250(crystal 3), and 1:500(crystal 4) 이다. 이들 단결정은 623 K와 1×10^-4 Pa의 진공하에서 2 일간 탈수 시켰다. 이들의 구조는 단결정 싱크로트론 X-선 회절법으로 입방공간군 Pm3-m을 사용하여 해석하였으며 crystals 1, 2, 3 및 4의 최종 오차 인자를 각각 0.047/0.146, 0.048/0.142, 0.036/0.128, and 0.040/0.156로 정밀화하였다. Crystal 1과 2에서는 6개의 Sr²⁺ 이온이 결정학적으로 서로 다른 3개의 위치에서 발견되었다. Crystal 3에서는 1개의 Sr²⁺ 이온과 10개의 Na⁺ 이온이 large cavity와 sodalite 내부에서 발견 되었다. Crystal 4 에서는 단지 12개의 Na⁺ 이온만이 3개의 서로 다른 결정학적 자리에 점유하고 있었다. Sr²⁺ 이온의 이온교환율은 초기 Na⁺ 이온의 농도가 증가하고 Sr²⁺ 이온의 농도가 감소함에 따라 100에서 16.7 및 0%로 급격하게 감소 하였다. 또한, Sr²⁺ 이온 교환률이 감소 함에 따라 제올라이트 골격의 단위 격자 상수 값이 갑소 하였다.

• 대한화학회지
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• 제57권1호
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• pp.12-19
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• 2013

The single-crystal structure of fully dehydrated partially $Li^+$-exchanged zeolite Y, ${\mid}Li_{50}Na_{25}{\mid}[Si_{117}Al_{75}O_{384}]$-FAU, was determined by single-crystal synchrotron X-ray diffraction techniques in the cubic space group $Fd\bar{3}m$ at 100(1) K. Ion exchange was accomplished by flowing stream of 0.1 M aqueous $LiNO_3$ for 2 days at 293 K, followed by vacuum dehydration at 623 K and $1{\times}10^{-6}$ Torr for 2 days. The structure was refined using all intensities to the final error indices (using only the 801 reflections with ($F_o$ > $4{\sigma}(F_o)$) $R_1/R_2=0.043/0.140$. The 50 $Li^+$ ions per unit cell are found at three different crystallographic sites. The 19 $Li^+$ ions occupy at site I' in the sodalite cavity: the $Li^+$ ions are recessed 0.30 ${\AA}$ into the sodalite cavity from their 3-oxygens plane (Li-O = 1.926(5) ${\AA}$ and $O-Li-O=117.7(3)^{\circ}$). The 20 $Li^+$ ions are found at site II in the supercage, being recessed 0.23 ${\AA}$ into the supercage (Li-O = 2.038(5) ${\AA}$ and $O-Li-O=118.7(3)^{\circ}$). Site III' positions are occupied by 11 $Li^+$ ions: these $Li^+$ ions bind strongly to one oxygen atom (Li-O = 2.00(8) ${\AA}$). About 25 $Na^+$ ions per unit cell are found at four different crystallographic sites: 4 $Na^+$ ions are at site I, 5 at site I', 12 at site II, and the remaining 4 at site III'.

• Bulletin of the Korean Chemical Society
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• 제5권3호
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• pp.117-121
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• 1984

The structure of $CS_{7.3}Ag_{4.7}Si_{12}Al_{12}O_{48}$, vacuum dehydrated zeolite A with all Na+ ions replaced by $Cs^+$ and $Ag^+$ as indicated, has been determined by single-crystal x-ray diffraction techniques in the cubic space group, Pm3m (a = 12.282 (1) ${\AA}$). The structure was refined to the final error indices $R_1$$R_2$ (weighted) = 0.099 using 347 independent reflections for whind intlch $I_0\;>\;3{\sigma}(I_0)$. Although deydration occurred at $360^{\circ}C$, no silver atoms or clusters have been observed. The 8-ring sites are occupied only by $Cs^+$ ion, and the 4-ring sites only by a single $Ag^+$ ion. The 6-ring sites contain $Ag^+$ and $Cs^+$ ions with $Ag^+$ nearly in 6-ring planes and $Cs^+$ well off them, one on the sodalite unit side. With regard to the 6-rings, the structure can be represented as a superposition of two types of unit cells: about 70 % have $4Ag^+$ and $4Cs^+$ ions, and the remaining 30 % have $3Ag^+$ and $5Cs^+$. In all unit cells, $3Cs^+$ ions lie at the centers of the 8-rings at sites of D4h symmetry; these ions are approximately 0.3 ${\AA}$ further from their nearest framework-oxygen neighbors than the sum of the appropriate ionic radii would indicate. To minimize electrostatic repulsions, the $Cs^+$ ions at Cs(1) are not likely to occupy adjacent 6-rings in the large cavity; they are likely to be tetrahedrally arranged when there are 4.

• 방사성폐기물학회지
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• 제1권1호
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• pp.65-72
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• 2003

원자력시설에서 방사성요오드 제거용으로 사용되는 TEDA 첨착활성탄의 고온공정에서치 메틸요오드의 제거성능을 은이온제올라이트(AgX)와 상호 비교하였다. 3$0^{\circ}C$-40$0^{\circ}C$ 온도범위에서 온도에 따른 메틸요오드의 흡착량 및 탈착후 잔존량을 측정한 결과, 비첨착활성탄의 흡착성능은 온도가 증가함에 따라 급격히 감소하지만 TEDA 첨착활성탄의 흡착성능은 10$0^{\circ}C$ 부근에서도 AgX-10과 거의 유사한 값을 나타내었고, 탈착후 잔존량은 25$0^{\circ}C$ 까지도 비첨착활성탄에 비하여 매우 높은 값을 유지하였다. 또한 10$0^{\circ}C$ 이상의 고온공정에서 AgX 및 TEDA 첨착활성탄을 충전한 고정층 파과특성을 상호 비교한 결과 10$0^{\circ}C$ 이상에서 AgX-10의 메틸요오드 흡착량 및 잔존량은 TEDA 첨착활성탄에 비하여 평균 30%정도 높은 값을 나타내어 고온에서 더 흡착성능이 우수함을 보여주고 있다. 흡착반응 후 생성된 기체의 성분을 분석한 결과를 토대로 AgX-10 흡착제를 충전한 고정층에서 메틸요오드 제거 메카니즘을 제안하였다.

• 한국응용과학기술학회지
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• 제22권1호
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• pp.28-34
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• 2005

The structure of a carbon monoxide sorption complex of dehydrated fully $Ca^{2+}$-exchanged zeolite X, $|Ca_{46}(CO)_{27}|[Si_{100}Al_{92}O_{384}]$-FAU, has been determined in the cubic space group $Fd\;{\overline{3}}$ at $21^{\circ}C$ (a = 24.970(4) ) by single-crystal X-ray diffraction techniques. The crystal was prepared by ion exchange in a flowing stream of 0.05 M aqueous ${Ca(NO_3)_2}$ for three days, followed by dehydration at $400^{\circ}C$ and $2{\times}10^{-6}$ Torr for two days, and exposure to 100 Torr of zeolitically dry carbon monoxide gas at $21^{\circ}C$. The structure was determined in this atmosphere and was refined, using the 356 reflections for which $F_o$ > $4{\sigma}(F_o)$, to the final error indices $R_1$ = 0.059 and $wR_2$ = 0.087. In this structure, $Ca^{2+}$ ions occupy three crystallographic sites. Sixteen $Ca^{2+}$ ions fill the octahedral site I at the centers of hexagonal prisms (Ca-O = 2.415(7) ${\AA}$). The remaining 30 $Ca^{2+}$ ions are found at two nonequivalent sites II (in the supercages) with occupancies of 3 and 27 ions. Each of these $Ca^{2+}$ ions coordinates to three framework oxygens, either at 2.276(10) or 2.298(8) ${\AA}$, respectively. Twenty-seven carbon monoxide molecules have been sorbed per unit cell, three per supercage. Each coordinates to one of the latter 16 site-II $Ca^{2+}$ ions: C-Ca = 2.72(8) ${\AA}$. The imprecisely determined N-C bond length, 1.26(14) ${\AA}$, differs insignificantly from that in carbon monoxide(g), 1.13 ${\AA}$.

• Bulletin of the Korean Chemical Society
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• 제32권10호
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• pp.3696-3701
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• 2011

The single-crystal structure of partially dehydrated partially $Mg^{2+}$-exchanged zeolite Y, ${\mid}Mg{30.5}Na_{14}(H_2O)_{2.5}{\mid}$ [$Si_{117}Al_{75}O_{384}$]-FAU per unit cell, ${\alpha}$ = 25.5060(1) ${\AA}$, dehydrated at 723 K and $1{\times}10^{-4}$ Pa, has been determined by single-crystal X-ray diffraction techniques in the cubic space group Fd$\bar{3}$ m at 100(1) K. The structure was refined using all intensities to the final error indices (using only the 561 reflections with $F_{\circ}$ > $4{\sigma}(F_{\circ})$) $R_1$ = 0.0377 (Based on F) and $R_2$ = 0.1032 (Based on $F^2$). About 30.5 $Mg^{2+}$ ions per unit cell are found at four different crystallographic sites. The 14 $Mg^{2+}$ ions occupy at site I at the center of double 6-ring (Mg-O = 2.231(3) ${\AA}$, O-Mg-O = $89.15(11)^{\circ}$ and $90.85(11)^{\circ}$). Four $Mg^{2+}$ ions are found at site I' in the sodalite cavity; the $Mg^{2+}$ ions are recessed 1.22 ${\AA}$ into the sodalite cavity from their 3-oxygen plane (Mg-O = 2.20(3) ${\AA}$ and O-Mg-O = $92.3(14)^{\circ}$). Site II' positions (opposite single 6-rings in the sodalite cage) are occupied by 2.5 $Mg^{2+}$ ions, each coordinated to an $H_2O$ molecule (Mg-O = 2.187(20) ${\AA}$ and O-Mg-O = $114.2(16)^{\circ}$). The 10 $Mg^{2+}$ ions are nearly three-quarters filled at site II in the supercage, being recessed 0.12 ${\AA}$ into the supercage (Mg-O = 2.123(4) A and O-Mg-O = $119.70(19)^{\circ}$). About 14 $Na^+$ ions per unit cell are found at one crystallographic site; the $Na^+$ ions are located at site II in the supercage (Na-O = 2.234(7) ${\AA}$ and O-Mg-O = $110.5(4)^{\circ}$).

• Bulletin of the Korean Chemical Society
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• 제9권6호
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• pp.338-341
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• 1988

Two crystal structures of fully dehydrated silver and potassium exchanged zeolite A, stoichiometries of $Ag_{9.3}K_{{2.7}^-}A$ (${\alpha}$ = 12.282(2) ${\AA}$) and $Ag_{10.7}K_{{1.3}^-}{\AA}$ (${\alpha}$ = 12.287(2) A) per unit cell, have been determined from 3-dimensional x-ray diffraction data gathered by counter methods. All structures were solved and refined in the cubic space group Pm3m at 21(1)$^{\circ}C$ . The crystals of $Ag_{9.3}K_{{2.7}^-}A$ and $Ag_{10.7}K_{{1.3}^-}A$ were prepared by flow method using exchange solutions in which mole ratios of $AgNO_3$ and $KNO_3$ were 1:10 and 1:5, respectively, with total concentration of 0.05M. The structures of the dehydrated $Ag_{9.3}K_{{2.7}^-}A$ and $Ag_{10.7}K_{{1.3}^-}A$ were refined to yield the final error indices $R_1$ = 0.037 and $R_2$ = 0.040 with 321 reflections, and $R_1$ = 0.042 and $R_2$ = 0.043 with 371 reflections, repectively, for which I > 3${\sigma}$(I). In both structures, eight $Ag^+$ ions are found nearly at 6-ring centers and each $Ag^+$ ion is nearly in the (1 1 1) plane at its O(3) ligands. The 8-ring sites are preferentially occupied by $K^+$ ions in both structures. 1.3 and 1.7 reduced silver atoms per unit cell were found inside of sodalite units of $Ag_{9.3}K_{{2.7}^-}A$ and that of $Ag_{10.7}K_{{1.3}^-}A$, respectively. These reduced silver species were presumably formed from the reduction of $Ag^+$ ions by oxide ions of residual water molecule or of the zeolite framework. These two crystals may be presented as hexasilver cluster in 21.7% and 28.3% of sodalite unit cells for $Ag_{9.3}K_{{2.7}^-}A$ and $Ag_{10.7}K_{{1.3}^-}A$, repectively.

• Korean Chemical Engineering Research
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• 제51권5호
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• pp.531-535
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• 2013

철 이온을 담지시킨 BEA 제올라이트에서 $N_2O$가 분해되는 반응을 조사하여 열처리 온도가 촉매의 활성에 미치는 영향을 고찰하였다. $N_2O$ 분해 반응 실험 결과, Fe/BEA 촉매에 대한 열처리 온도가 증가함에 따라 $N_2O$ 분해 활성이 현저히 줄어들었다. 열처리 온도의 증가에 따른 Fe/BEA 촉매의 입자모양 및 크기의 변화는 크지 않았지만, 열처리 온도 증가에 따라 비표면적이 크게 줄어들었다. 또한 열처리온도가 증가함에 따라 ${\beta}$ 구조의 결정성이 크게 낮아지는 것을 확인하였고, 열처리 온도가 높아질수록 SiO 구조는 증가하거나 크게 변화가 없는 반면, Fe가 골격구조와 결합된 구조는 감소하는 것으로 판단되었다. 이와 같은 결과로 열처리 온도의 증가에 따라 알루미늄과 Fe가 결합된 ${\beta}$ 구조가 붕괴되어 $N_2O$ 분해활성이 크게 저하되는 것으로 사료된다.

• Bulletin of the Korean Chemical Society
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• 제22권1호
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• pp.30-36
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• 2001

The crystal structures of fully dehydrated $Pd^{2+}$ - and $TI^{+}$ -exchanged zeolite X, $Pd_{18}TI_{56}Si_{100}Al_{92}O_{384}(Pd_{18}TI_{50-}X$, a = $24.935(4)\AA$ and $Pd_{21}TI_{50}Si_{100}Al_{92}O_{384}(Pd_{21}TI_{50-}X$ a = $24.914(4)\AA)$, have been determined by single-crystal X-ray diffraction methods in the cubic space group Fd3 at $21(1)^{\circ}C.$ The crystals were prepared using an exchange solution that had a $Pd(NH_3)_4Cl_2\;:TINO_3$ mole ratio of 50 : 1 and 200 : 1, respectively, with a total concentration of 0.05M for 4 days. After dehydration at $360^{\circ}C$ and 2 ${\times}$$10^{-6}$ Torr in flowing oxygen for 2 days, the crystals were evacuated at $21(1)^{\circ}C$ for 2 hours. They were refined to the final error indices $R_1$ = 0.045 and $R_2$ = 0.038 with 344 reflections for $Pd_{18}Tl_{56-}X$, and $R_1$ = 0.043 and $R_2$ = 0.045 with 280 reflections for $Pd_{21}Tl_{50-}X$; I > $3\sigma(I).$ In the structure of dehydrated $Pd_{18}Tl_{56-}X$, eighteen $Pd^{2+}$ ions and fourteen $TI^{+}$ ions are located at site I'. About twenty-seven $TI^{+}$ ions occupy site II recessed $1.74\AA$ into a supercage from the plane of three oxygens. The remaining fifteen $TI^{+}$ ions are distributed over two non-equivalent III' sites, with occupancies of 11 and 4, respectively. In the structure of $Pd_{21}Tl_{50-}X$, twenty $Pd^{2+}$ and ten $TI^{+}$ ions occupy site I', and one $Pd^{2+}$ ion is at site I. About twenty-three $TI^{+}$ ions occupy site II, and the remaining seventeen $TI^{+}$ ions are distributed over two different III' sites. $Pd^{2+}$ ions show a limit of exchange (ca. 39% and 46%), though their concentration of exchange was much higher than that of $TI^{+}$ ions. $Pd^{2+}$ ions tend to occupy site I', where they fit the double six-ring plane as nearly ideal trigonal planar. $TI^{+}$ ions fill the remaining I' sites, then occupy site II and two different III' sites. The two crystal structures show that approximately two and one-half I' sites per sodalite cage may be occupied by $Pd^{2+}$ ions. The remaining I' sites are occupied by $TI^{+}$ ions with Tl-O bond distance that is shorter than the sum of their ionic radii. The electrostatic repulsion between two large $TI^{+}$ ions and between $TI^{+}$ and $Pd^{2+}$ ions in the same $\beta-cage$ pushes each other to the charged six-ring planes. It causes the Tl-O bond to have some covalent character. However, $TI^{+}$ ions at site II form ionic bonds with three oxygens because the super-cage has the available space to obtain the reliable ionic bonds.