Syntheses, structures, photochromic and photocatalytic properties of two viologen-polyoxometalate hybrid materials

Huirong LIU Hao XU Dunru ZHU Junyong ZHANG Chunhua GONG Jingli XIE

Citation:  Huirong LIU, Hao XU, Dunru ZHU, Junyong ZHANG, Chunhua GONG, Jingli XIE. Syntheses, structures, photochromic and photocatalytic properties of two viologen-polyoxometalate hybrid materials[J]. Chinese Journal of Inorganic Chemistry, 2024, 40(7): 1368-1376. doi: 10.11862/CJIC.20240066 shu

两个紫精-多酸杂化材料的合成、结构及其光致变色和光催化性质

    通讯作者: 朱敦如, zhudr@njtech.edu.cn
    宫春华, gongch@jxnhu.edu.cn
    谢景力, jlxie@mail.zjxu.edu.cn
  • 基金项目:

    国家自然科学基金 21771088

    浙江省自然科学基金 LY20B010005

摘要: 分别利用1, 1'-二甲基-4, 4'-联吡啶(甲基紫精, MV)二氯化物和1, 1'-二乙基-4, 4'-联吡啶(乙基紫精, EV)二溴化物的阳离子作为电子受体, 富电子的杂多酸阴离子作为电子给体, 合成了2个新的紫精-多酸杂化晶态材料: (MV)2[HPW2W10O40]·2H2O (1)和(EV)2[Mo8O26] (2), 并解析了其单晶结构, 在化合物 12中, 阴、阳离子间均存在氢键相互作用。2具有光致变色性能, 光响应时间为1 min以内。通过固体漫反射、电子顺磁共振和理论计算等手段, 探究了2的光致变色机理。12对光降解有机染料(亚甲蓝、盐酸副玫瑰苯胺和罗丹明6G)均具有一定的催化性能。

English

  • Photochromic materials with colour change induced by light have received widespread attention because of their important application in optical infor mation storages, optical switches, optical control mate rials and so on[1-4]. Among the materials, inorganic polyoxometalate (POM) is one of the notable photochromic compounds due to its exceptional redox properties, pho toactivities, and thermal stabilities[5-9]. However, it is still difficult to synthesize the pure POM with improved photochromic performance[10]. On the other hand, pure organic photochromic materials often show poor fatigue resistance and high-temperature resistance despite they have fast response time and rich colours. In con trast, organic-inorganic hybrid photochromic materials can not only maintain the advantages of the organic and inorganic components but also generate new prop erties due to the synergistic effect between the organic and inorganic units[11-16].

    As an important photochromic material, viologen compounds usually act as electron acceptors and show a potential application in the fields of photochemical devices, optoelectronics, and inkless printing[17-21]. Recently, viologen-POM hybrids as a new kind of photochromic materials have garnered increasing atten tion due to their structural diversities and good photo thermal stabilities[22-25]. For example, in 2021, Zheng et al. reported a novel metalloviologen-POM hybrid, [Co (H2O)6]2[Co3(bpdo)4(H2O)10] [Co4(H2O)2(B-α-PW9O34)2] · 2bpdo·14H2O (bpdo=4, 4′-bipyridyl-N, N′-dioxide), which exhibits tunable thermochromic properties and reversible structural transformations in single-crystal-to-single-crystal fashion and can be used as a nonvolatile memristor with unique temperature-regulated resis tive switching behaviours[26]. In 2020, Zhang et al. syn thesized a new viologen-POM hybrid, (Pbpy)(Me2NH2)3 [PW11ZnO40] (Pbpy=1, 1′-[1, 4-phenylene-bis(methy lene)]bis(4, 4′-bipyridinium)), which can be used as a multifunctional material for rapid solar ultraviolet (UV) light detection, photoluminescence-based UV probing and inkless and erasable printing[27]. In 2022, Wang et al. synthesized three viologen-POM hybrids, [Ag(bmypd)0.5(β-Mo8O26)0.5] (bmypd=1, 1′-[biphenyl-4, 4′-bis(methylene)]bis(4, 4′-bipyridyinium)), [Ag2(bypy)4 (HSiW12O40)2] ·14H2O and [Ag(bypy) (γ-Mo8O26)0.5] (bypy=1-benzyl-4, 4′-bipyridyinium), which can be used as the photochromic materials for UV probing, amine detecting and inkless and erasable printing[28]. Furthermore, POMs can be integrated into the frame work of Prussian blue through various interactions including ionic electrostatic attraction, π···π stacking and hydrogen bonding. These integrations can provide rich structural tunable methods for preparation of the functional hybrid materials. Moreover, the combination of viologen and POMs can promote electron transfers, which will not only enhance the photochromic perfor mance but also expand the application fields of the cor responding hybrid materials[29-31].

    Based on the above consideration, herein, by using the cations of 1, 1′-dimethyl-4, 4′-bipyridinium (MV) dichloride (MV·2Cl) and 1, 1′-diethyl-4, 4′-bipyri-dinium (EV) dibromide (EV·2Br) to combine with the different POM anions, two new viologen-POM hybrid materials: (MV)2[HPW2W10O40] ·2H2O (1) and (EV)2 [Mo8O26] (2) have been synthesized successfully. Single-crystal structural analyses revealed that there are rich hydrogen bond interactions between the cations and the anions in 1 and 2. Intriguingly, 2 exhibits sensitive photochromic properties with a response time of 1 min. In addition, both 1 and 2 display good catalytic activi ties in the photocatalytic degradation of several organic dyes such as methylene blue (MB), pararosaniline hydrochloride (PH), and rhodamine 6G (R6G).

    All the chemicals were received as AR grade and used without further purification. IR spectra were recorded on a Varian 640 FT-IR spectrometer with KBr pellets in a range of 4 000-400 cm-1. Powder X-ray diffraction (PXRD) pattern was collected on a DX-2600 spectrometer with Mo radiation (λ=0.071 073 nm) at room temperature (U=40 kV, I=30 mA, 2θ=5°-50°). Thermogravimetric analyses (TGA) were carried out under N2 flow on an SDT 2960 differential thermal ana lyzer with a rate of 10 ℃·min-1. Solid-state UV-Vis diffused reflection spectra were conducted using a Cary5000 UV-Vis spectrophotometer. Electron spin resonance (ESR) spectra were performed with a Bruker EMX spectrometer at an X-band frequency (100 kHz) under a high pure N2 atmosphere.

    MV·2Cl (12.8 mg, 0.05 mmol) and H3PW12O40· xH2O (71.4 mg, 0.025 mmol) in a 5 mL solution of methanol and water were added to a 15 mL Teflonlined autoclave. After 30 min of ultrasonic vibration, the closed reactor was placed in an oven and heated at 160 ℃ for 72 h. After cooling to room temperature, black square crystals were filtered and washed with ethanol and deionized water to obtain compound 1. Yield: 37.6% based on MV·2Cl. Anal. Calcd. for C24H33N4O42PW12 (%): C, 8.77; H, 1.01; N, 1.71. Found (%): C, 8.64; H, 0.92; N, 1.56. IR (KBr disc, cm-1): 3 447 (m, br), 3 054 (w), 2 917 (w), 1 639 (m), 1 187 (w), 1 061 (s), 957 (s), 884 (s), 802 (vs), 671 (m).

    EV·2Br (18.7 mg, 0.05 mmol), (NH4)6Mo7O24· 4H2O (37 mg, 0.3 mmol) and AgNO3 (3.4 mg, 0.02 mmol) in 20 mL water were added to a 25 mL Teflonlined autoclave, and the pH value of solution was adjusted to 5 by using NH3·H2O. After heating at 160 ℃ for 72 h, yellow square crystals of compound 2 were obtained. Yield: 67.4% based on EV·2Br. Anal. Calcd. for C28H36Mo8N4O26 (%): C, 20.86; H, 2.25; N, 3.48. Found (%): C, 20.90; H, 2.37; N, 3.59. IR (KBr disc, cm-1): 3 423 (m, br), 3 059 (m), 1 635 (s), 1 448 (m), 1 169 (m), 932 (vs), 837 (s), 798 (s), 661 (s).

    The single-crystal X-ray diffraction data of compound 1 were collected on a Bruker D8 QUEST instrument equipped with graphite-monochromated Cu radiation (λ =0.154 184 nm) at 296 K. The single-crystal data of compound 2 were collected on an Oxford Diffraction Gemini R Ultra diffractometer with graphite monochromated Mo (λ=0.071 073 nm) at 296.15 K. Structures were solved by SHELXS (direct methods) and refined by SHELXL (full-matrix least-squares techniques) in the Olex2 package. Crystal data and structure refinements of 1 and 2 are provided in Table S1 (Supporting information). Selected bond lengths and angles are listed in Table S2 and S3.

    The hybrid materials 1 and 2 (30 mg) were added into the 50 mL aqueous solution of MB, PH and R6G (6 mg·L-1), then the obtained suspensions were magnetically stirred in the dark for about 30 min to ensure the equilibrium of working solution. The solution was then exposed to UV irradiation from a 100 W Hg lamp (λ= 365 nm). The solution was kept stirring during irradiation. At given time intervals, 2 mL of the sample was taken out for analysis.

    Single-crystal structural analysis reveals that compound 1 crystallizes in a triclinic P1 space group, and the asymmetric unit comprises two MV2+ cations, two [H0.5P0.5WW5O20]2- units and two lattice water molecules (Fig. 1a). A lot of hydrogen bonding interactions have been observed between the MV2+ cations and the [HPW2W10O40]4- anions with the C—H···O distances in a range of 0.318-0.355 nm (Table 1). The water molecules are linked to the POM anions by four kinds of O—H···O hydrogen bonds (Fig. 2a and Table 1). These hydrogen bonding interactions connect the MV2+ cations and POM anions to form a 2D plane (Fig. 2b) and finally a 3D supramolecular network (Fig. 2c).

    Figure 1

    Figure 1.  Structures of the asymmetric units of compounds 1 (a) and 2 (b)

    All hydrogen atoms except water and the disordered atoms are omitted for clarity.

    Figure 2

    Figure 2.  (a) Hydrogen-bond interactions in compound 1; (b) View of a 2D layer; (c) 3D network along the a-axis

    Symmetry codes: 1-x, -y, 1-z; -x, -y, -z; -x, 2-y, 1-z; x, 1+y, 1+z; 1 -x, 1-y, 1-z; x, y, 1+z; x, 1+y, z; 1+x, y-1, z.

    Table 1

    Table 1.  Hydrogen-bonding parameters of compound 1
    下载: 导出CSV
    D—H···A d(D—H) / nm d(H···A) / nm d(D···A) / nm ∠D—H···A / (°)
    O1W—H1WA···O5 0.085 0.221 0.301(4) 157
    O1W—H1WB···O7 0.085 0.244 0.327(4) 166
    O2W—H2WA···O27 0.085 0.201 0.284(4) 166
    O2W—H2WB···O29 0.085 0.217 0.295(5) 151
    C2—H2···O11 0.093 0.236 0.328(4) 171
    C3—H3···O2W 0.093 0.269 0.345(6) 140
    C5—H5···O2 0.093 0.239 0.331(4) 171
    C6—H6···O1 0.093 0.257 0.318(5) 123
    C7—H7A···O37 0.096 0.255 0.345(5) 157
    C7—H7B···O36 0.096 0.259 0.322(4) 123
    C9—H9···O27 0.093 0.242 0.317(4) 138
    C11—H11···O2 0.093 0.252 0.343(4) 167
    C12—H12···O32 0.093 0.265 0.339(4) 137
    C13—H13C···O32 0.096 0.264 0.346(4) 144
    C15—H15···O16 0.093 0.245 0.330(4) 152
    C17—H17···O38 0.093 0.262 0.355(4) 177
    C19—H19A···O12 0.096 0.252 0.332(4) 141
    C19—H19C···O3 0.096 0.248 0.320(5) 132
    C20—H20···O14 0.093 0.264 0.330(4) 128
    C21—H21···O5 0.093 0.265 0.341(4) 139
    C23—H23···O38 0.093 0.247 0.333(4) 154
    C24—H24···O39 0.093 0.250 0.323(3) 136
    Symmetry codes: 1-x, -y, 1-z; -x, -y, -z; -x, 2-y, 1-z; x, 1+y, 1+z; 1-x, 1-y, 1-z; x, y, 1+z; x, 1+y, z; 1+x, y-1, z.

    Compound 2 crystallizes in a monoclinic P21/n space group. The asymmetric unit contains a half of [Mo8O26]4- unit and an EV2+ cation (Fig. 1b). The Mo8 unit exhibits a classic α-type [Mo8O26]4- anion. As shown in Fig. 3a, each EV2+ cation is connected to six neighbouring [Mo8O26]4- ions via the C—H···O hydrogen bonding interactions (Table 2). These hydrogen bonding interactions connect the EV2+ cations and [Mo8O26]4- anions to form a 3D supramolecular network (Fig. 3b).

    Figure 3

    Figure 3.  (a) Hydrogen bonding interactions of compound 2; (b) 3D network along the a-axis

    Symmetry codes: x-0.5, 1.5-y, 0.5+z; x-1, y, z; 1-x, 1-y, 2-z; 1-x, 2-y, 2-z; x, 1+y, z; 1.5-x, 0.5+y, 1.5-z; x-0.5, 1.5-y, z-0.5.

    Table 2

    Table 2.  Hydrogen-bonding parameters of compound 2
    下载: 导出CSV
    D—H···A d(D—H) /nm d(H···A) /nm d(D···A) /nm ∠D—H···A /(°)
    C2—H2A···O8 0.097 0.253 0.325(3) 131
    C2—H2B···O5 0.097 0.243 0.324(2) 141
    C3—H3···O4 0.093 0.238 0.309(2) 133
    C4—H4···O11 0.093 0.242 0.332(2) 161
    C5—H5···O9 0.093 0.269 0.338(3) 132
    C6—H6···O8 0.093 0.258 0.331(3) 136
    C9—H9···O10 0.093 0.244 0.318(3) 136
    C10—H10···O9 0.093 0.269 0.350(2) 146
    C11—H11···O13 0.093 0.253 0.346(2) 177
    C12—H12···O12 0.093 0.251 0.310(2) 122
    C13—H13B···O8 0.097 0.248 0.338(3) 154
    C14—H14A···O9 0.096 0.248 0.327(3) 139
    C14—H14C···O4 0.096 0.249 0.334(3) 148
    Symmetry codes: x-0.5, 1.5-y, 0.5+z; x-1, y, z; 1-x, 1-y, 2-z; 1-x, 2-y, 2-z; x, 1+y, z; 1.5-x, 0.5+y, 1.5-z; x-0.5, 1.5-y, z-0.5.

    It is noticeable that the bipyridyl rings in compound 1 are almost in a plane with the dihedral angles of 12.5(2)° and 14.2(2)° for the bipyridyl with N3/N4 and N1/N2 atoms, respectively, while the bipyridyl rings in compound 2 are non-planar due to a large dihedral angle of 58.5(2)°.

    IR spectra of compounds 1 and 2 are shown in Fig. S1. As for 1, a broad peak at 3 447 cm-1 is attributed to the O—H vibration of water. The weak peak at 2 917 cm-1 is assigned to the C—H stretching vibration. A band at 1 639 cm-1 can be attributed to the —C=N stretching vibration of the pyridyl ring. In addition, the four bands at 957, 884, 802 and 671 cm-1 are the characteristic peaks of the [HPW2W10O40]4- anion. As for 2, the weak peak at 2 978 cm-1 is assigned to the C—H stretching vibration. A band at 1 636 cm-1 can be attributed to the —C=N stretching vibration of the pyridyl ring. In addition, the four bands at 932, 837, 798 and 661 cm-1 are the characteristic peaks of the [Mo8O26]4- unit.

    As shown in Fig. S2, the PXRD patterns of as-synthesized samples of compounds 1 and 2 were consistent with the simulated results, demonstrating the high phase purity of the bulk samples.

    The photochromic properties of compounds 1 and 2 were studied in detail. When 1 and 2 were exposed to a 300 W mercury lamp at room temperature, the colour of 1 did not change significantly, while 2 showed a sensitive colour change from yellow to grey within 1 min to give sample 2g (Fig. 4). When the sample 2g was heated at 120 ℃ for 1 h, its colour turned into a faint yellow (2-decoloured). The sample 2-decoloured can change back to 2g after being illuminated again. These changes have been demonstrated by solid-state UV-Vis spectra (Fig. 5a). In addition, at the same illumination under the nitrogen atmosphere, 2 can also show the same colour change, indicating that the photochromism of 2 is not affected in the presence of oxygen (Fig.S4).

    Figure 4

    Figure 4.  Transformation among samples 2, 2g and 2-decoloured and their colour changes

    Figure 5

    Figure 5.  (a) Solid-state UV-Vis spectra of 2 and 2g; (b) ESR spectra of 2 and 2g

    To clarify the photochromic mechanism of compound 2, ESR spectra and theoretical calculations were carried out. Before illumination, 2 did not show any ESR signal. However, when 2 was exposed to a mercury lamp, an obvious ESR peak appeared immediately with g=2.005 7, which can be attributed to EV+· radical (Fig. 5b) [32], revealing that there is an electron transfer between the cation and anion. As we know from the crystal structure analysis, the most favourable electron transfer path between the [Mo8O26]4- anion and the EV2+ cation is from the O atom of POM to the N atom of pyridine. As shown in Fig. 6a, there is a strong p···π interaction between the O2 of POM and the pyridyl (py) ring with a distance of 0.291 nm for O2···π (N2-py) and 0.309 nm for O2···π (N1-py), which is significantly shorter than the known distance (0.382 nm) of the related electron donor and acceptor[33]. Moreover, further evidence can be obtained from the theoretical calculation of electrostatic potential on the surface of molecules. As shown in Fig. 6b, the red region around the EV2+ cation and the blue region around the POM anion represent the electron-deficient and electron-rich units, respectively[22, 34-35]. This result indicated that the POM anion is a good electron donor, the EV2+ cation is a good electron acceptor, and electron transfer can occur easily between the anion and cation under light. Therefore, the photochromic mechanism of 2 is due to the photo-induced electron transfer.

    Figure 6

    Figure 6.  (a) p···π interactions between the O2 of POM and the py ring in compound 2; (b) Surface electrostatic potential diagram of 2

    Symmetry codes: 1-x, 1-y, 2-z; x, 1+y, z; Materials Studio 2020 version; the GGA‑ PBE function was used to calculate the electrostatic potential of the system on the DNP basis set, with other settings set to the default Fine accuracy of the system.

    It is worthwhile to note that the viologen-POM hybrids have seldom been observed to be used as photocatalysts for the degradations of organic dyes up to now[16]. Hence, it is interesting to explore the photocatalytic activities of compounds 1 and 2 in the degradations of organic dyes like MB, PH and R6G under light irradiation. Our preliminary experimental results indicated that the absorption peaks of MB, PH and R6G decreased to some extent as time went by (Fig. S5). Based on these results, the time-dependent concentration changes of the dyes with UV irradiation in the presence of 1 and 2 can be calculated and shown in Fig. 7a. As shown in Fig. 7b, after irradiation for 2 h on MB and PH, and 80 min on R6G solution, the degradation rates of MB, PH, R6G by 1 were 96.4%, 40.9% and 94.2%, respectively. The corresponding values by 2 were 83.0%, 96.6% (100 min) and 66.1%, respectively. 1 shows an efficient photodegradation on both MB and R6G dyes, while 2 exhibits an excellent photodegradation performance on the PH solution. Notably, the photocatalytic activities of 1 and 2 are at the top as compared with the other related photocatalysts (Table S4). Furthermore, the structural stabilities of 1 and 2 after the photodegradation are still maintained, as confirmed by the PXRD patterns (Fig.S6).

    Figure 7

    Figure 7.  (a) Time-dependent concentration changes of the dye (MB, PH and R6G) solutions with UV irradiation in the presence of compounds 1 and 2; (b) Degradation rates of the dyes by 1 and 2

    Two viologen-POM hybrid materials, (MV)2 [HPW2W10O40]2·2H2O (1) and (EV)2[Mo8O26] (2) have been synthesized by using the MV2+ and EV2+ cations to combine with the POM anions. 2 shows a sensitive photochromic change with a response time of 1 min. 1 indicates an efficient photodegradation on both MB and R6G dyes, while 2 exhibits an excellent photodegradation performance on PH dye. This result may provide a general method to prepare promising organic-inorganic hybrids with good functions.


    Supporting information is available at http://www.wjhxxb.cn
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  • Figure 1  Structures of the asymmetric units of compounds 1 (a) and 2 (b)

    All hydrogen atoms except water and the disordered atoms are omitted for clarity.

    Figure 2  (a) Hydrogen-bond interactions in compound 1; (b) View of a 2D layer; (c) 3D network along the a-axis

    Symmetry codes: 1-x, -y, 1-z; -x, -y, -z; -x, 2-y, 1-z; x, 1+y, 1+z; 1 -x, 1-y, 1-z; x, y, 1+z; x, 1+y, z; 1+x, y-1, z.

    Figure 3  (a) Hydrogen bonding interactions of compound 2; (b) 3D network along the a-axis

    Symmetry codes: x-0.5, 1.5-y, 0.5+z; x-1, y, z; 1-x, 1-y, 2-z; 1-x, 2-y, 2-z; x, 1+y, z; 1.5-x, 0.5+y, 1.5-z; x-0.5, 1.5-y, z-0.5.

    Figure 4  Transformation among samples 2, 2g and 2-decoloured and their colour changes

    Figure 5  (a) Solid-state UV-Vis spectra of 2 and 2g; (b) ESR spectra of 2 and 2g

    Figure 6  (a) p···π interactions between the O2 of POM and the py ring in compound 2; (b) Surface electrostatic potential diagram of 2

    Symmetry codes: 1-x, 1-y, 2-z; x, 1+y, z; Materials Studio 2020 version; the GGA‑ PBE function was used to calculate the electrostatic potential of the system on the DNP basis set, with other settings set to the default Fine accuracy of the system.

    Figure 7  (a) Time-dependent concentration changes of the dye (MB, PH and R6G) solutions with UV irradiation in the presence of compounds 1 and 2; (b) Degradation rates of the dyes by 1 and 2

    Table 1.  Hydrogen-bonding parameters of compound 1

    D—H···A d(D—H) / nm d(H···A) / nm d(D···A) / nm ∠D—H···A / (°)
    O1W—H1WA···O5 0.085 0.221 0.301(4) 157
    O1W—H1WB···O7 0.085 0.244 0.327(4) 166
    O2W—H2WA···O27 0.085 0.201 0.284(4) 166
    O2W—H2WB···O29 0.085 0.217 0.295(5) 151
    C2—H2···O11 0.093 0.236 0.328(4) 171
    C3—H3···O2W 0.093 0.269 0.345(6) 140
    C5—H5···O2 0.093 0.239 0.331(4) 171
    C6—H6···O1 0.093 0.257 0.318(5) 123
    C7—H7A···O37 0.096 0.255 0.345(5) 157
    C7—H7B···O36 0.096 0.259 0.322(4) 123
    C9—H9···O27 0.093 0.242 0.317(4) 138
    C11—H11···O2 0.093 0.252 0.343(4) 167
    C12—H12···O32 0.093 0.265 0.339(4) 137
    C13—H13C···O32 0.096 0.264 0.346(4) 144
    C15—H15···O16 0.093 0.245 0.330(4) 152
    C17—H17···O38 0.093 0.262 0.355(4) 177
    C19—H19A···O12 0.096 0.252 0.332(4) 141
    C19—H19C···O3 0.096 0.248 0.320(5) 132
    C20—H20···O14 0.093 0.264 0.330(4) 128
    C21—H21···O5 0.093 0.265 0.341(4) 139
    C23—H23···O38 0.093 0.247 0.333(4) 154
    C24—H24···O39 0.093 0.250 0.323(3) 136
    Symmetry codes: 1-x, -y, 1-z; -x, -y, -z; -x, 2-y, 1-z; x, 1+y, 1+z; 1-x, 1-y, 1-z; x, y, 1+z; x, 1+y, z; 1+x, y-1, z.
    下载: 导出CSV

    Table 2.  Hydrogen-bonding parameters of compound 2

    D—H···A d(D—H) /nm d(H···A) /nm d(D···A) /nm ∠D—H···A /(°)
    C2—H2A···O8 0.097 0.253 0.325(3) 131
    C2—H2B···O5 0.097 0.243 0.324(2) 141
    C3—H3···O4 0.093 0.238 0.309(2) 133
    C4—H4···O11 0.093 0.242 0.332(2) 161
    C5—H5···O9 0.093 0.269 0.338(3) 132
    C6—H6···O8 0.093 0.258 0.331(3) 136
    C9—H9···O10 0.093 0.244 0.318(3) 136
    C10—H10···O9 0.093 0.269 0.350(2) 146
    C11—H11···O13 0.093 0.253 0.346(2) 177
    C12—H12···O12 0.093 0.251 0.310(2) 122
    C13—H13B···O8 0.097 0.248 0.338(3) 154
    C14—H14A···O9 0.096 0.248 0.327(3) 139
    C14—H14C···O4 0.096 0.249 0.334(3) 148
    Symmetry codes: x-0.5, 1.5-y, 0.5+z; x-1, y, z; 1-x, 1-y, 2-z; 1-x, 2-y, 2-z; x, 1+y, z; 1.5-x, 0.5+y, 1.5-z; x-0.5, 1.5-y, z-0.5.
    下载: 导出CSV
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  • 发布日期:  2024-07-10
  • 收稿日期:  2024-02-27
  • 修回日期:  2024-05-27
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