DL-Serine covalently modified multinuclear lanthanide-implanted arsenotungstates with fast photochromism

Kangting Zheng Bingxue Niu Cunmeng Lin Yizhen Song Pengtao Ma Jingping Wang Jingyang Niu

Citation:  Kangting Zheng, Bingxue Niu, Cunmeng Lin, Yizhen Song, Pengtao Ma, Jingping Wang, Jingyang Niu. DL-Serine covalently modified multinuclear lanthanide-implanted arsenotungstates with fast photochromism[J]. Chinese Chemical Letters, 2023, 34(2): 107238. doi: 10.1016/j.cclet.2022.02.043 shu

DL-Serine covalently modified multinuclear lanthanide-implanted arsenotungstates with fast photochromism

English

  • The organic-inorganic hybrid polyoxometalates (POMs) are a class of molecular-based nanomaterials with required morphologies and functionalities, which show excellent physical and chemical properties [1-4]. Among them, carboxylate covalently modified POM derivatives have received more and more attention in recent years owing to the performance advantages of both organic components and POMs groups, which have broad application prospects in the fields of catalysis, optoelectronic functional material, owing to excellent photoelectric and photochromic properties [5, 6]. Carboxylates can be considered to be involved in the backbone of POMs as the following characteristics: (1) multiple coordination modes of the carboxyl, where a carboxylate group can coordinate to one or two metal centers; (2) diverse types, mono-, di- or multiple carboxyl group in one carboxylate ligand; (3) as flexible aliphatic ligand or rigid aromatic carboxylate ligand; (4) as a template agent for modulating the structure. More importantly, the carboxylate ligand covalently binding to the POM cluster significantly disperses the surface electronegativity of the polyoxoanion skeleton, and gives rise to strong d-pπ interactions for improving the structural stability and photoreactivity of the POMs [1, 7].

    At present, the carboxylate covalently modified POM derivatives have mostly focused on polyoxovanadates and polyoxomolybdates [7, 8]. Some impressive examples of carboxylate covalently modified polyoxovanadates have been made such as nano-sized cage-like (NH2Me2)12[(V5O9Cl)6(NDC)12]·(DMF)8(CH3CH2OH)0.5, (NH2Et2)8{[V6O6(OCH3)9(SO4)]4(BDC)6}·(DEF)2, and high nuclear polyoxoanion [V17VV12IV(OH)4O60(OOC(CH2)4COO)8]7‒ [9-12].

    Carboxylate covalently modified polyoxomolybdates are one of the most widely studied carboxylate functionalized POMs derivatives nowadays [7]. For example, the formate modified giant molecular cluster [{MoV2O4(HCOO)}30{(Mo)Mo5O21(H2O)6}12]42‒ (Mo132) was reported in 1999 [13]. In 2002, Kortz et al. addressed a series of amino acid modified polyoxomolybdates [XMo6O21(O2CRNH3)3]n– (n = 2, X = Se4+, Te4+; n = 3, X = As3+, Sb3+, B3+; R = methylene, ethylene, cyclopropane, CHCH3, CH(CH2)4NH2) [14]. Since 2013, our group had launched the assembly system based heteropololymolybdate building units [XMo6O21]n– (X = HP3+, As3+, Sb3+, Se4+, Te4+) with various aliphatic and aromatic carboxylate groups (from monocarboxylate, dicarboxylate to multicarboxylate), generating many carboxylate covalently modified heteropolymolybdates with abundant architectures featuring from monomer, dimeric, to hexameric clusters [15-19]. Among them, multiple examples of carboxylate covalently modified heteropolymolybdate displayed significant photochromic properties [16, 18, 19].

    By comparison, the carboxylate covalently modified polyoxotungstates are relatively rare, mainly because the reaction activity between polyoxotungstates fragments and carboxylate group is comparatively weak [7]. In this branch, Boskovic's group had made more contributions. They synthesized a series of carboxylate covalently modified arsenotungstates [{Ln(H2O)3}2{As2W19O68} {WO2(L)}2]8– (Ln = Y3+, L = PdcH, Mcpc; Ln = Dy3+, L = Pic), [As4(M4)MoxVIW44–xVIY4O160(L)y(H2O)z]n– (M = combination of Mo, W and Y; L = Nle or Gly) and [As4(YW3)W44Y4O159(Gly)8(H2O)14]9– [20-23]. Li's group reported a tetrameric alanine modified arsenotungstate [Ce4As4W44O151(ala)4(OH)2(H2O)10]12‒ [24]. Our group had also prepared several examples of carboxylate covalently modified arsenotungstates such as hexameric cluster anion {Ln2(H2O)4As2W19O68(WO2)2(C6O7H4)2}3]33‒ (Ln = Y3+, Tb3+, Dy3+, Ho3+, Er3+, Tm3+, Yb3+, Lu3+), and a one-dimensional (1D) chainlike POM Na4H8[{Pr(H2O)2}2{As2W19O68}{WO2(mal)}2]·24H2O (mal=malate) [25-27].

    Recently, we launched the explorations on the system of the polyoxotungstates covalently modified by amino acid ligands. In this work, DL-serine (DL-Ser) ligand was chosen for the covalent modification with arsenotungstates based on the following considerations: (a) it as a chelating functional ligand with flexible amino and carboxyl coordination sites, which will result in the direction to form the larger high-nuclearity clusters by incorporating various metal centers such as La and W ions via multifunctional ligand patterns, implementing its organic functionalization; (b) it possesses amino and hydroxyl groups, significantly facilitating the establishment of rich intra- and/or inter-molecular hydrogen bonds in the targeted products between DL-Ser ligands and POMs skeleton, largely boosting the intra-molecular proton transition rate, thus becoming an ideal candidate for improving the opto-chemical and opto-physical properties of targeted products [8, 28]. Fortunately, we successfully obtained a series of 1D linear chainlike DL-Ser covalently modified multinuclear Ln3+ implanted arsenotungstates K2[{Ln(H2O)7}2{As4W44O137(OH)18(H2O)2(DL-Ser)2}{Ln2(H2O)5(DL-Ser)}2]·65H2O (Ln = La (1), Ce (2), Pr (3)), which all exhibited rapid photochromic behaviors.

    X-ray crystal structure analyses indicated that compounds 13 are all isomorphic, which crystallized in triclinic P-1 space group (Table S1 in Supporting information). Therefore, only 1 was structurally descripted in detail. Bond valence sum (BVS) calculations of 1 indicated that the oxidation states of W, As, and La centers are +6, +3, and +3, respectively (Table S2 in Supporting information).

    Structure analysis indicates that 1 is composed of 1D linear chainlike anion [{Ln(H2O)7}2{As4W44O137(OH)18(H2O)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]2−, two K+ cations and 65 lattice water molecules. Specifically, this 1D framework is built up of the tetra-nuclear Ln3+ implanted DL-serine covalently modified arsenotungstate polyoxoanion [{As4W44O137(OH)18(H2O)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]8– (1a) (Fig. 1a). Regardless of the insertion of La3+ ions, the polyoxoanion 1a can be considered as a double DL-Ser groups covalently modified arsenotungstate cluster [As4W44O137(OH)18(H2O)2(DL-Ser)2]18‒, which consists of two distorted {As2W19O59(OH)8(H2O)}6‒ building blocks linked together by a double DL-Ser ligands functionalized [W6O23(OH)2(DL-Ser)2]14‒ fragment (Fig. 1b). In the structure of 1a, the {As2W19O59(OH)8(H2O)}6‒ building blocks are distinctly different from the precursor [As2W19O67(H2O)]14‒ ({As2W19}) (Fig. S1 in Supporting information), and the opening angle in 1a is obviously greater than that of the {As2W19} precursor. This means that the {As2W19} precursor undergo significant dissociation recombination or torsion deformation during the reaction process. Remarkably, the central part {WO5(H2O)} group in {As2W19} precursor changed from {WO5(H2O)} to {WO6} in the assembly process of 1a, also opening the As⋯W({WO6})⋯As angle. As a result, the As⋯As distance in 1 was 8.114(19) Å, which is obviously longer than the As⋯As distance in {As2W19} precursor of 6.522(11) Å (Fig. S1), as well as the significantly larger angle As−W({WO6})−As(171.88(9)°) compared to the angle of 110.01(5)° in {As2W19} precursor (Fig. S1), and this phenomenon has been reported before [28-30]. At the same time, the centrosymmetric Z-shaped [W6O23(OH)2(DL-Ser)2]14‒ segment (Fig. S2a) is made up of a pair of serine covalently modified {W2O9(DL-Ser)}7‒ groups, in which W1 and W2 (W3 and W4) atoms are connected by a chelating DL-Ser ligand and a μ2–O atom, fused together by a corner-sharing {W2O5(OH)2} segment (Fig. 1c). Also, the [W6O23(OH)2(DL-Ser)2]14‒ segment is viewed as a pair of DL-serine covalently modified {W3O11(OH)(DL-Ser)}6– groups connected through a μ2‒O atom in the form of a common vertex μ2‒O atom from another perspective (Fig. S2b in Supporting information). Alternately, the polyoxoanion [{As4W44O137(OH)18(H2O)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]8‒ can also be viewed as a tetramer established by two [B-α-AsW9O29(OH)4]5‒ subunits, two [B-α-AsW9O28(OH)4(H2O)]3‒ subunits, and a central [{W8O43(OH)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]32‒ group (Fig. S3 in Supporting information). Moreover, 1a is further stabilized by two embedded [La2(H2O)5(DL-Ser)]5+ groups, which is connected into 1D linear chainlike structure via two peripheral La3+ ions (Fig. 1d).

    Figure 1

    Figure 1.  (a) The polyhedron representation of the basic polyoxoanion unit in 1: [{As4W44O137(OH)18(H2O)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]8–. (b) The polyhedron representation of the polyoxoanion unit of [As4W44O137(OH)18(H2O)2(DL-Ser)2]18‒. (c) The centrosymmetric Z-shaped hexatungstate [W6O23(OH)2(DL-Ser)2]14‒ fragment. (d) 1D linear chainlike polyoxoanion 1a linked by peripheral La3+ ions.

    Moreover, the continuous-shape measure of three disparate La3+ ions are analyzed by SHAPE 2.1 software [31, 32]. The eight-coordinate La1 exhibits a square antiprismatic (D4d) geometry, while the La2 and La3 show a Muffin prism (Cs) of nine-coordinate and a spherical tricapped trigonal prism (D3h) of nine-coordinate (Tables S3 and S4 in Supporting information), respectively. The coordination environment of La1, La2 and La3 in 1 are shown in Fig. S4 (Supporting information). Specifically, the La1 is defined by five μ2‒O atoms from five {WO6} octahedra, and two coordinated H2O molecules, one O atom from DL-Ser ligand. The La2 is constructed from five μ2‒O atoms from five {WO6} octahedral, and three coordinated H2O molecules, one O atom from DL-Ser ligand, while La3, as a linker, is defined by seven coordinated H2O molecules, and two μ2‒O atoms from two {WO6} octahedra.

    It is noteworthy that the multiple intra-molecular O−H⋯O and N−H⋯O hydrogen bonds interaction among DL-Ser ligands, POM skeleton and water molecules resides in the solid state structure of 1. These detailed intra-molecular hydrogen bonds with the O−H⋯O and N−H⋯O distances in the range of 2.684(4)−3.216(5) Å are shown in Tables S5 and Fig. S5 (Supporting information), which further contributes to the stability of the crystal structure. More importantly, this will most likely facilitate electron transfer between DL-Ser ligands and POM components via hydrogen bonds pathway, improving the photochromic property of the matrix.

    Powder samples of 13 all exhibit rapid photochromic behaviors in response to UV irradiation. As shown in Figs. 2ac, the crystalline state samples of 13 display white (1), yellow (2), green (3) color in the ground state, and which changed color to blue (1), brown (2) and glaucous (3) with the increment of the irradiation time. It apparently began to change color for about 4 min, and gradually reached saturation visible to the naked eye within 10 min. The IR spectra (Fig. S6 in Supporting information) and the PXRD patterns (Fig. S7 in Supporting information) of 13 before and after irradiation showed that all peak positions remained essentially unchanged, which further proved the stability of the structural skeleton. during the photochromic process. In addition, the irradiated samples were placed in the dark for about 22 h, which returned to their natural colors, thus suggesting that the 13 all display efficiently reversible photochromism.

    Figure 2

    Figure 2.  (a–c) The color evolution for 13 irradiated after 0, 4, 6, 8, 10 min and the color fading in the dark under ambient conditions after 10 h, 15 h, 22 h. (d–f) The evolutions of the solid-state diffuse reflectance absorption spectra of 13 with irradiation times of 0, 4, 6, 8, 10 min.

    In particular, the color changing of the first cycle was studied by UV-visible spectroscopy in the covered almost the entire visible spectrum, and the absorption spectra in 250–800 nm were collected under ambient conditions. There was no absorption band appears in the absorption spectra of 1 except for the UV absorption, attributing to the completely empty 4f orbital of La3+ with no f–f electron transition appeared. It was worth noting that a broad absorption band at around about 470 nm can be found in the UV-vis absorption spectra of 2, which is due to the allowed 4f → 5d electron transition of Ce3+ ions. The difference was that another four sharp absorption bands at about 447, 471, 487 and 593 nm in the UV-vis absorption spectra of 3, which are ascribed to the f-f transitions 3H43P2, 3H43P1, 3H43P0, 3H47D2 of Pr3+ ions. Most importantly, the obvious broad bands in the range of 500−800 nm about centered at 675 nm for 1, 575 nm for 2 and 673 nm for 3 are observed in their absorption spectra when increasing irradiation times, which is obviously ascribed to the occurrence of electron-transfer process as a result of the metal-to-metal extra inter-valence charge-transfer inter valence charge transfer (IVCT) WVI→WV (Figs. 2df) [7, 23].

    In addition, we investigated the solid-state photochromic properties of 13. The diffuse reflectance spectra of 13 were performed in the range of 250–800 nm, and the reflectance values of Kubelka-Munk (K–M) functions were also calculated [31]. The diffuse reflectance spectra of samples 13 and their associated K–M transform plots can be seen that the optical gaps of 13 before radiation were 3.07 eV, 2.05 eV and 3.11 eV, respectively. Then, by calculating the optical gap of 13 under a certain period of irradiation, the optical gaps significantly decreased to 2.13 eV, 1.37 eV and 1.45 eV, respectively, manifesting that the photochromic reaction triggered after irradiation (Fig. S8 in Supporting information). The absorption change of intensity at broad bands visible region under irradiation and recovery is shown in Fig. S9 (Supporting information), the absorption intensity at ~675 nm for 1, ~575 nm for 2 and ~673 nm for 3 could maintain about 93.2%, 90.3% and 92.5% of their first values after six cycles, which demonstrate excellent reversible photochromic behavior of 13 with a repeatability of no less than 6 cycles.

    Considering above-mentioned abundant hydrogen bonding in solid state structures of 13, it can be inferred that the photochromic mechanism of 13 relies on Yamase's model for the charge transfer (CT) aspect of the photochromic mechanism [33, 34]. Therefore, similar to the mechanism proposed by Yamase's group, the electron transfer occurs between the terminal oxygen atom of the POM cluster and its connecting WVI atom, induced by the multiple intra-molecular O−H⋯O and N−H⋯O hydrogen bonding pathway between the DL-serine ligand and POM components under high-power irradiation (Scheme 1).

    Scheme 1

    Scheme 1.  The photochromic mechanism of 13. X represents N or O atoms in the serine ligand.

    Additionally, we carried out the study of the kinetics of the coloration of 13. According to the theory proposed by Desssapt's group, the coloration rate is related to the concentration of inducible WVI center with irradiation time and follows a second-order reaction law [35-38]. The reflectance values of 13 at the wavelength of maximum absorbance versus irradiation time in the range of 250‒800 nm were shown in Fig. 3. It can be seen that the light values abruptly decreased and then tended to a slight flatten with the duration of irradiation. The curves of reflectivity R(t) vs. t for 13 can be well-fitted using the function [31, 39, 40]:

    (1)

    Figure 3

    Figure 3.  The plots of reflectivity R(t) vs. t for 1 (a) 2 (b) and 3 (c) measured at 675 nm, 575 nm, 673 nm for 0, 4, 6, 8 and 10 min irradiation.

    a and b: proportional constants, c = Rmax(N). The photochromic rate (half-life), t1/2, is the time required to reach [R(0) + R(N)]/2, approximately t1/2= 1/b. The relative parameters can be obtained by the curve fitting and listed in Fig. 3. The t1/2 values from the curve fitting were 3.69 min, 4.52 min and 3.38 min. The coloration speeds of 13 are all evidently fast, which are comparable with most fast photochromic polyoxotungstates (Table S6 in Supporting information). In addition, the rapid photochromic behavior is closely related to the low optical band gaps and rich intramolecular hydrogen bonds of 13 during the photochromism [41].

    In summary, a series of isostructural 1D linear chainlike DL-Ser ligands covalently modified multinuclear lanthanide implanted arsenotungstates: K2[{Ln(H2O)7}2{As4W44O137(OH)18(H2O)2(DL-Ser)2}{Ln2(H2O)5 (DL-Ser)}2]·65H2O (DL-Ser = DL-serine, Ln = La (1), Ce (2), Pr (3)), were successfully obtained by reaction of K14[As2W19O67(H2O)] precursor and DL-Ser ligands through a facile aqueous solution assembly. The 1D framework is established by using the DL-serine ligand covalently modified tetra-nuclear Ln3+ ions implanted arsenotungstate polyoxoanion [{As4W44O137(OH)18(H2O)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]8–, which is constituted of two {As2W19O59(OH)8(H2O)}6‒ subunits, a core [W6O23(OH)2(DL-Ser)2]14‒ segment and two implanted [Ln2(H2O)5(DL-Ser)]5+ groups. Additionally, 13 display excellent photochromic behaviors in response to UV irradiation. Moreover, the hydrogen bond interaction between POM components and DL-Ser ligands greatly improves the photochromic properties of these compounds. This not only enrich the field of POMs chemistry, but pave the way towards understanding the POMs-based photochromic materials.

    The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

    This work was supported by the National Natural Science Foundation of China (No. 222071043), the Major Project of Science and Technology, Education Department of Henan Province (No. 20A150010) and the 2021 Students Innovative Pilot Plan of Henan University (No. 202110475079).

    Supplementary material associated with this article can be found, in the online version, at doi:10.1016/j.cclet.2022.02.043.


    1. [1]

      H.G. He, G.W. Wang, S.C. Chai, et al., Chin. Chem. Lett. 32 (2021) 2013–2016. doi: 10.1016/j.cclet.2021.01.051

    2. [2]

      L. Cronin, A. Muller, Chem. Soc. Rev. 41 (2012) 7333–7334. doi: 10.1039/c2cs90087d

    3. [3]

      T.P. Hu, Zhao Y. Q, Z. Jagličić, et al., Inorg. Chem. 54 (2015) 7415–7423. doi: 10.1021/acs.inorgchem.5b00962

    4. [4]

      Y.Q. Zhao, K. Yu, L.W. Wang, et al., Inorg. Chem. 53 (2014) 11046–11050. doi: 10.1021/ic501567s

    5. [5]

      J.J. Walsh, A.M. Bond, R.J. Forster, T.E. Keyes, Coord. Chem. Rev. 306 (2016) 217–234. doi: 10.1016/j.ccr.2015.06.016

    6. [6]

      G.P. Yang, Y. Liu, K. Li, et al., Chin. Chem. Lett. 31 (2020) 3233–3236. doi: 10.1016/j.cclet.2020.07.018

    7. [7]

      P.T. Ma, H Feng, J.P. Wang, J.Y. Niu, Coord. Chem. Rev. 378 (2019) 281–309. doi: 10.1016/j.ccr.2018.02.010

    8. [8]

      P.T. Ma, H Feng, R. Wan, et al., J. Mater. Chem. C 4 (2016) 5424–5433. doi: 10.1039/C6TC00960C

    9. [9]

      Y.T. Zhang, X.L. Wang, S.B. Li, et al., Inorg. Chem. 55 (2016) 8770–8775. doi: 10.1021/acs.inorgchem.6b01338

    10. [10]

      Y.T. Zhang, X.L. Wang, S.B. Li, et al., Chem. Commun. 52 (2016) 9632–9635. doi: 10.1039/C6CC04583A

    11. [11]

      Y.T. Zhang, S.B. Li, X.L. Wang, et al., Dalton Trans. 45 (2016) 14898–14901. doi: 10.1039/C6DT02764D

    12. [12]

      K. Wang, N.J. Niu, D.Y. Zhao, et al., Inorg. Chem. 56 (2017) 14053–14059. doi: 10.1021/acs.inorgchem.7b02207

    13. [13]

      A. Muller, V.P. Fedin, C. Kuhlmann, H. Bogge, M. Schmidtmann, Chem. Commun. (1999) 927–929.

    14. [14]

      U. Kortz, M.G. Savelieff, F.Y.A. Ghali, et al., Angew. Chem. Int. Ed. 41 (2002) 4070–4073. doi: 10.1002/1521-3773(20021104)41:21<4070::AID-ANIE4070>3.0.CO;2-3

    15. [15]

      D.H. Yang, Y.F. Liang, P.T. Ma, et al., CrystEngComm 16 (2014) 8041–8046. doi: 10.1039/C4CE00580E

    16. [16]

      Y.F. Liang, S.Z. Li, D.H. Yang, et al., J. Mater. Chem. C 3 (2015) 4632–4639. doi: 10.1039/C5TC00297D

    17. [17]

      D.H. Yang, S.Z. Li, P.T. Ma, J.P. Wang, J.Y. Niu, Inorg. Chem. 52 (2013) 14034–14039. doi: 10.1021/ic401804e

    18. [18]

      D.H. Yang, Y.F. Liang, P.T. Ma, et al., Inorg. Chem. 53 (2014) 3048–3053. doi: 10.1021/ic402882a

    19. [19]

      D.H. Yang, S.Z. Li, P.T. Ma, J.P. Wang, J.Y. Niu, Inorg. Chem. 52 (2013) 8987–8992. doi: 10.1021/ic401176j

    20. [20]

      M.R. Healey, R.W. Gable, C. Ritchie, C. Boskovic, Polyhedron 64 (2013) 13–19. doi: 10.1016/j.poly.2013.01.058

    21. [21]

      C. Ritchie, C.E. Miller, C. Boskovic, Dalton Trans. 40 (2011) 12037–12039. doi: 10.1039/c1dt10866b

    22. [22]

      M. Vonci, F.A. Bagherjeri, P.D. Hall, et al., Chem. Eur. J. 20 (2014) 14102–14111. doi: 10.1002/chem.201403222

    23. [23]

      F.A. Bagherjeri, M. Vonci, E.A. Nagul, et al., Inorg. Chem. 55 (2016) 12329–12347. doi: 10.1021/acs.inorgchem.6b02218

    24. [24]

      X.J. Feng, H.Y. Han, Y.H. Wang, et al., CrystEngComm 15 (2013) 7267–7273. doi: 10.1039/c3ce40686e

    25. [25]

      P.T. Ma, R. Wan, Y.N. Si, et al., Dalton Trans. 44 (2015) 11514–11523. doi: 10.1039/C5DT01323B

    26. [26]

      Y. Wang, X.P. Sun, S.Z. Li, et al., Cryst. Growth Des. 15 (2015) 2057–2063. doi: 10.1021/cg5012499

    27. [27]

      J. Wang, W.J. Shi, S.J. Li, et al., Dalton Trans. 47 (2018) 7949–7955.

    28. [28]

      H.L. Li, Y.J. Liu, J.L. Liu, et al., Chem. Eur. J. 23 (2017) 2673–2689. doi: 10.1002/chem.201605070

    29. [29]

      C. Ritchie, M. Speldrich, R.W. Gable, L. Sorace, C. Boskovic, Inorg. Chem. 50 (2011) 7004–7014. doi: 10.1021/ic200366a

    30. [30]

      H.C. Wu, R. Wan, Y.N. Si, et al., Dalton Trans. 47 (2018) 1958–1965.

    31. [31]

      B. Yan, H.C. Wu, P.T. Ma, J.P. Wang, J.Y. Niu, Inorg. Chem. Front. 8 (2021) 4158–4176. doi: 10.1039/d1qi00681a

    32. [32]

      B. Yan, R.C. Liang, K.T. Zheng, et al., Inorg. Chem. 60 (2021) 8164–8172. doi: 10.1021/acs.inorgchem.1c00798

    33. [33]

      T. Yamase, Chem. Rev. 98 (1998) 307–326. doi: 10.1021/cr9604043

    34. [34]

      T. Yamase, M. Sugeta, J. Chem. Soc. Dalton Trans. (1993) 759–765.

    35. [35]

      E. Papaconstantinou, Chem. Soc. Rev. 18 (1989) 1–31. doi: 10.1039/cs9891800001

    36. [36]

      R. Dessapt, M. Collet, V. Coué, et al., Inorg. Chem. 48 (2009) 574–580. doi: 10.1021/ic8013865

    37. [37]

      O. Oms, T. Benali, J. Marrot, et al., Inorganics 3 (2015) 279–294. doi: 10.3390/inorganics3020279

    38. [38]

      R.C. Howell, F.G. Perez, S. Jain, et al., Angew. Chem. Int. Ed. 40 (2001) 4031–4034. doi: 10.1002/1521-3773(20011105)40:21<4031::AID-ANIE4031>3.0.CO;2-8

    39. [39]

      J. Wang, P.T. Ma, Y.P. Wang, et al., J. Phys. Chem. Solids. 110 (2017) 161–166. doi: 10.1016/j.jpcs.2017.06.007

    40. [40]

      V. Coué, R. Dessapt, M. Bujoli-Doeuff, M. Evain, S. Jobic, Inorg. Chem. 46 (2007) 2824–2835. doi: 10.1021/ic0621502

    41. [41]

      Y.F. Liang, S.Z. Li, D.H. Yang, et al., J. Mater. Chem. C 3 (2015) 4632–4639. doi: 10.1039/C5TC00297D

  • Figure 1  (a) The polyhedron representation of the basic polyoxoanion unit in 1: [{As4W44O137(OH)18(H2O)2(DL-Ser)2}{La2(H2O)5(DL-Ser)}2]8–. (b) The polyhedron representation of the polyoxoanion unit of [As4W44O137(OH)18(H2O)2(DL-Ser)2]18‒. (c) The centrosymmetric Z-shaped hexatungstate [W6O23(OH)2(DL-Ser)2]14‒ fragment. (d) 1D linear chainlike polyoxoanion 1a linked by peripheral La3+ ions.

    Figure 2  (a–c) The color evolution for 13 irradiated after 0, 4, 6, 8, 10 min and the color fading in the dark under ambient conditions after 10 h, 15 h, 22 h. (d–f) The evolutions of the solid-state diffuse reflectance absorption spectra of 13 with irradiation times of 0, 4, 6, 8, 10 min.

    Scheme 1  The photochromic mechanism of 13. X represents N or O atoms in the serine ligand.

    Figure 3  The plots of reflectivity R(t) vs. t for 1 (a) 2 (b) and 3 (c) measured at 675 nm, 575 nm, 673 nm for 0, 4, 6, 8 and 10 min irradiation.

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  • 发布日期:  2023-02-15
  • 收稿日期:  2021-12-30
  • 接受日期:  2022-02-17
  • 修回日期:  2022-02-08
  • 网络出版日期:  2022-02-20
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