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A novel metal-organic framework based on mixed ligands as a highly-selective luminescent sensor for Cr2O72− and nitroaromatic compounds
Accepted Manuscript A novel metal-organic framework based on mixed ligands as a highly-selective luminescent sensor for Cr2O72− and nitroaromatic compounds
Feng Guo PII: DOI: Reference:
S1387-7003(19)30067-X https://doi.org/10.1016/j.inoche.2019.02.026 INOCHE 7284
To appear in:
Inorganic Chemistry Communications
Received date: Revised date: Accepted date:
17 January 2019 16 February 2019 16 February 2019
Please cite this article as: F. Guo, A novel metal-organic framework based on mixed ligands as a highly-selective luminescent sensor for Cr2O72− and nitroaromatic compounds, Inorganic Chemistry Communications, https://doi.org/10.1016/ j.inoche.2019.02.026
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A novel metal-organic framework based on mixed ligands as a highly-selective luminescent sensor for Cr2O72– and nitroaromatic compounds
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Feng Guo, a*
Chongqing Key Laboratory of Inorganic Special Functional Materials, School of
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Chemistry and Chemical Engineering, Yangtze Normal University, Fuling, Chongqing
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408100, China.
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Corresponding Authors: Prof. Feng Guo
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E-mail address: [email protected]
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Abstract A novel 3D metal-organic framework, namely [Mn2(HBTC)2(TIAB)]n, was successfully synthesized by mixing two rigid ligands 1,2,4,5-tetrakis(1-imidazolyl) benzene (TIAB) and 1,3,5-benzenetricarboxylic acid (H3BTC). The resultant sample was investigated in detail by single crystal X-ray diffraction, elemental analysis of C,
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H and N, powder X-ray diffraction pattern, thermogravimetric analysis, and luminescent properties. In virtue of its stability and luminescence properties, the
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resultant [Mn2(HBTC)2(TIAB)]n can be applied as a bifunctional luminescent sensor
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for Cr2O72– and nitroaromatic compounds. In addition, it can be recycled at least four
Keywords:
Metal-organic
Cr2O72–;
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times due to the excellent stability.
framework;
compound;
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luminescence; sensor.
nitroaromatic
Metal-organic frameworks (MOFs)[1-6] are a common class of inorganic-organic
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hybrid material, which have been implemented in various applications, including gas
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sorption,[7-11] biological molecular immobilization,[12-15] luminescence detector,[16-22] heterogeneous catalysis,[23-27] and optics device,[28-30] because they have relatively high BET surface area, remarkable designability, multiformity and functionality. To
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date, lots of MOFs have been successfully prepared.[31-35] Among all the applications, detecting contaminantsusing luminescent MOFs as sensors have drawn much
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attention due to their outstanding advantages, such as rapid-response, prominent selectivity, high sensitivity and excellent reusability.[16-22] MOFs contain two different parts including bridging organic linkers and multiple metal ions/clusters, which can be considered and designed as emitted sources for luminescent sensors. The organic ligands not only are able to apply to construct interesting MOFs, but also can be introduced targeted groups to increase the luminescent detectability towards heavy metal ions, organic vapour solvents and some toxic molecules. Additionally, the mixed ligand strategy always can be adopted to fabricate novel luminescence MOFs to extensively use as sensor materials.[36-38] Cr2O72– and nitroaromatic compounds are
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the most wide spread toxic contaminants in many fields to cause various security and environmental puzzles all over the world. Meanwhile, the poor stability of luminescence MOFs limits their actual use of industrialization in detection applications. Thus, it is remarkably important to design and prepare such efficient and stable luminescence MOFs by the mixed ligand strategy as useful sensors tomonitor
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Cr2O72– and nitroaromatic compounds for security and environmental protection. In this work, we selected two rigid organic ligands 1,2,4,5-tetrakis(1-imidazolyl)
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benzene (TIAB) and 1,3,5-benzenetricarboxylic acid (H3BTC), because they have
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multiform coordination nodes, different coordinated atoms, and rigid structures to feasibly generate MOFs. Mn(II) ion is a commonly used inorganic centre to
MOFs
with
outstanding
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self-assemble with two rigid organic ligands TIAB and H3BTC to fabricate novel properties.
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novel
3D
Mn-MOF
(namely
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[Mn2(HBTC)2(TIAB)]n) has been achieved by the mixed ligand strategy via heating MnCl2, TIAB and H3BTC in a mixture solvent of N,N-dimethylformamide (DMF)
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and H2O at 120 °C after 3 days.[39] The resultant sample was measured and
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characterized in detail by single crystal and powder X-ray diffraction, C, H and Nelemental analysis, luminescent properties, and thermogravimetric analysis. Because of high stability and luminescence property, it can be founded as a high-efficient
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recyclability.
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luminescent sensor for Cr2O72– and nitroaromatic compounds with outstanding
From the single-crystal X-ray diffraction result, it displayed that the resultant sample crystallizes in the monoclinic with C2/c space group and contains a three-dimensional (3D) structure.[40] Compared with the reported MOFs or coordinated compounds based on H3BTC[41, 42] and TIAB[43, 44], the as-synthesized sample was constructed by H3BTC and TIAB simultaneously, which is the first reported in all MOFs. As seen in Fig. S1, the asymmetric unit contains one independent Mn(II) ion, one second TIAB molecule and a partly deprotonated HBTC2– ligand. As founded in Fig. 1a, each Mn(II) ion is six-coordinated with four
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oxygen atoms from three carboxylate groups of different HBTC2- ligands and two nitrogen atoms from two different TIAB ligands (Mn-O = 2.1968(17) and Mn-N = 2.2083(20) Å). Two Mn(II) ions can be connected each other by the oxygen atoms from functional carboxylate groups to form binuclear Mn(II) clusters. The MnMn distance in this binuclear cluster is about 4.6779(6) Å. The HBTC2– ligand was three-connected via only one coordinated mode as 3-1: 1: 1: 1 (Fig. 1b). The
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neutral TIAB is linked with four Mn(II) ions based on a coordination mode as 4-1:
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1: 1: 1 (Fig. 1c). The binuclear Mn(II) clusters were further connected by these
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ligands to construct a 3D construction finally (Figs. 1d and 1e).
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Fig. 1. (a) The binuclear Mn(II) clusters; (b) the coordination mode of partly deprotonated HBTC2– ligand; (c) the coordination mode of TIAB ligand; (d and e) viewing of the 3D structure (all hydrogen atoms are removed for clarity, and C, gray; O, red; N, blue; Mn, green).
The measured powder X-ray diffraction profile of the prepared sample was almost similar with those of the characteristic signals of the simulated one from the obtained single crystal structure, illustrating that the obtained sample was pure (Fig. 2a). As shown in Fig. 2b, the thermogravimetric analyses (TGA) data of the as-synthesized sample in air was collected, which exhibited a significant weight loss
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after increasing the temperature to 300 °C. The slight weight loss before 300 °C was mainly attributed to the small amount of adsorbed water molecules on the surface of Mn-MOF. The corresponding PXRD profile of the as-synthesized sample after heating at 300 °C for 30 minutes obviously exhibited thatit possessed the outstanding heating stability (Fig. S2). Finally, the residual sample decomposed completely with
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the increasing temperature.
Fig. 2. (a) PXRD curves of the simulated (black) and experimental (red) samples; (b) TGA data of
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the as-synthesized sample.
Due to the extensively potential luminescent sensing ability, the solid-state luminescent property of the resultant sample was measured at indoor temperature. As
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displayed in Fig. 3a, the resultant sample showed a significant broad emission band at 407 nm under excitation wavelength at 342 nm, which is significantly similar with the
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H3BTC organic ligand (Fig. S3).[45] The results indicated that the luminescent property is primary attributed to the ligand-to-metal and the intraligand transition like the other previous literature.[46-49] Fig. S4 shown the luminescent emission intensities of the as-synthesized sample dispersed in different solvents, which clearly illustrated the relative strong emission luminescence in DMF. In addition, the resultant sample can retain its luminescent property at least for one day in DMF (Fig. S5). More importantly, the resultant sample showed a significant luminescence quenching performance after encountering the Cr2O72– in Fig. 3a. To investigate the luminescent detectability towards Cr2O72–, the luminescent intensity remarkably decreased with
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the increasing concentration (Fig. 3b). As we know, the Stern-Volmer equation: I0/I = 1 + Ksv[Q] can be applied to calculate the Ksv value and further quantitatively confirmed the detectability. Herein, the I0 and I are the luminescent intensities of the origin and after adding analyte, [Q] is the molar concentration (M–1), and Ksv value is the Stern-Volmer constant. If the results of I0/I vs [Q] are linear, the Ksv value is able to confirm accurately. As the insert result in Fig. 3b, the corresponding Ksv value of
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Cr2O72– was calculated about 8.9 × 103 M–1. Meanwhile, the detection limit of Cr2O72–
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can be calculated from 3δ/Slope (δ:standard error).[50] The corresponding detection limit of Cr2O72– is 1.25 × 10–5 mol L–1. The compared results of the reported MOFs
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were listed in Table S1. The UV-Vis overlap of Cr2O72– and the excitation spectra of the resultant sample are mainly attributed to the excitation light competition (Fig. S6).
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The anti-interference and sensitivity experiments of Cr2O72– were further investigated and explored in detail (Fig. S7), which displayed that the prepared crystal has
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excellent selectivity for Cr2O72– by the luminescence quenching.
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Fig. 3. (a) The corresponding emission spectra of the resultant sample in different ions (1×10
M); (b) the titrating experiment with Cr2O72– at different concentrations from 1.05× 10–5 to 1.0 × 10–4 mol L–1 with the insert Stern-Volmer result. Meanwhile, the ground powder also exhibited remarkably luminescence quenching effect for common nitroaromatic compounds, including 3,5-dinitrobenzoicacid (3,5-DNBA), nitrobenzene
1,3-dinitrobenzene (NB),
4-nitrobenzoic
(1,3-DNB), acid
2,4-dinitrotoluene(2,4-DNT),
(4-NBA),
4-nitrotoluene
(4-NT),
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1-bromo-4-nitrobenzene (1-Br-4-NB), and picric acid (PA). As illustrated in Fig. 4a, it showed the highest luminescence performance towards PA among all the used nitroaromatic compounds. The luminescence titration experiment also clearly showed the luminescent intensity significantly decreased with the increasing concentration of PA in DMF solution. In the low concentration range of PA, the Ksv value can be accurately calculated by the Stern-Volmer equation, which is about 1.12 × 104 M–1.
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Furthermore, the corresponding detection limit of PA is 3.08 × 10–5 mol L–1. The
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UV-Vis adsorption results obviously exhibited that the excitation spectra and the adsorption band of PA has large overlap, leading to the excitation light competition
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(Fig. S8). In addition, the selectivity of PA was studied and performed in detail. The
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outstanding selectivity for PA (Fig. S9).
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anti-interference and sensitivity experiment displayed that the prepared sample has
Fig. 4. (a) The corresponding emission spectra of the resultant sample in different nitroaromatic compounds; (b) the titrating experiment with PA at different concentrations from 4.4 × 10–6 to 5.0
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× 10–4 mol L–1 with the Stern-Volmer data.
Furthermore, another important property for the sensing material is the recyclability. The resultant sample was easily recollected and further reused after the sequential detected experiments. As founded in Fig. 5, the sensing detection ability of the recollected sample can almost retain very well after recycling four times for Cr2O72– and PA, which is mainly ascribed to the high stability of this MOF material. The luminescence intensity is easily regained after washing with fresh DMF several times. The recycled PXRD profiles of the reused crystals after four times displayed that the
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framework of this MOF can be retained very well (Fig. S10).
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Fig. 5. The recyclability for the as-synthesized MOF for the Cr2O72– (a) and PA (b).
In summary, a novel 3D Mn(II)-MOF with high stability is successfully designed
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and fabricated by the mixed ligand strategy, which can be further considered as a luminescent sensor for Cr2O72– and PA. Meanwhile, the resultant sample also possesses the excellent recyclability at least four times.
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Appendix A. Supplementary data The luminescent spectra and crystal table are listed in the supporting information. The
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[39] Synthesis of [Mn2(HBTC)2(TIAB)]n:A mixture of MnCl2 (25.2 mg, 0.1 mmol), TIAB (34.2 mg,0.1 mmol) and H3BTC (21 mg,0.1 mmol) was dissolved in a mixed solution of N,N-Dimethylformamide (DMF, 5 mL) and H2O (1 mL) in a 23.0 mL Teflon-lined autoclave and sonicated about 15 minutes, which was further put into 120°C oven for 3 days. The achieved samples can be collected
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directly after cooling to room temperature and further washed with fresh DMF for several times. Yield: 67% (based on H3BTC). Anal. calcd for C36H22O12N8Mn2: C
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Graphical Abstract-Pictogram
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This work presents a new 3D luminescent metal-organic framework. It can be used as a luminescence sensor for PA and Cr2O72- with excellent recyclability.
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Highlights
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1. A novel 3D MOF was successfully fabricated by the mixed ligand strategy. 2. It can be implemented as a luminescence sensor for Cr2O72- and PA. 3. It has good recyclability at least four times.
Feng Guo PII: DOI: Reference:
S1387-7003(19)30067-X https://doi.org/10.1016/j.inoche.2019.02.026 INOCHE 7284
To appear in:
Inorganic Chemistry Communications
Received date: Revised date: Accepted date:
17 January 2019 16 February 2019 16 February 2019
Please cite this article as: F. Guo, A novel metal-organic framework based on mixed ligands as a highly-selective luminescent sensor for Cr2O72− and nitroaromatic compounds, Inorganic Chemistry Communications, https://doi.org/10.1016/ j.inoche.2019.02.026
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A novel metal-organic framework based on mixed ligands as a highly-selective luminescent sensor for Cr2O72– and nitroaromatic compounds
a
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Feng Guo, a*
Chongqing Key Laboratory of Inorganic Special Functional Materials, School of
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Chemistry and Chemical Engineering, Yangtze Normal University, Fuling, Chongqing
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408100, China.
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Corresponding Authors: Prof. Feng Guo
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E-mail address: [email protected]
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Abstract A novel 3D metal-organic framework, namely [Mn2(HBTC)2(TIAB)]n, was successfully synthesized by mixing two rigid ligands 1,2,4,5-tetrakis(1-imidazolyl) benzene (TIAB) and 1,3,5-benzenetricarboxylic acid (H3BTC). The resultant sample was investigated in detail by single crystal X-ray diffraction, elemental analysis of C,
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H and N, powder X-ray diffraction pattern, thermogravimetric analysis, and luminescent properties. In virtue of its stability and luminescence properties, the
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resultant [Mn2(HBTC)2(TIAB)]n can be applied as a bifunctional luminescent sensor
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for Cr2O72– and nitroaromatic compounds. In addition, it can be recycled at least four
Keywords:
Metal-organic
Cr2O72–;
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times due to the excellent stability.
framework;
compound;
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luminescence; sensor.
nitroaromatic
Metal-organic frameworks (MOFs)[1-6] are a common class of inorganic-organic
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hybrid material, which have been implemented in various applications, including gas
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sorption,[7-11] biological molecular immobilization,[12-15] luminescence detector,[16-22] heterogeneous catalysis,[23-27] and optics device,[28-30] because they have relatively high BET surface area, remarkable designability, multiformity and functionality. To
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date, lots of MOFs have been successfully prepared.[31-35] Among all the applications, detecting contaminantsusing luminescent MOFs as sensors have drawn much
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attention due to their outstanding advantages, such as rapid-response, prominent selectivity, high sensitivity and excellent reusability.[16-22] MOFs contain two different parts including bridging organic linkers and multiple metal ions/clusters, which can be considered and designed as emitted sources for luminescent sensors. The organic ligands not only are able to apply to construct interesting MOFs, but also can be introduced targeted groups to increase the luminescent detectability towards heavy metal ions, organic vapour solvents and some toxic molecules. Additionally, the mixed ligand strategy always can be adopted to fabricate novel luminescence MOFs to extensively use as sensor materials.[36-38] Cr2O72– and nitroaromatic compounds are
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the most wide spread toxic contaminants in many fields to cause various security and environmental puzzles all over the world. Meanwhile, the poor stability of luminescence MOFs limits their actual use of industrialization in detection applications. Thus, it is remarkably important to design and prepare such efficient and stable luminescence MOFs by the mixed ligand strategy as useful sensors tomonitor
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Cr2O72– and nitroaromatic compounds for security and environmental protection. In this work, we selected two rigid organic ligands 1,2,4,5-tetrakis(1-imidazolyl)
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benzene (TIAB) and 1,3,5-benzenetricarboxylic acid (H3BTC), because they have
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multiform coordination nodes, different coordinated atoms, and rigid structures to feasibly generate MOFs. Mn(II) ion is a commonly used inorganic centre to
MOFs
with
outstanding
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self-assemble with two rigid organic ligands TIAB and H3BTC to fabricate novel properties.
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novel
3D
Mn-MOF
(namely
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[Mn2(HBTC)2(TIAB)]n) has been achieved by the mixed ligand strategy via heating MnCl2, TIAB and H3BTC in a mixture solvent of N,N-dimethylformamide (DMF)
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and H2O at 120 °C after 3 days.[39] The resultant sample was measured and
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characterized in detail by single crystal and powder X-ray diffraction, C, H and Nelemental analysis, luminescent properties, and thermogravimetric analysis. Because of high stability and luminescence property, it can be founded as a high-efficient
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recyclability.
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luminescent sensor for Cr2O72– and nitroaromatic compounds with outstanding
From the single-crystal X-ray diffraction result, it displayed that the resultant sample crystallizes in the monoclinic with C2/c space group and contains a three-dimensional (3D) structure.[40] Compared with the reported MOFs or coordinated compounds based on H3BTC[41, 42] and TIAB[43, 44], the as-synthesized sample was constructed by H3BTC and TIAB simultaneously, which is the first reported in all MOFs. As seen in Fig. S1, the asymmetric unit contains one independent Mn(II) ion, one second TIAB molecule and a partly deprotonated HBTC2– ligand. As founded in Fig. 1a, each Mn(II) ion is six-coordinated with four
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oxygen atoms from three carboxylate groups of different HBTC2- ligands and two nitrogen atoms from two different TIAB ligands (Mn-O = 2.1968(17) and Mn-N = 2.2083(20) Å). Two Mn(II) ions can be connected each other by the oxygen atoms from functional carboxylate groups to form binuclear Mn(II) clusters. The MnMn distance in this binuclear cluster is about 4.6779(6) Å. The HBTC2– ligand was three-connected via only one coordinated mode as 3-1: 1: 1: 1 (Fig. 1b). The
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neutral TIAB is linked with four Mn(II) ions based on a coordination mode as 4-1:
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1: 1: 1 (Fig. 1c). The binuclear Mn(II) clusters were further connected by these
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ligands to construct a 3D construction finally (Figs. 1d and 1e).
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Fig. 1. (a) The binuclear Mn(II) clusters; (b) the coordination mode of partly deprotonated HBTC2– ligand; (c) the coordination mode of TIAB ligand; (d and e) viewing of the 3D structure (all hydrogen atoms are removed for clarity, and C, gray; O, red; N, blue; Mn, green).
The measured powder X-ray diffraction profile of the prepared sample was almost similar with those of the characteristic signals of the simulated one from the obtained single crystal structure, illustrating that the obtained sample was pure (Fig. 2a). As shown in Fig. 2b, the thermogravimetric analyses (TGA) data of the as-synthesized sample in air was collected, which exhibited a significant weight loss
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after increasing the temperature to 300 °C. The slight weight loss before 300 °C was mainly attributed to the small amount of adsorbed water molecules on the surface of Mn-MOF. The corresponding PXRD profile of the as-synthesized sample after heating at 300 °C for 30 minutes obviously exhibited thatit possessed the outstanding heating stability (Fig. S2). Finally, the residual sample decomposed completely with
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the increasing temperature.
Fig. 2. (a) PXRD curves of the simulated (black) and experimental (red) samples; (b) TGA data of
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the as-synthesized sample.
Due to the extensively potential luminescent sensing ability, the solid-state luminescent property of the resultant sample was measured at indoor temperature. As
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displayed in Fig. 3a, the resultant sample showed a significant broad emission band at 407 nm under excitation wavelength at 342 nm, which is significantly similar with the
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H3BTC organic ligand (Fig. S3).[45] The results indicated that the luminescent property is primary attributed to the ligand-to-metal and the intraligand transition like the other previous literature.[46-49] Fig. S4 shown the luminescent emission intensities of the as-synthesized sample dispersed in different solvents, which clearly illustrated the relative strong emission luminescence in DMF. In addition, the resultant sample can retain its luminescent property at least for one day in DMF (Fig. S5). More importantly, the resultant sample showed a significant luminescence quenching performance after encountering the Cr2O72– in Fig. 3a. To investigate the luminescent detectability towards Cr2O72–, the luminescent intensity remarkably decreased with
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the increasing concentration (Fig. 3b). As we know, the Stern-Volmer equation: I0/I = 1 + Ksv[Q] can be applied to calculate the Ksv value and further quantitatively confirmed the detectability. Herein, the I0 and I are the luminescent intensities of the origin and after adding analyte, [Q] is the molar concentration (M–1), and Ksv value is the Stern-Volmer constant. If the results of I0/I vs [Q] are linear, the Ksv value is able to confirm accurately. As the insert result in Fig. 3b, the corresponding Ksv value of
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Cr2O72– was calculated about 8.9 × 103 M–1. Meanwhile, the detection limit of Cr2O72–
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can be calculated from 3δ/Slope (δ:standard error).[50] The corresponding detection limit of Cr2O72– is 1.25 × 10–5 mol L–1. The compared results of the reported MOFs
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were listed in Table S1. The UV-Vis overlap of Cr2O72– and the excitation spectra of the resultant sample are mainly attributed to the excitation light competition (Fig. S6).
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The anti-interference and sensitivity experiments of Cr2O72– were further investigated and explored in detail (Fig. S7), which displayed that the prepared crystal has
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excellent selectivity for Cr2O72– by the luminescence quenching.
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Fig. 3. (a) The corresponding emission spectra of the resultant sample in different ions (1×10
M); (b) the titrating experiment with Cr2O72– at different concentrations from 1.05× 10–5 to 1.0 × 10–4 mol L–1 with the insert Stern-Volmer result. Meanwhile, the ground powder also exhibited remarkably luminescence quenching effect for common nitroaromatic compounds, including 3,5-dinitrobenzoicacid (3,5-DNBA), nitrobenzene
1,3-dinitrobenzene (NB),
4-nitrobenzoic
(1,3-DNB), acid
2,4-dinitrotoluene(2,4-DNT),
(4-NBA),
4-nitrotoluene
(4-NT),
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1-bromo-4-nitrobenzene (1-Br-4-NB), and picric acid (PA). As illustrated in Fig. 4a, it showed the highest luminescence performance towards PA among all the used nitroaromatic compounds. The luminescence titration experiment also clearly showed the luminescent intensity significantly decreased with the increasing concentration of PA in DMF solution. In the low concentration range of PA, the Ksv value can be accurately calculated by the Stern-Volmer equation, which is about 1.12 × 104 M–1.
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Furthermore, the corresponding detection limit of PA is 3.08 × 10–5 mol L–1. The
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UV-Vis adsorption results obviously exhibited that the excitation spectra and the adsorption band of PA has large overlap, leading to the excitation light competition
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(Fig. S8). In addition, the selectivity of PA was studied and performed in detail. The
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outstanding selectivity for PA (Fig. S9).
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anti-interference and sensitivity experiment displayed that the prepared sample has
Fig. 4. (a) The corresponding emission spectra of the resultant sample in different nitroaromatic compounds; (b) the titrating experiment with PA at different concentrations from 4.4 × 10–6 to 5.0
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× 10–4 mol L–1 with the Stern-Volmer data.
Furthermore, another important property for the sensing material is the recyclability. The resultant sample was easily recollected and further reused after the sequential detected experiments. As founded in Fig. 5, the sensing detection ability of the recollected sample can almost retain very well after recycling four times for Cr2O72– and PA, which is mainly ascribed to the high stability of this MOF material. The luminescence intensity is easily regained after washing with fresh DMF several times. The recycled PXRD profiles of the reused crystals after four times displayed that the
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framework of this MOF can be retained very well (Fig. S10).
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Fig. 5. The recyclability for the as-synthesized MOF for the Cr2O72– (a) and PA (b).
In summary, a novel 3D Mn(II)-MOF with high stability is successfully designed
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and fabricated by the mixed ligand strategy, which can be further considered as a luminescent sensor for Cr2O72– and PA. Meanwhile, the resultant sample also possesses the excellent recyclability at least four times.
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Appendix A. Supplementary data The luminescent spectra and crystal table are listed in the supporting information. The
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[39] Synthesis of [Mn2(HBTC)2(TIAB)]n:A mixture of MnCl2 (25.2 mg, 0.1 mmol), TIAB (34.2 mg,0.1 mmol) and H3BTC (21 mg,0.1 mmol) was dissolved in a mixed solution of N,N-Dimethylformamide (DMF, 5 mL) and H2O (1 mL) in a 23.0 mL Teflon-lined autoclave and sonicated about 15 minutes, which was further put into 120°C oven for 3 days. The achieved samples can be collected
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directly after cooling to room temperature and further washed with fresh DMF for several times. Yield: 67% (based on H3BTC). Anal. calcd for C36H22O12N8Mn2: C
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49.77, H 2.53, N 12.90%; found: C 49.68, H 2.59, N 12.87%.
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22.364(2), b = 8.3422(8), c = 19.7364(19) Å, α = 90, β = 90.660(2), γ = 90, V = 3681.8(6) Å3, Z = 8, Dc = 1.567 g cm-3, μ = 0.762 mm-1, R(int) = 0.419, Nref =
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Graphical Abstract-Pictogram
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This work presents a new 3D luminescent metal-organic framework. It can be used as a luminescence sensor for PA and Cr2O72- with excellent recyclability.
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Highlights
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1. A novel 3D MOF was successfully fabricated by the mixed ligand strategy. 2. It can be implemented as a luminescence sensor for Cr2O72- and PA. 3. It has good recyclability at least four times.