PDF
Abstract
To realize highly sensitive and specific sensing toward sarin, an Eu(III) based metal-organic framework (Eu-CTTB-MOF), encompassing a π-conjugated organic ligand H4CTTB (4,4′,4″,4‴-(9H-carbazole-1,3,6,8-tetrayl)tetrabenzoic acid) was explored for ratiometric fluorescent sensing. An unprecedented specific recognition of nerve-agent sarin mimic diethyl chlorophosphate (DCP) in the presence of HCl interferent and a low limit of detection (LOD, 20.97 nM) were achieved. This excellent detection performance is driven by the dual hydrogen bonding and hydrophobic interaction between the CTTB organic ligand and DCP, which would cause a dramatic change in the molecular configuration of the CTTB ligand. Density functional theory (DFT) calculations further verify the recognition of DCP by Eu-CTTB-MOF could suppress the rotations of the aromatic rings in CTTB ligand, significantly reducing the nonradiative decay pathways and subsequently enhancing the fluorescent intensity of the CTTB ligand. Especially, the Eu-CTTB-MOF enables the immediate response to DCP vapor and excellent specificity towards DCP even in the presence of 18 types of interferents, including HCl vapor, structural analogs, and volatile organic solvent, and a gas detector with accurate detection of DCP in simulated scenarios, positioning the designed MOF as a promising sensing material for practical scenarios. We expect that the present sensing strategy will shine a light on the development of brand-new sensing materials for on-site detection applications.
Keywords
fluorescent sensing
/
metal-organic framework
/
nerve agent
/
rotation restricted emission
/
sarin
Cite this article
Download citation ▾
Cong Lyu, Chuanfang Zhao, Meimei Wang, Jiawen Li, Zhenzhen Cai, Xincun Dou, Baiyi Zu.
Exactly Restricting the Phenyl Ring Rotation in Metal-Organic Framework for Ultra-Sensitive and Specific Ratiometric Fluorescent Sensing of Sarin.
Aggregate, 2025, 6(8): e70053 DOI:10.1002/agt2.70053
| [1] |
R. Stone, “How to Defeat a Nerve Agent,” Science 359 (2018): 23.
|
| [2] |
L. K. Sydnes, “Update the Chemical Weapons Convention,” Nature 496 (2013): 25-26.
|
| [3] |
W. Q. Meng, A. C. Sedgwick, N. Kwon, et al., “Fluorescent Probes for the Detection of Chemical Warfare Agents,” Chemical Society Reviews 52 (2023): 601-662.
|
| [4] |
Q. Chen, J. Liu, S. Liu, et al., “Visual and Rapid Detection of Nerve Agent Mimics in Gas and Solution Phase by a Simple Fluorescent Probe,” Analytical Chemistry 95 (2023): 4390-4394.
|
| [5] |
P. Zheng, Z. Cui, H. Liu, W. Cao, F. Li, and M. Zhang, “Ultrafast-Response, Highly-Sensitive and Recyclable Colorimetric/Fluorometric Dual-Channel Chemical Warfare Agent Probes,” Journal of Hazardous Materials 415 (2021): 125619.
|
| [6] |
K. Liu, J. Zhang, Q. Shi, L. Ding, T. Liu, and Y. Fang, “Precise Manipulation of Excited-State Intramolecular Proton Transfer via Incorporating Charge Transfer Toward High-Performance Film-Based Fluorescence Sensing,” Journal of the American Chemical Society 145 (2023): 7408-7415.
|
| [7] |
L.-L. Yang, H. Wang, J. Zhang, et al., “Understanding the AIE Phenomenon of Nonconjugated Rhodamine Derivatives via Aggregation-Induced Molecular Conformation Change,” Nature Communications 15 (2024): 999.
|
| [8] |
X. Wang, S. S. Liew, J. Huang, Y. Hu, X. Wei, and K. Pu, “Dual-Locked Enzyme-Activatable Bioorthogonal Fluorescence Turn-On Imaging of Senescent Cancer Cells,” Journal of the American Chemical Society 146 (2024): 22689-22698.
|
| [9] |
H. Q. Yin, K. Tan, S. Jensen, et al., “A Switchable Sensor and Scavenger: Detection and Removal of Fluorinated Chemical Species by a Luminescent Metal-Organic Framework,” Chemical Science 12 (2021): 14189-14197.
|
| [10] |
X. Zhou, Y. Zeng, C. Liyan, X. Wu, and J. Yoon, “A Fluorescent Sensor for Dual-Channel Discrimination Between Phosgene and a Nerve-Gas Mimic,” Angewandte Chemie International Edition 55 (2016): 4729-4733.
|
| [11] |
K. Liu, M. Qin, Q. Shi, et al., “Fast and Selective Detection of Trace Chemical Warfare Agents Enabled by an ESIPT-Based Fluorescent Film Sensor,” Analytical Chemistry 94 (2022): 11151-11158.
|
| [12] |
X. Huang, Z. Jiao, Z. Guo, et al., “Development of Reaction-Based AIE Handy Pen for Visual Detection of Toxic Vapors,” ACS Materials Letters 3 (2021): 249-254.
|
| [13] |
S. Zhang, B. Yang, B. Yuan, et al., “Dual-State Fluorescent Probe for Ultrafast and Sensitive Detection of Nerve Agent Simulants in Solution and Vapor,” ACS Sensors 8 (2023): 1220-1229.
|
| [14] |
Z. Zhou, L. Zhang, L. Peng, et al., “Dynamic Response and Discrimination of Gaseous Sarin Using a Boron-Difluoride Complex Film-Based Fluorescence Sensor,” Aggregate 5 (2024): e629.
|
| [15] |
L. Zeng, T. Chen, B. Zhu, et al., “A Molecular Recognition Platform for the Simultaneous Sensing of Diverse Chemical Weapons,” Chemical Science 13 (2022): 4523-4532.
|
| [16] |
F. Xiao, D. Lei, C. Liu, et al., “Coherent Modulation of the Aggregation Behavior and Intramolecular Charge Transfer in Small Molecule Probes for Sensitive and Long-Term Nerve Agent Monitoring,” Angewandte Chemie International Edition 63 (2024): 202400453.
|
| [17] |
W. Mo, Z. Zhu, F. Kong, et al., “Controllable Synthesis of Conjugated Microporous Polymer Films for Ultrasensitive Detection of Chemical Warfare Agents,” Nature Communications 13 (2022): 5189.
|
| [18] |
J. Yao, Y. Fu, W. Xu, et al., “Concise and Efficient Fluorescent Probe via an Intromolecular Charge Transfer for the Chemical Warfare Agent Mimic Diethylchlorophosphate Vapor Detection,” Analytical Chemistry 88 (2016): 2497-2501.
|
| [19] |
H. Y. Li, S. N. Zhao, S. Q. Zang, and J. Li, “Functional Metal-Organic Frameworks as Effective Sensors of Gases and Volatile Compounds,” Chemical Society Reviews 49 (2020): 6364-6401.
|
| [20] |
M. O'Shaughnessy, J. Glover, R. Hafizi, et al., “Porous Isoreticular Non-Metal Organic Frameworks,” Nature 630 (2024): 102-108.
|
| [21] |
B. E. R. Snyder, A. B. Turkiewicz, H. Furukawa, et al., “A Ligand Insertion Mechanism for Cooperative NH3 Capture in Metal-Organic Frameworks,” Nature 613 (2023): 287-291.
|
| [22] |
R. W. Huang, Y. S. Wei, X. Y. Dong, et al., “Hypersensitive Dual-Function Luminescence Switching of a Silver-Chalcogenolate Cluster-Based Metal-Organic Framework,” Nature Chemistry 9 (2017): 689-697.
|
| [23] |
S. Wu, H. Min, W. Shi, and P. Cheng, “Multicenter Metal-Organic Framework-Based Ratiometric Fluorescent Sensors,” Advanced Materials 32 (2020): 1805871.
|
| [24] |
R. Zang, Y. Liu, Y. Wang, et al., “Defect Engineering Zr-MOF-Endowed Activity-Dimension Dual-Sieving Strategy for Anti-acid Recognition of Real Phosphoryl Fluoride Nerve Agents,” Advanced Functional Materials (2025): 2425082, https://doi.org/10.1002/adfm.202425082.
|
| [25] |
W. P. Lustig, S. Mukherjee, N. D. Rudd, A. V. Desai, J. Li, and S. K. Ghosh, “Metal-Organic Frameworks: Functional Luminescent and Photonic Materials for Sensing Applications,” Chemical Society Reviews 46 (2017): 3242-3285.
|
| [26] |
J. Wang, D. Li, Y. Ye, et al., “A Fluorescent Metal-Organic Framework for Food Real-Time Visual Monitoring,” Advanced Materials 33 (2021): 2008020.
|
| [27] |
B. Song, D. Lu, A. Qin, and B. Z. Tang, “Combining Hydroxyl-Yne and Thiol-Ene Click Reactions to Facilely Access Sequence-Defined Macromolecules for High-Density Data Storage,” Journal of the American Chemical Society 144 (2021): 1672-1680.
|
| [28] |
H. Zhao, Y. Liu, G. Li, et al., “Electrophilicity Modulation for Sub-ppm Visualization and Discrimination of EDA,” Advanced Science 11 (2024): 2400361.
|
| [29] |
J. Wang, T. Tian, R. Zhang, et al., “Efficient Conversion of Inert Nitriles to Multifunctional Poly(5-amino-1,2,3-triazole)s via Regioselective Click Polymerization With Azide Monomers Under Ambient Conditions,” Journal of the American Chemical Society 146 (2024): 6652-6664.
|
| [30] |
J. Xu, M. Huang, H. Pang, et al., “C─H···π Interaction Induced H-Aggregates for Wide Range Water Content Detection in Organic Solvents,” Aggregate 5 (2024): e546.
|
| [31] |
Y. Feng, D. Lei, B. Zu, J. Li, Y. Li, and X. Dou, “A Self-Accelerating Naphthalimide-Based Probe Coupled With Upconversion Nanoparticles for Ultra-Accurate Tri-Mode Visualization of Hydrogen Peroxide,” Advanced Science 11 (2024): 2309182.
|
| [32] |
X. He, H. Xie, L. Hu, et al., “A Versatile AIE Fluorogen With Selective Reactivity to Primary Amines for Monitoring Amination, Protein Labeling, and Mitochondrial Staining,” Aggregate 4 (2022): e239.
|
| [33] |
Z. H. Zhu, Z. Ni, H. H. Zou, G. Feng, and B. Z. Tang, “Smart Metal-Organic Frameworks With Reversible Luminescence/Magnetic Switch Behavior for HCl Vapor Detection,” Advanced Functional Materials 31 (2021): 2106925.
|
| [34] |
J. Qiao, X. Liu, L. Zhang, J. F. Eubank, X. Liu, and Y. Liu, “Unique Fluorescence Turn-On and Turn-Off-On Responses to Acids by a Carbazole-Based Metal-Organic Framework and Theoretical Studies,” Journal of the American Chemical Society 144 (2022): 17054-17063.
|
| [35] |
J. Wang, J. Mei, R. Hu, J. Z. Sun, A. Qin, and B. Z. Tang, “Click Synthesis, Aggregation-Induced Emission, E / Z Isomerization, Self-Organization, and Multiple Chromisms of Pure Stereoisomers of a Tetraphenylethene-Cored Luminogen,” Journal of the American Chemical Society 134 (2012): 9956-9966.
|
| [36] |
C. Y. Liu, X. R. Chen, H. X. Chen, et al., “Ultrafast Luminescent Light-Up Guest Detection Based on the Lock of the Host Molecular Vibration,” Journal of the American Chemical Society 142 (2020): 6690-6697.
|
| [37] |
Z. Li, F. Jiang, M. Yu, S. Li, L. Chen, and M. Hong, “Achieving Gas Pressure-Dependent Luminescence From an AIEgen-Based Metal-Organic Framework,” Nature Communications 13 (2022): 2142.
|
| [38] |
X. L. Lv, L. Feng, L. H. Xie, et al., “Linker Desymmetrization: Access to a Series of Rare-Earth Tetracarboxylate Frameworks With Eight-Connected Hexanuclear Nodes,” Journal of the American Chemical Society 143 (2021): 2784-2791.
|
| [39] |
X.-L. Lv, L.-H. Xie, B. Wang, M. Zhao, Y. Cui, and J.-R. Li, “Flexible Metal-Organic Frameworks for the Wavelength-Based Luminescence Sensing of Aqueous pH,” Journal of Materials Chemistry C 6 (2018): 10628-10639.
|
| [40] |
B. A. Maynard, P. A. Smith, L. Ladner, et al., “Emission Enhancement Through Dual Donor Sensitization: Modulation of Structural and Spectroscopic Properties in a Series of Europium Tetracyanoplatinates,” Inorganic Chemistry 48 (2009): 6425-6435.
|
| [41] |
S. Wu, Y. Lin, J. Liu, W. Shi, G. Yang, and P. Cheng, “Rapid Detection of the Biomarkers for Carcinoid Tumors by a Water Stable Luminescent Lanthanide Metal-Organic Framework Sensor,” Advanced Functional Materials 28 (2018): 1707169.
|
| [42] |
H.-Q. Yin, X.-Y. Wang, and X.-B. Yin, “Rotation Restricted Emission and Antenna Effect in Single Metal-Organic Frameworks,” Journal of the American Chemical Society 141 (2019): 15166-15173.
|
| [43] |
Y. Li, S. Zhang, and D. Song, “A Luminescent Metal-Organic Framework as a Turn-On Sensor for DMF Vapor,” Angewandte Chemie International Edition 52 (2013): 710-713.
|
| [44] |
J.-J. Pang, Z.-Q. Yao, K. Zhang, et al., “Real-Time In Situ Volatile Organic Compound Sensing by a Dual-Emissive Polynuclear Ln-MOF With Pronounced Ln III Luminescence Response,” Angewandte Chemie International Edition 62 (2022): e202217456.
|
| [45] |
Y. Hu, R. S. H. Khoo, J. Lu, X. Zhang, and J. Zhang, “Robust Carbazole-Based Rare-Earth MOFs: Tunable White-Light Emission for Temperature and DMF Sensing,” ACS Applied Materials & Interfaces 14 (2022): 41178-41185.
|
| [46] |
B. Díaz de Greñu, D. Moreno, T. Torroba, et al., “Fluorescent Discrimination Between Traces of Chemical Warfare Agents and Their Mimics,” Journal of the American Chemical Society 136 (2014): 4125-4128.
|
| [47] |
C. Yan, Z. Guo, W. Chi, et al., “Fluorescence Umpolung Enables Light-Up Sensing of N-Acetyltransferases and Nerve Agents,” Nature Communications 12 (2021): 3869.
|
| [48] |
P. Liu, C. Chu, W. Qiu, et al., “3D/4D Printed Versatile Fibre-Based Wearables for Embroidery, AIE-Chemosensing, and Unidirectional Draining,” Aggregate 5 (2024): e521.
|
| [49] |
H. Xu and P. Cheng, “Metal-Organic Frameworks With Aggregation-Induced Emission,” Aggregate 5 (2024): e518.
|
| [50] |
J. Ren, Z. Niu, Y. Ye, et al., “Second-Sphere Interaction Promoted Turn-On Fluorescence for Selective Sensing of Organic Amines in a Tb III -Based Macrocyclic Framework,” Angewandte Chemie International Edition 60 (2021): 23705-23712.
|
| [51] |
M. J. Frisch, G. W. Trucks, H. B. Schlegel, et al., Gaussian 09, Revision C.01 (Gaussian, Inc., 2016).
|
| [52] |
Y. Zhao and D. G. Truhlar, “The M06 Suite of Density Functionals for Main Group Thermochemistry, Thermochemical Kinetics, Noncovalent Interactions, Excited States, and Transition Elements: Two New Functionals and Systematic Testing of Four M06-Class Functionals and 12 Other Functionals,” Theoretical Chemistry Accounts 120 (2008): 215-241.
|
| [53] |
Y. Zhao and D. G. Truhlar, “Density Functionals With Broad Applicability in Chemistry,” Accounts of Chemical Research 41 (2008): 157-167.
|
| [54] |
V. A. Rassolov, M. A. Ratner, J. A. Pople, P. C. Redfern, and L. A. Curtiss, “6-31G* Basis Set for Third-Row Atoms,” Journal of Computational Chemistry 22 (2001): 976-984.
|
| [55] |
C. Lefebvre, G. Rubez, H. Khartabil, J.-C. Boisson, J. Contreras-Garcia, and E. Henon, “Accurately Extracting the Signature of Intermolecular Interactions Present in the NCI Plot of the Reduced Density Gradient Versus Electron Density,” Physical Chemistry Chemical Physics 19 (2017): 17928-17936.
|
| [56] |
T. Lu, “A Comprehensive Electron Wavefunction Analysis Toolbox for Chemists, Multiwfn,” Journal of Chemical Physics 161 (2024): 082503.
|
| [57] |
E. Espinosa, E. Molins, and C. Lecomte, “Hydrogen Bond Strengths Revealed by Topological Analyses of Experimentally Observed Electron Densities,” Chemical Physics Letters 285 (1998): 170-173.
|
| [58] |
D. Feller, “The Role of Databases in Support of Computational Chemistry Calculations,” Journal of Computational Chemistry 17 (1996): 1571-1586.
|
| [59] |
T. Brinck, A. G. Larsen, K. M. Madsen, and K. Daasbjerg, “Solvation of Carbanions in Organic Solvents: A Test of the Polarizable Continuum Model,” Journal of Physical Chemistry B 104 (2000): 9887-9893.
|
| [60] |
R. Valero, R. Costa, I. d. P. R. Moreira, D. G. Truhlar, and F. Illas, “Performance of the M06 Family of Exchange-Correlation Functionals for Predicting Magnetic Coupling in Organic and Inorganic Molecules,” Journal of Chemical Physics 128 (2008): 114103.
|
| [61] |
B. C. De Simone, T. Marino, and N. Russo, “TDDFT Investigation on Methylviologen, 3,7-Diazabenzophosphole, and Helical Helquat Electrochromic Systems,” Theoretical Chemistry Accounts 135 (2016): 118.
|
| [62] |
Z. M. E. Fahim, S. M. Bouzzine, A. A. Youssef, M. Bouachrine, and M. Hamidi, “Ground State Geometries, UV/vis Absorption Spectra and Charge Transfer Properties of Triphenylamine-Thiophenes Based Dyes for DSSCs: A TD-DFT Benchmark Study,” Computational & Theoretical Chemistry 1125 (2018): 39-48.
|
| [63] |
V. A. Rassolov, J. A. Pople, M. A. Ratner, and T. L. Windus, “6-31G* Basis Set for Atoms K Through Zn,” Journal of Chemical Physics 109 (1998): 1223-1229.
|
| [64] |
S. N. Maximoff, M. Ernzerhof, and G. E. Scuseria, “Current-Dependent Extension of the Perdew-Burke-Ernzerhof Exchange-Correlation Functional,” Journal of Chemical Physics 120 (2004): 2105-2109.
|
| [65] |
S. Grimme, S. Ehrlich, and L. Goerigk, “Effect of the Damping Function in Dispersion Corrected Density Functional Theory,” Journal of Computational Chemistry 32 (2011): 1456-1465.
|
| [66] |
H. Roohi and T. Pouryahya, “Tuning the Photophysical Properties of ESIPT Active Unsymmetrical Zzine Dyes by the Change in the Substituent and Solvent: TD-PBE0 and TD-CAM-B3LYP Studies,” Molecular Systems Design & Engineering 9 (2024): 625-648.
|
| [67] |
C. Y. Legault, CYLview 1.0b. (Université de Sherbrooke, 2009).
|
RIGHTS & PERMISSIONS
2025 The Author(s). Aggregate published by SCUT, AIEI, and John Wiley & Sons Australia, Ltd.
