CN113008853A

CN113008853A - Method for in-situ marking and visual tracing of explosive based on fluorescent energetic molecules

Info

Publication number: CN113008853A
Application number: CN202110210082.2A
Authority: CN
Inventors: 陈建波; 丁欢; 刘渝; 陈娅
Original assignee: Institute of Chemical Material of CAEP
Current assignee: Institute of Chemical Material of CAEP
Priority date: 2021-02-25
Filing date: 2021-02-25
Publication date: 2021-06-22
Anticipated expiration: 2041-02-25
Also published as: CN113008853B

Abstract

The invention discloses an in-situ labeling and visual tracing method for explosives based on fluorescent energetic molecules, which comprises the following steps: step 1: constructing fluorescent energetic molecules; step 2: investigating the spectral property of the fluorescent energetic molecule; and step 3: optimizing the luminescence signal of the fluorescence energetic molecule; and 4, step 4: and (3) marking and tracing the explosive by the fluorescent energetic molecules. The invention provides a method for enlarging a conjugated system of an explosive aiming at the marking and tracing technology of the explosive, and regulates and controls the chemical position of a nitro group to be used as a chromogenic group so as to enhance the light absorption efficiency, so that the nitro group can not quench the fluorescence of explosive molecules but enhance the fluorescence of the explosive molecules, thereby realizing the marking and tracing of the explosive.

Description

Method for in-situ marking and visual tracing of explosive based on fluorescent energetic molecules

Technical Field

The invention relates to the technical fields of energetic materials, public safety, environmental protection and the like, and an embodiment of the invention relates to the analysis of the existence and the content of a fluorescent energetic molecule through a self fluorescent signal of the fluorescent energetic molecule, and the fluorescent energetic molecule can be doped in other explosives to further mark and trace the other explosives so as to improve the detection sensitivity and the naked eye visibility of the other explosives.

Background

Explosives, as a high energy material, are widely used in the fields of weapon systems, civil blasting, etc. due to their high energy characteristics and destructive effects. The analysis and detection of the explosive not only relate to the quality control of the development and production process, but also relate to the environmental detection of manufacturing sewage or using sites, and in addition, the analysis and detection of the explosive plays an important role in terrorist explosion early warning in the field of public safety. However, the explosive molecules themselves have weak conjugated systems or strong electron-withdrawing groups, so that the explosive molecules themselves do not actively emit signals. Currently, in order to realize highly sensitive in-situ detection of explosives, an additional design is usually required to prepare a fluorescent sensing material, and the molecules of the explosives are indirectly detected by using fluorescence quenching caused by the interaction of the fluorescent sensing material and the molecules of the explosives. Most fluorescent materials are conventional materials, cannot be used as energetic materials by themselves, and when the fluorescent materials are doped into explosives, the energy of the explosives is reduced, so that the high-energy characteristics of the explosives are not maintained. The novel material with both fluorescence and high energy, namely the fluorescent energetic molecules, is developed, so that the high energy of the explosive can be kept, the explosive can be endowed with an actively emitted signal, and the analysis detection and naked eye identification of the explosive can be realized without additionally preparing a sensing material. However, so far, no report on the use of fluorescent energetic molecules for explosive labeling and tracing has been found.

Disclosure of Invention

At present, the self-conjugated system of explosive molecules is weaker, or the explosive molecules have strong electron-withdrawing nitro groups, so that the explosive molecules do not have actively-emitted fluorescent signals, and the explosive molecules cannot be directly subjected to in-situ detection and naked eye identification. Therefore, the invention provides the fluorescent energetic molecules based on the fluorescence emission signals, which are used for in-situ labeling and visual tracing analysis of explosive molecules.

In order to achieve the purpose, the invention adopts the following technical scheme:

in order to realize the autofluorescence emission of the nitro-explosive, expand the conjugated system of explosive molecules, generate fluorescence enhancement signals, investigate the fluorescence properties of the nitro-explosive, optimize the generation conditions of the fluorescence signals, dope the nitro-explosive into other explosive molecules, investigate the marking effect and the tracing condition of the nitro-explosive in a solution or solid state, and finally form a high-sensitivity marking and visual tracing technology for the nitro-explosive based on the fluorescence energetic molecules.

In order to obtain a novel dissolving technology and a novel dissolving method aiming at TATB, the invention adopts the following specific technical scheme:

(1) construction of novel fluorescent energetic molecules: in order to enable the nitrobenzene explosive molecules to have a fluorescence effect, a conjugated system of the nitrobenzene explosive molecules is firstly expanded, and the number of phenyl condensed rings is not less than 3. Then, a nitro group is introduced to serve as a chromophore, and the position of the nitro group is regulated so that the absorption coefficient and the luminous efficiency of explosive molecules are high. In addition, the introduced nitro group also serves as an explosion-causing group, so that the energy level of the fluorescent molecule is improved, and the fluorescent molecule becomes a fluorescent energetic molecule.

(2) Examination of spectral properties of fluorescent energetic molecules: and (3) observing the ultraviolet absorption spectrum and the maximum absorption wavelength of the fluorescent energetic molecules by using an ultraviolet absorption spectrometer, observing the fluorescent emission spectrum and the maximum emission wavelength of the fluorescent energetic molecules by using the fluorescent spectrometer, and calculating the spectral parameters of the fluorescent energetic molecules, such as the molar absorption coefficient, the Stokes shift, the fluorescence quantum yield and the like.

(3) Optimizing the luminescence signal of the fluorescent energetic molecule: the influence of different solvents such as acetonitrile, methanol, dimethyl sulfoxide, dimethyl formamide and the like on fluorescence signals of the fluorescent energetic molecules is inspected, the influence of different water contents on the fluorescence signals of the fluorescent energetic molecules is analyzed, and the influence of different pH values on the fluorescence signals of the fluorescent energetic molecules is researched. The conditions are optimized such that the fluorescent energetic molecule has an optimal fluorescence emission signal.

(4) Marking and tracing explosive by fluorescent energetic molecules: a certain amount of fluorescent energetic molecules are doped into other non-luminous explosives such as TNT, HMX and PETN. Establishing a liquid sample high-sensitivity marking technology, and inspecting the detection sensitivity of fluorescent energetic molecules to other explosive in-situ marks by adopting a fluorescence spectrometer. Establishing a visual tracing technology of the solid sample, and inspecting the sensitivity of the fluorescent energetic molecules to other explosive visual detection by adopting a fluorescent microscopic imaging technology.

Compared with the prior art, the invention has the beneficial effects that:

the invention provides a method for enlarging a conjugated system of an explosive aiming at the marking and tracing technology of the explosive, and regulates and controls the chemical position of a nitro group to be used as a chromogenic group so as to enhance the light absorption efficiency, so that the nitro group can not quench the fluorescence of explosive molecules but enhance the fluorescence of the explosive molecules, thereby realizing the marking and tracing of the explosive.

Drawings

Fig. 1 is a flow chart of a construction strategy of BPTAP, wherein a: extended conjugated system, b: introducing nitro group.

FIG. 2 shows fluorescence signals of BPTAP in different solvents, wherein 1: DMSO, 2: DMF, 3: acetonitrile, 4: methanol.

FIG. 3 is the optimum solubility of TATB for the novel solvent system (10 g).

FIG. 4 shows the morphology of BPTAP itself.

Detailed Description

The present invention will be further described with reference to the following examples, which are intended to illustrate only some, but not all, of the embodiments of the present invention. Based on the embodiments of the present invention, other embodiments used by those skilled in the art without any creative effort belong to the protection scope of the present invention.

Example 1

(1) Construction of BPTAP fluorescent energetic molecules: the tetra-aza-pentalene is taken as a core structure, phenyl and pyridine are respectively arranged on two sides to form a condensed ring structure with 4 rings connected in parallel, and the conjugation degree of a molecular system is enlarged (figure 1). Four nitro groups are introduced into 2,4,8 and 10 positions of benzo-1, 3a,6,6 a-tetraazapentalenopyridine, and the introduced four nitro groups are used as chromophores to improve light absorption and luminous efficiency. On the other hand, the introduced four nitro groups are used as explosion-causing groups to improve the energy level, so that BPTAP has good thermal stability (thermal decomposition temperature is 375 ℃) and detonation energy (detonation velocity is 7.43 km/s).

(2) Spectral properties of BPTAP study:

the ultraviolet absorption spectrum range of BPTAP obtained by an ultraviolet absorption spectrometer is 400-600nm, and the maximum absorption wavelength is 460 nm. The fluorescence emission spectrum range of the BPTAP obtained by a fluorescence spectrometer is 450-650nm, and the maximum emission wavelength of the BPTAP is 508 nm. The calculated molar absorption coefficient of BPTAP is 4.12X 10⁴M^-1·cm^-1Stoke ofShift by 48nm, fluorescence quantum yield was 0.24.

(3) Fluorescence signal optimization of BPTAP: when 5. mu.g of BPTAP was dissolved in 10mL of different solvents such as acetonitrile, methanol, dimethyl sulfoxide, dimethylformamide and the like, the fluorescence intensity of BPTAP in acetonitrile, methanol, dimethyl sulfoxide and dimethylformamide was 105.77, 16.75, 4.99 and 5.33 respectively, and the highest fluorescence intensity of BPTAP in acetonitrile was observed (FIG. 2). The fluorescence intensity is respectively reduced by 21%, 64% and 73% by adding 10%, 20% and 40% of water into the BPTAP solvent system, and the fluorescence signal of the BPTAP is obviously reduced by increasing the water content. The fluorescence signals of BPTAP in different pH environments, such as pH values of 5, 6, 7, 8, 9, etc., were tested, and it was found that the fluorescence intensity of BPTAP decreased greatly when the pH value was greater than 7.0. Through condition optimization, the optimal conditions of the BPTAP fluorescent signal are acetonitrile solution, no water and pH value not more than 7.0.

(4) Labelling and tracing studies of BPTAP on explosives:

the fluorescence signals of BPTAP with different concentrations (0.1-1 mug/mL) are tested (figure 3), and the fluorescence intensity and the concentration have good linear relation and the correlation coefficient R²The detection limit was 0.03ppm at 0.998. Aiming at the liquid sample marking test of other explosives, 1mg of BPTAP is respectively doped in 100mg of TNT and HMX, and the test finds that the concentration range of TNT and HMX is 1-50 mu g/mL, the marking of TNT and HMX has good linear relation and the correlation coefficient R²The detection limit of BPTAP-based labeling for TNT and HMX was 0.48ppm and 0.15ppm, respectively, as 0.997. Aiming at a visual tracing test (figure 4) of a solid sample of other explosives, 5mg of BPTAP is respectively doped in 100mg of TNT and HMX, the mixture is uniformly mixed and then placed under a fluorescence microscope for testing, and uniform and obvious fluorescence signals in the mixed explosive sample are found, which indicates that the BPTAP realizes the visual tracing of TNT and HMX.

2,4,8, 10-tetranitrobenzo-1, 3a,6,6 a-tetraazapentalenopyridine (BPTAP) is used as a fluorescent energetic molecule and has a large condensed ring system and 4 nitro group groups, the maximum emission wavelength of the BPTAP is 508, the fluorescence quantum yield is 0.24, obvious green fluorescence is shown in both liquid state and solid state, a in figure 4 is the shape of the BPTAP, and b in figure 4 is the fluorescence emission effect of the BPTAP under an ultraviolet lamp. For the highly sensitive labeling of liquid samples, the sensitivity of BPTAP itself was 0.03ppm, and the sensitivity to TNT and HMX labels was 0.48ppm and 0.15ppm, respectively. Aiming at the visual tracing of a solid sample, the crystal of BPTAP has bright fluorescence, and obvious visual effect is shown by doping 5% of BPTAP into TNT and HMX solid powder, wherein c in fig. 4 is the original appearance of the TNT explosive doped with BPTAP, and d in fig. 4 is the fluorescence emission and tracing effect of the BPTAP doped in the TNT under an ultraviolet lamp.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. The method for in-situ marking and visual tracing of explosives based on fluorescent energetic molecules is characterized by comprising the following steps:

step 1: constructing fluorescent energetic molecules;

step 2: investigating the spectral property of the fluorescent energetic molecule;

and step 3: optimizing the luminescence signal of the fluorescence energetic molecule;

and 4, step 4: and (3) marking and tracing the explosive by the fluorescent energetic molecules.

2. The method for in-situ labeling and visual tracing of explosives based on fluorescent energetic molecules as claimed in claim 1, wherein in step 1, the construction of fluorescent energetic molecules comprises: enlarging the conjugated system of nitrobenzene explosive molecules, wherein the number of condensed phenyl rings is not less than 3; the introduction of nitro group as chromophore and the regulation of nitro position makes the explosive molecule possess high light absorption coefficient and luminous efficiency.

3. The method for in-situ labeling and visual tracing of explosives based on fluorescent energetic molecules as claimed in claim 1 wherein in step 2, the investigation of the spectral properties of fluorescent energetic molecules comprises: and calculating the molar absorption coefficient, Stokes shift and fluorescence quantum yield spectral parameters of the fluorescent energetic molecules.

4. The method for in-situ labeling and visual tracing of explosives based on fluorescent energetic molecules as claimed in claim 3, wherein the investigation of the spectral properties of the fluorescent energetic molecules specifically comprises: and (3) adopting an ultraviolet absorption spectrometer to inspect the ultraviolet absorption spectrum and the maximum absorption wavelength of the fluorescent energetic molecules, and adopting a fluorescence spectrometer to inspect the fluorescence emission spectrum and the maximum emission wavelength of the fluorescent energetic molecules.

5. The method for in-situ labeling and visual tracing of explosives based on fluorescent energetic molecules as claimed in claim 1 wherein in step 3, the luminescent signal of fluorescent energetic molecules is optimized, comprising: and (3) investigating the influence of different solvents on the fluorescence signal of the fluorescent energetic molecule, analyzing the influence of different water contents on the fluorescence signal of the fluorescent energetic molecule, and researching the influence of different pH values on the fluorescence signal of the fluorescent energetic molecule.

6. The method for in-situ labeling and visual tracing of explosives based on fluorescent energetic molecules as claimed in claim 1 wherein in step 4, the labeling and tracing of explosives by fluorescent energetic molecules comprises: doping fluorescent energetic molecules into other non-luminous explosives, establishing a liquid sample high-sensitivity marking technology, and inspecting the detection sensitivity of the fluorescent energetic molecules to the in-situ marking of the other explosives by using a fluorescence spectrometer; establishing a visual tracing technology of the solid sample, and inspecting the sensitivity of the fluorescent energetic molecules to other explosive visual detection by adopting a fluorescent microscopic imaging technology.