RU2821797C2 - Cartridge for collection and analysis of fine particles - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to technology of producing structured materials for supersensitive diagnostics of composition and structure of organic substances by SERS spectroscopy. Disclosed is a cartridge for collecting and analysing fine particles, having a housing and a means for capturing fine particles installed in it, having the possibility of surface amplification of Raman light scattering. At that, it is equipped with at least one device intended for deformation of means for catching fine particles, made in the form of a base, which is a film of polymer material with thickness of 10–20 mcm with an array of through, essentially identical cylindrical channels, coated with a layer of plasmon material with thickness of 50–200 nm, with degree of deformation of 10–15% with formation of microcracks in said layer of plasmon material.

EFFECT: invention provides multiple amplification of the SERS signal without deterioration of the quality of capturing fine particles.

4 cl, 7 dwg

Description

The invention relates to the field of technology for creating structured materials for ultrasensitive diagnostics of the composition and structure of organic substances using SERS spectroscopy (from the English SERS - surface-enhanced Raman scattering of light).

The Raman scattering method, which is ultra-sensitive to determining individual components of the substance under study, is low-intensity in nature, which limits the scope of its applications to research in scientific laboratories.

Structured SERS-active substrates make it possible to increase the intensity of the detected Raman scattering signal by several orders of magnitude, which makes it possible to study substances of low concentration, down to single molecules.

A cartridge is known for collecting and analyzing fine particles dispersed in the air, containing a housing and a means installed in it for collecting fine particles, which has the ability to surface enhance Raman scattering of light (see RU 2718911 C2, IPC G01N 1/22, publ. 04/15/2020 [1]).

Said means is a filter plate made, for example, of silicon nitride or aluminum oxide, with a plurality of filter pores, the edges of which form a reinforcement structure, or a filter membrane, made, for example, of polycarbonate, with a reinforcement structure formed by particles located on the surface filter membrane or embedded in it. As a consequence, the said agent is both a filter element and a SERS-active substrate.

The disadvantages of the known cartridge are that, as a result of the design features of the means for collecting fine particles, it does not provide amplification of the SERS signal to a level that allows the study of fine particles with the maximum degree of reliability. In addition, the size of the filtering area of the mentioned product is insignificant, which makes it difficult to use for its intended purpose.

As a rule, gold or silver nanoparticles are used as particles forming the enhancement structure in filter membranes (see, for example, the article by Lynn R. Terry et al. “Applications of surface-enhanced Raman spectroscopy in environmental detection,” Anal. Sci. Adv ., 2022, 3, pp. 113-145 [2]), which, among other things, complicates and increases the cost of manufacturing such means for collecting fine particles.

The cartridge disclosed in [1] is accepted as the closest analogue of the claimed cartridge.

The technical problem solved by the claimed invention is to create a cartridge for collecting and analyzing fine particles, allowing the study of fine particles contained in air or fluid with the maximum degree of reliability.

In this case, a technical result is achieved, which consists in providing multiple amplification of the SERS signal without reducing the quality of collection of fine particles.

The technical problem is solved, and the specified technical result is achieved by creating a cartridge for collecting and analyzing fine particles, containing a housing and a means installed in it for collecting fine particles, which has the ability to surface enhance Raman scattering of light. The cartridge is equipped with at least one means designed to deform the means for collecting fine particles, made in the form of a base, which is a film of polymer material 10-20 microns thick with an array of through identical cylindrical channels, coated with a layer of plasmonic metal 50-200 nm thick, at a degree of deformation of 10-15% with the formation of microcracks in the mentioned layer of plasmonic material.

In one of the particular variants, the mentioned base is a track membrane.

In another particular embodiment, the width of each of the mentioned microcracks is 4-7 nm.

In yet another particular embodiment, said means for deforming the means for collecting fine particles is designed to be stretchable.

In fig. Figure 1 shows a schematic representation of the claimed cartridge in a disassembled state, according to a particular version.

In fig. 2 shows a schematic illustration of a means for collecting fine particles.

In fig. 3a-3d show the sequence of use of the claimed cartridge.

The claimed cartridge shown in FIG. 1, contains a housing (1), a movable intermediate element (2), a means for catching fine particles (3) and two pressure plates (4), fixing it on the intermediate element (2) using screws (5).

The claimed cartridge is manufactured and used as follows.

1. A base (6) is obtained, which is a film made of a polymer material (for example, polycarbonate) 10-20 microns thick with an array of end-to-end, essentially identical cylindrical channels (7).

The use of a film with a thickness of less than 10 microns does not provide the required base rigidity (6). The use of a film with a thickness of more than 20 microns causes difficulties in the formation of through channels (7), which, as a consequence, does not guarantee the uniformity of their structure and, as a result, makes it difficult to use the means for trapping fine particles (3) for its intended purpose.

As a basis (6), a commercially available track membrane manufactured using ion-track technology can be used (see, for example, the article Apel P.Y., Dmitriev S.N. “Micro- and nanoporous materials produced using accelerated heavy ion beams,” Advances in Natural Sciences: Nanoscience and Nanotechnology, 2011, vol. 2, no. 1 [3]).

2. Plasmonic metal (mainly gold or silver) is applied (including, but not limited to, by vacuum deposition) to the surface of one of the large sides of the base (6) to form a layer (8) 50-200 nm thick on it.

The formation of a layer (8) with a thickness of less than 50 nm is impractical due to the impossibility of ensuring its homogeneity. In addition, such a layer is translucent, and the spectra of the base (6) made of a polymer material can appear in the spectra of the particles under study.

The formation of a layer (8) with a thickness of more than 200 nm is impractical due to the fact that such a layer will peel off during operation.

3. The thus obtained means for collecting fine particles (3) (see Fig. 2) is placed in the body (1) of the claimed cartridge (see Fig. 3a) with the side of the base (6) on which a layer (8) of plasmonic metal is formed , up on the intermediate element (2) and fixed with pressure plates (4) using screws (5).

Next (see Fig. 3b), the movable intermediate element (2) is moved relative to the longitudinal axis of the housing (1) until its protrusion (9) falls into the groove (10) of the housing and fixes the intermediate element (2) in position , providing deformation (and, specifically, biaxial longitudinal stretching) of the means for trapping fine particles (3), as a result of which microcracks form in the layer (8) of the plasmonic metal.

The intermediate element (2) with the protrusion (9) together with the groove (10) of the housing forms a means designed to deform the means for collecting fine particles (3).

Any other implementation of such a means is acceptable, as well as the use of more than one similar means, with its inherent functional purpose - deformation of the means for trapping fine particles (3), leading to the formation of microcracks in the layer (8) of the plasmonic metal.

By “microcracks” we mean cracks of microscopic or submicroscopic sizes, commensurate with the elements of the microstructure (see Encyclopedic Dictionary of Metallurgy, Moscow, Intermet Engineering, 2000 [4]).

It has been experimentally established that so-called microcracks are formed along the edges of microcracks. “hot spots” - areas in which the SERS signal is amplified many times (see the article Kovalets N.P., Kozhina E.R. et al. “Towards single molecule surface-enhanced raman scattering with novel type of metasurfaces synthesized by crack-stratching of metallized track membranes,” J. Chem. Phys., 2021 [5]), which allows the resulting structure to be used as a reinforcement structure, and a similar means for trapping fine particles (3) as a SERS-active substrate .

The width of the resulting microcracks depends on the magnitude of the deforming load applied to the means for trapping fine particles (3). The maximum enhancement of the SERS signal occurs when the width of each microcrack is 4-7 nm (which corresponds to a degree of deformation of 10-15%).

With this degree of deformation, the structure of the cylindrical channels (7) does not undergo significant changes, which allows for guaranteed capture of fine particles in cases where this is a prerequisite for the operation of the claimed cartridge (in particular, when filtering drinking water).

4. The claimed cartridge is placed in a filter cell designed to filter liquids, plant cell cultures or isolate volatile organic compounds. In this case, the means for collecting fine particles (3) is placed with the side of the base (6), on which a layer (8) of plasmonic metal is formed, towards the flow of particles (see Fig. 3c).

5. Fine particles are collected, after which the claimed cartridge is removed from the filter cell, and the deforming load is removed from the means for collecting fine particles (3) by releasing the protrusion (9) from the groove (10) of the housing (1) (see Fig. 3d ).

As a result, the cartridge returns to its original position (Fig. 3e).

The formation (as a result of the formation of microcracks in the layer (8) of the plasmonic metal) of the gain structure immediately before using the claimed cartridge allows one to avoid the problems of reducing the gain of the SERS signal during long-term storage of the means for collecting fine particles (3) before its use due to sulfidation of the layer (8 ) plasmonic metal.

In this case, in the case of the initial stretching of the base (6), after a certain period of time, its partial recovery (compression) occurs, as a result of which the microcracks in the layer (8) of the plasmonic material close. In this case, fine particles become trapped inside microcracks, which leads to an additional enhancement of the SERS signal.

6. Place the declared cartridge in the holder of a Raman microscope to take spectra and analyze the collected fine particles.

Alternatively, the claimed cartridge can be combined with a compact Raman spectrometer, which will allow spectra to be taken online or with some periodicity before the appearance of peaks of interest (for example, in the case of the appearance of certain chemicals in the atmosphere). After the peaks of interest appear, the cartridge can be returned to its original position, which can provide additional amplification of the SERS signal.

The claimed cartridge for collecting and analyzing fine particles, due to the peculiarities of its manufacture and use, allows for maximum amplification of the SERS signal, which, in turn, allows for the study of fine particles with the maximum degree of reliability without compromising the quality of their collection.

Claims (4)

1. A cartridge for collecting and analyzing fine particles, containing a housing and a means for collecting fine particles installed in it, having the ability to surface enhance Raman scattering of light, characterized in that it is equipped with at least one means designed to deform the means for collecting fine particles , made in the form of a base, which is a film of polymer material 10-20 microns thick with an array of end-to-end, essentially identical cylindrical channels, coated with a layer of plasmonic material 50-200 nm thick, with a degree of deformation of 10-15% with the formation of a plasmonic microcrack material. 2. The cartridge according to claim 1, characterized in that said base is a track membrane. 3. Cartridge according to claim 1 or 2, characterized in that the width of each of the mentioned microcracks is 4-7 nm. 4. The cartridge according to claim 1 or 2, characterized in that said means, designed to deform the means for collecting fine particles, is designed to stretch it.