KR20110068452A - Raman spectroscopy for detection of chemical residues at surface of specimen and raman spectroscopy using the same - Google Patents

Abstract

PURPOSE: A raman spectroscope for detecting residual chemical materials on the surface of sample and a raman spectroscopic analysis method using the same are provided to use easily for detecting chemical materials remaining on the surface without damaging sample in a field. CONSTITUTION: A raman spectroscope for detecting residual chemical materials on the surface of sample comprises: a light source generating incident light; a detector receiving scattered light from sample with the incident light and generating signals to indicate the spectrum intensity of a specific wavelength band; an access probe(102) collecting the incident light and putting into the sample, and collecting the scattered light and transmitting to the detector; first light fiber(104) connecting the light source with the access probe; and second light fiber(105) connecting the access probe and the detector.

Description

Raman spectroscopy for detection of chemical residues at surface of specimen and Raman spectroscopy using the same}

The present invention relates to the detection of trace chemicals remaining on the surface of a sample by introducing light into the sample and quantitatively analyzing the Raman light scattered therefrom.

When radiation, such as light, passes through a material, the radiation passes through the material or is absorbed or scattered by the material. When radiation penetrates a material, the oscillating electric field of radiation causes electrons in the material to oscillate around the nucleus, causing periodic polarization, which is the energy that was used to momentarily polarize molecules if radiation is not absorbed. Is emitted in all directions in the form of radiation when the material returns to its original state. Since there is no change in energy in the radiation scattering process, the emitted radiation has a wavelength equal to the wavelength of incident light, which is called elastic scattering or rayleigh scattering. However, in this process, one of the millions of incident photons is scattered with different energies. In other words, the interaction between radiation and the material causes some of the energy of the radiation to be used to transfer the vibrational energy levels of molecules in the material, resulting in emission of radiation with a wavelength different from the incident light. This phenomenon is called inelastic scattering or Raman. It is called Raman scattering. Raman spectroscopy using such Raman scattering, when Indian scientist CV Raman (Chandrasekhara Venkata Raman) injects a single frequency of incident light into a material about 70 years ago, scattered light having an energy different from that of incident light is observed. The energy difference at this time is used as a means of obtaining information on the vibration and molecular structure of molecules and crystals after discovering the Raman scattering phenomenon determined by the properties of the material. Since Raman spectroscopy can obtain information on the vibration characteristics of atoms that make up a material, it is very sensitive to the short-range order of atoms and the mass of atoms when changes around atoms make such defects of substitution / intrusion possible. When used, it is very useful for observing the behavior of dopants. In addition, since the laser is used as the excitation light, polarization measurement, low temperature measurement and high pressure measurement for small amount of samples such as gas, liquid and solid can be performed. In addition, by attaching an optical microscope to a general spectrometer, spatial resolution can be seen up to micron units, so local analysis is also possible. Raman spectroscopy, which has these advantages, can be applied to both organic and inorganic materials, so that not only structural, vibration, and short-lived molecular species can be applied throughout the material but also in medicine, biology, environmental science, It is widely applied to geology, mineralogy, archeology, etc., and it is possible to obtain various information that cannot be obtained by other analytical techniques.

In general, Raman spectroscopy uses a condensing optical system in which lenses or mirrors are variously combined on an optical table in order to transmit incident light generated from a light source or scattered light scattered from a sample. However, since the condensing optical system is complicated in its construction and requires precise arrangement of the optical system, there are various restrictions when constructing a spectroscope for detecting chemical components such as pesticides remaining on the surface of vegetables, for example, pesticides. .

An object of the present invention is to provide a Raman spectrometer and a Raman spectroscopy method using the same, based on the Raman scattering technology, which can be easily used for detecting chemicals remaining on the surface without damaging the sample in the field. In this case, agricultural products such as vegetables or fruits may be used as the sample, and chemicals include pesticides used in these agricultural products. The object of the present invention is not limited to those mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

According to a first aspect of the present invention for solving this problem, a detector for generating a signal representing a spectral intensity of a specific wavelength band by receiving a scattered light from a light source for generating incident light and a sample into which the incident light is input and focusing the incident light The Raman spectrometer including a focusing probe is added to the sample, and the scattered light is focused and transmitted to the detector.

In this case, the first aspect of the present invention may further include a first optical fiber connecting the light source and the focusing probe and a second optical fiber connecting the focusing probe and the detector.

In another aspect according to the first aspect of the present invention, the focusing probe focuses a first lens for refracting and passing the incident light input from a connection portion connected to the first optical fiber and an incident light transmitted through the first lens. And a second lens for refracting and passing the scattered light scattered by the incident light introduced into the sample, and a scattering light transmitted through the second lens to focus the second optical fiber into a connection portion to which the second optical fiber is connected. Disposed between a third lens and the first and third lenses and the second lens, the incident light passing through the first lens is transmitted without refraction to the second lens, and scattered light passing through the second lens is transmitted. It may include a prism to reflect and transmit to the third lens.

In still another feature according to the first aspect of the present invention, an optical filter may be further disposed between the first lens and the prism or between the third lens and the prism.

In still another feature according to the first aspect of the present invention, the prism refracts incident light passing through the first prism as a surface in contact with the first prism and the first prism through which the incident light passing through the first lens is refracted. A second prism having a first surface passing through the second lens and reflecting the scattered light passing through the second lens, and a second surface reflecting the scattered light reflected from the first surface and transmitting the reflected light to the third lens. Can be.

In still another feature according to the first aspect of the invention, the first and second prisms may have the same refractive index.

In still another feature according to the first aspect of the present invention, the surfaces of the first and second prisms may be an antireflective multilayer coating in which the refractive index is gradually changed.

In still another aspect of the present invention, an angle formed by scattered light passing through the first surface and the second lens or an angle formed by scattered light reflected from the third surface and the first surface is determined by the second aspect. It may be set larger than the total reflection critical angle of the prism.

In another aspect according to the first aspect of the present invention, the second prism may include a third prism having the first surface and a fourth prism having one surface in contact with the third prism and having the third surface. Can be.

According to a second aspect of the present invention there is provided a Raman spectroscopy method for detecting chemicals remaining on the surface of a sample using any of the Raman spectroscopy described above.

According to one feature of the second aspect of the present invention, the sample may be a prototype of the produce or may be produced by cutting an area including the surface portion of the produce.

According to another feature of the second aspect of the present invention, the sample may be prepared in powder form by separating the surface portion of the agricultural product, or may be a liquid squeezed after separating the surface portion.

According to another feature of the second aspect of the invention, the produce may comprise paprika.

According to another feature of the second aspect of the invention, the chemical can be any one of Bensultap, Tolclofos-methyl, Flufenoxuron, Kresoxim-methyl, Metalaxyl, Pencycuron, Procymidone, Triophanate, Chlorpyrifos, Carbofuran, Carbendazaim, and Diazinon have.

According to the Raman spectrometer according to the present invention, chemical components such as pesticides remaining on the surface of various vegetables or fruits can be easily and accurately detected in the field. The effects of the present invention are not limited to those mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the following description.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. In addition, in describing the present invention, when it is determined that the detailed description of the related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 shows a Raman spectrometer 100 according to an embodiment of the present invention. As shown in FIG. 1, the Raman spectrometer 100 according to an exemplary embodiment of the present invention includes a light source 101 for generating light to be input to an analysis target and a sample holder 106 for mounting a sample to be analyzed. ) And a detector 103 for receiving a scattered light scattered from a sample into which incident light is input and generating a signal indicating a spectral intensity of a specific wavelength band, and focusing the incident light into the sample, focusing the scattered light, and detecting the scattered light. Focusing probe 102 to transmit to.

In this case, the light source 101 includes a laser light source that emits light in the visible light region. Since the intensity of Raman scattering is proportional to the square of the frequency of the light emitted from the light source, it may be advantageous to use radiation of short wavelength if possible, but if the wavelength is shorter than visible light, the photolysis of the sample occurs and the sample exhibits fluorescence. Since this problem appears larger as the wavelength is shorter, it is important to select a laser light source that emits radiation of an appropriate wavelength. As a laser light source, a semiconductor laser called a junction laser or a diode laser can be used. Such a semiconductor laser is very efficient, easy to handle, and can be manufactured in a small size, and is continuous. wave: CW) is possible.

Meanwhile, in the embodiment of the present invention, the movement path from the light source 101 of the incident light to the focusing probe 102 and the movement path of the scattered light from the focusing probe 102 to the detector 103 are respectively optical fibers 104 and 105. Is made of. That is, the light source 10 and the focusing probe 102 are connected to the first optical fiber 104, and the focusing probe 102 and the detector 103 are connected to the second optical fiber 105.

By using such optical fibers 104 and 105, there is an advantage that the optical system can be configured relatively simply. The optical fibers 104 and 105 may use both a single mode fiber used to transmit only a single wavelength and a multi mode fiber that can be used to transmit various wavelengths.

In the embodiment of the present invention, a focusing probe 102 is used to focus incident light from the light source 101 into the sample and to focus and transmit scattered light scattered from the sample by the input of the incident light. As shown in FIG. 2, the focusing probe 102 according to the embodiment of the present invention is connected to the first connection portion 201 and the detector 103 to which the optical fiber 104 connected to the light source 101 is connected. And a second connection portion 202 to which the optical fiber 105 is connected. At this time, the focusing probe 102 is transmitted through the first lens 204 and the first lens 204 for refracting and passing the incident light input from the connecting portion 201 connected to the first optical fiber 104. Scattered light transmitted through the second lens 206 and the second lens 206 for focusing the incident light into the sample mounted on the sample holder 106 and refracting the scattered scattered light through the incident light introduced into the sample. Is disposed between the third lens 205 and the first and third lenses 204 and 205 and the second lens 206 to focus the light into the connection portion 202 to which the second optical fiber 105 is connected. The incident light passing through the first lens 204 is transmitted without refraction to the second lens 206, and the scattered light passing through the second lens 206 is reflected to the third lens 205. It contains a prism to transmit.

Therefore, incident light propagated through the optical fiber 104 connected to the first connecting portion 201 is refracted by the first lens 204 to become parallel light, and then passes through the prism 207 and is focused through the second lens 206. After that, the sample holder 106 is put in the sample. At this time, an opening 203 is opened between the second lens 206 and the prism 207 so that the incident light passing through the prism 207 is transmitted to the second lens 206 without being emitted to the outside. Can be.

At this time, the prism 207 passes the parallel light passing through the first lens 204 without refraction as it is and transmits it to the second lens 206.

In this case, a band pass filter 210 may be disposed between the first lens 204 and the prism 207 so that light of another component is not transmitted to the sample through incident light passing through the first lens 204.

As such, the scattered light scattered by the Raman phenomenon is generated in the specimen into which incident light is input. In this case, the scattered light may include both Stokes scattering in which a negative shift of the main intensity peak wavelength is generated or anti-Stokes scattering in which a positive shift occurs, compared to incident light.

Samples to be analyzed can be produced by using prototypes of fruits, vegetables, and other agricultural products, or by cutting part of the surface. Alternatively, the surface portion of the solid agricultural product may be separated and analyzed in a powder form, or the liquid squeezed by pressing the sample may be used as a sample.

Such a sample is mounted in the sample holder 106, one end of the sample holder may be provided with a portion on which the focusing probe 102 can be mounted.

The sample holder 106 is composed of a portion for mounting the focusing probe 102 and a sample mounting portion for placing a sample. The sample mounting part may be configured to have a dark room shielded from being incident from the light source other than the incident light from the light source 101 from the outside. In addition, the portion on which the focusing probe 102 is mounted has an open area for allowing incident light from the focusing probe 102 to be injected into the sample or scattered light from the sample to be injected into the focusing probe 102.

Therefore, according to the present invention, paprika, which is collected for analysis, as an example, paprika or the like, may be immediately mounted to a sample mounting unit without special processing, or a portion of the cut portion may be cut and mounted on the sample mounting unit to perform analysis. It is possible to detect chemicals remaining on the surface of the back, for example, pesticides.

In some cases, only the surface portion of the collected paprika is separately separated and manufactured in the same manner, but the size of the sample mounting part may be adjusted according to the size of the sample.

 When the sample is a liquid squeezed after separating only the surface portion of the collected paprika separately, the sample mounting part may be designed to include an area into which a glass container containing such a liquid sample may be inserted.

Scattered light generated from the sample is refracted while passing through the second lens 206 to be parallel light, and is then introduced into the prism 207. At this time, the prism 207 reflects the scattered light passing through the second lens 206 and transmits it to the third lens 205.

Accordingly, the prism 207 according to the embodiment of the present invention is disposed between the first and third lenses 204 and 205 and the second lens 206 to pass the incident light passing through the first lens 204. The light is passed through the second lens 206 without refraction, and the scattered light passing through the second lens 206 is reflected and transmitted to the third lens 205.

The prism 207 may be formed by combining one or more prisms. As a first embodiment of such a prism, the prism 207 may be composed of a first prism 207a and a second prism 207b, as shown in FIG. 2.

The first and second prisms 207a and 207b may have a right triangle in cross section perpendicular to the advancing direction of incident light or scattered light. Such a right triangle may be an isosceles right triangle having the same length of two sides. In addition, the first and second prisms 207a and 207b have the same refractive index.

The incident light from the light source 101 is refracted through the first lens 204 into the first prism 207a and is introduced into the parallel light state. In this case, one of the one surface of the first prism 207a may be disposed to be perpendicular to the parallel light in order to maintain the injected parallel light as it is.

The second prism 207b has a first surface 208 in contact with the first prism 207a, where the first and second prisms 207a and 207b have the same refractive index, so they pass through the first prism 207a. One parallel light is injected into the second prism 207b without refraction at the first surface 208. One side of the second prism 207b toward the second lens 206 is disposed perpendicular to the incident light so that the incident light introduced into the second prism 207b passes in parallel light.

On the other hand, the scattered light from the sample is refracted while passing through the second lens 206 to become parallel light and then injected into the second prism 207b. In this case, the parallel light from the second lens 206 may be input at a predetermined angle, for example, 45 degrees with the first surface 208 of the second prism 207b. At this time, the predetermined angle formed by the first surface 208 and the scattered light to be input is set such that the predetermined angle is larger than the total reflection critical angle of the second prism 2907b. Therefore, the scattered light applied to the first surface 208 is totally reflected. The totally reflected scattered light is injected into the second surface 209 of the second prism 207b. In this case, the second surface 209 may also form a predetermined angle with the scattered light input from the second prism 207b, and the predetermined angle is set to be larger than the total reflection critical angle of the second prism 207b. Therefore, the scattered light introduced from the first prism 207a is totally reflected by the second surface 209 to be injected into the third lens 205. At this time, the angle formed by the scattered light passing through the first surface 208 and the second lens 206 of the second prism 207b and the angle formed by the scattered light reflected from the third surface 209 and the first surface 208. Each can be set independently of each other in a range larger than the total reflection threshold angle, and of course can be set identically to each other.

At this time, in the region where the first prism 207a and the second prism 207b are in contact with each other, the scattered light passing through the second lens 206 is not introduced into the first prism 207a without being totally reflected. Since the area where the first prism 207a and the second prism 207b come into contact with each other can be made as small as possible, the loss efficiency of scattered light can be reduced.

In this case, the surface of each of the first to second prisms 207a and 207b may be coated with an antireflective multilayer to change the refractive index step by step from the refractive index of the air to the refractive index of the prism in order to reduce the loss caused by the reflection of incident light on the surface. .

3 shows a second embodiment of a prism 207. As shown in Fig. 3, the prism 207 of the second embodiment is the same as the prism 207 of the first embodiment and the first prism 207a, but the second prism 207b of the first embodiment has the above-described first prism. The third prism 301 having the surface 208 and the fourth prism 302 having one surface in contact with the third prism 301 and having the third surface 209 described above may be configured. In this case, the third and fourth prisms 301 and 302 may have the same refractive index, and in this case, the scattered light reflected from the first surface 208 of the third prism 301 may cause the third and fourth prisms 301, 302 may pass through the interface formed in contact with each other without refraction. Therefore, the scattered light injected from the second prism 301 into the third prism 302 without refraction may be reflected from the second surface 209 and introduced into the third lens 205.

These third and fourth prisms 301 and 302 also have an isosceles triangular cross-sectional structure similar to that of the second prism 207b and may be coated with an antireflective multilayer and have a first side 208 of the third prism 301. ) And the angle formed by the scattered light passing through the second lens 206 and the scattered light reflected from the third surface 209 and the first surface 208 in the same manner as the second prism 207b described above. Can be set.

In this way, the scattered light introduced into the third lens 205 is focused in the third lens 205 and proceeds along the optical fiber 105 connected through the second connection part 202 and is injected into the detector 103. At this time, the scattered light passing through the prism 207 may be mixed with some Raman scattered light of the incident light input to the sample, so that only the Raman scattered light is transmitted to the third lens 205 to the prism 207 and the third lens. A band pass filter 211 may be disposed between the 205.

The detector 103 is a device for generating a signal indicating the spectral intensity of a specific wavelength band by spectroscopy of the scattered light transmitted from the focusing probe 102 and receives the scattered light so as to be dispersed in different directions according to the wavelength. ) And a detection element 103b measuring the scattered wavelength and converting the wavelength into a spectrum intensity signal.

As the dispersing element 103a, a prism, a diffraction grating, or the like is used as a device for admitting the incident light in different directions depending on its constituent wavelengths.

In the case where various wavelengths are dispersed from the dispersion element 103a, a multi-channel detector such as a photo diode array (PDA) or a charge coupled device (CCD) is used as the detection element 103b, respectively. All data points with different energies must be acquired at the same time. Multi-channel detectors can not only obtain the multi-wavelength data scattered from the diffraction grating, but also measure and quantify the multi-components with different patterns at each wavelength at the same time. Not only is it simple, it also has excellent wavelength reproducibility. Charge-coupled devices are more effective at converting less charge into a current than photodiode arrays, and have excellent sensitivity but low saturation limits for photons. On the other hand, the photodiode array has a merit that the saturation limit is higher than that of the charge coupling device in terms of sensitivity but lower than that of the charge coupling device. Therefore, according to such a sample, it is possible to select and use a suitable one of the two elements described above.

Hereinafter, a Raman spectrometer manufactured according to an embodiment of the present invention and a detection result of the pesticide remaining on the surface of vegetables using the same. The vegetable selected as a sample was paprika, and Table 1 shows the chemicals and types of samples to be detected as pesticides remaining on the surface of the paprika.

Material name Chemical formula shape Bensultap C ₁₇ H ₂₁ NO ₄ S ₄ powder Carbendazaim C ₉ H ₉ N ₃ O ₂ Powder, solution Carbofuran C ₁₂ H ₁₅ NO ₃ Powder, solution Chlorpyrifos C ₉ H ₁₁ Cl ₃ NO ₃ PS Powder, solution Diazinon C ₁₂ H ₂₁ N ₂ O ₃ PS Powder, solution Flufenoxuron C ₂₁ H ₁₁ ClF ₆ N ₂ O ₃ Powder, solution Kresoxim-methyl C ₁₈ H ₁₉ NO ₄ Powder, solution Metalaxyl C ₁₈ H ₂₁ NO ₄ Powder, solution Pencycuron C ₁₉ H ₂₁ ClN ₂ O Powder, solution Procymidone C ₁₃ H ₁₁ Cl ₂ NO ₂ Powder, solution Tolclofos-methyl C ₉ H ₁₁ Cl ₂ O ₃ PS Powder, solution Triophanate C7H7N3 Powder, solution

The wavelength of the laser light source used two types, 532 nm and 785 nm. Irradiation of the output voltage condition was performed for both wavelengths. As an example, an output voltage condition of 534 nm wavelength is illustrated in FIG. 4. As shown in FIG. 4, the output of the laser of 532 nm can reach a maximum output of 350 kW according to the applied voltage.

In addition, since the optical fiber uses two types of lasers, 532 and 785 nm, a multimode fiber is used. The optical fiber used has an inner diameter and an outer diameter of 100 µm and 140 µm, respectively, and the loss of the laser transmission can be transmitted from 35% to 16% in kilometer (km), which is in meters (m). It can be seen that about 99.85 to 99.8% of the laser transmits. In this embodiment, an optical fiber of 1 m was used, and therefore, it is judged that there is almost no light loss.

The focal length of the lens introduced into the sample from the second lens of the focusing probe was determined to be 6 mm with the best optical efficiency. Among the Raman scattering phenomena generated by the incident laser, two prisms were passed through a lens having a focal length of 6 mm so as to focus the laser on the Raman scattered light generated from the sample.

Pesticides used in paprika were purchased in two forms, solid and liquid, to perform Raman spectroscopy experiments. The solid samples are all in powder form, and the liquid samples are dissolved in different solvents depending on the samples. Pesticides in the testing of solid samples require a lot of ambient handling, so sample holders are designed and fabricated to use as few samples as possible and to obtain Raman spectra for the same amount for all samples. The inside of the sample holder is provided with a groove-shaped sample mounting portion having a predetermined depth, and a certain amount of powder sample is inserted into the sample mounting portion and placed at the bottom of the portion where the focusing probe can be mounted. Made by pushing from the outside to fit. The upper part of the sample holder is equipped with the above-mentioned focusing probe, and it is designed so that the focal length of the focusing probe and the powder sample surface are exactly matched. In addition, the sample support on which the sample was placed made grooves 2, 5 and 10 mm deep so that a small amount of sample could be measured. As a liquid sample, a transparent glass bottle made of glass (Agilent, capacity 1.5 ml) was used. And the amount of liquid used for the measurement was about 0.8-1.0 ml.

On the other hand, as a spectroscopic element of the present embodiment, a Czerny-Tuner type diffraction grating was used, and the condensing distance was 85 mm. A single monochromator was used and a charge-coupled device with 1340 × 100 pixels was used as the detection device. The scan ranges of scattered light were 60 nm-3100 nm and 200 nm-3100 nm.

In the test using the present embodiment, the wavelength was detected while changing the laser power, data integration time, and gain of the detector. The laser power was 350 ㎽ at zero and the acquisition time was 0.001. From seconds to detector saturation limit, the gain of the detector varied from 1 to 3. Among these variables, the Raman spectrometer to be applied to detect residual pesticides requires the highest output under conditions that do not damage paprika, the data acquisition time should be short for field application, and the gain of detector The higher the, the worse the signal / noise ratio, so try to keep the gain as low as possible.

 In the case of the powdered pesticide in the test using the present example, when the data acquisition time is 1 second and the gain of the detector is 1, the Raman spectroscopy that can distinguish the background and peak can be obtained from the laser output of 20 mW. The Raman spectroscopy spectra of FIGS. 5 to 8 are the results obtained by measuring the data acquisition time at 1 second, the gain of the detector at 1, and the laser power at 45 Hz.

5 (a) to 5 (f) and 6 (a) to 6 (f) show the Raman spectroscopic spectra obtained with a laser of 785 nm for the paprika pesticides selected in Table 1. The spectral results of FIGS. 5 (a) to 5 (f) are Bensultap, Tolclofos-methyl, Flufenoxuron, Kresoxim-methyl, Metalaxyl and Pencycuron, and the spectral results of FIGS. 6 (a) to 6 (f) are sequentially Procymidone. , Triophanate, Chlorpyrifos, Carbofuran, Carbendazaim, and Diazinon.

The spectra shown in Figs. 5 (a) to 5 (f) and 6 (a) to 6 (f) are the results of a laser having a wavelength of 785 nm, when the Raman spectroscopy experiment was performed. The Raman spectroscopy spectra obtained showed a better signal / noise ratio than the one obtained using a 532 nm laser. This is due to the fact that most of the pesticides consist of light elements on the periodic table, for example carbon (C), hydrogen (H), oxygen (O), nitrogen (N) and chlorine (Cl). Compared with heavy elements such as (Pb) and tungsten (W), it is considered that it is easy to be excited from the ground state to the excited state. The fact that a substance can absorb external energy well indicates that it can be easily excited from the ground state to the excited state, and once excited, the atoms are excited to fall back to the ground state after a certain period of time. The difference in energy is emitted to the outside in any form. One form of this energy emission is fluorescence, which, as in the results of this example, is that pesticides composed of light elements generate more fluorescence for 532 nm with fluorescence than 785 nm. For this reason, when the Raman spectrum is obtained using a laser of 532 nm having a higher energy than 785 nm, the background becomes high, making it difficult to distinguish the Raman peak from the background. In addition, some of the Raman spectra measured using a 785 nm laser have a high background due to the above-mentioned fluorescence effect. Therefore, based on the results of this experiment, the laser is one of the components of the Raman spectroscopy system used to detect pesticides. If the long wavelength laser is used, the laser can suppress the fluorescence effect from the pesticide to be measured. The ratio indicates that a better Raman spectrum can be obtained.

On the other hand, in order to observe the change in the molecular structure of paprika over time, paprika was washed with distilled water four times, and then a portion of the paprika was cut and used as a sample for measurement. After the measurement, the sample was placed in a plastic container and stored in a refrigerator to prevent rapid reduction of contamination and moisture due to contact with outside air.

Figure 7 shows the Raman spectroscopy spectrum of paprika with the change of time (1 day, 3 days, 10 days, 15 days). Raman spectrum of the paprika has showed a Raman peak intensity is large at 1008.31 ㎝ ^-1, 1157.41 ㎝ ^-1 and 1520.96㎝ ^-1, most of the Raman peaks 2000 ㎝ ^- appear in the ^first or less. As shown in FIG. 5, the molecular structure of paprika is changed from day 1 to 3 but the paprika molecular structure is maintained as it is, but as time passes, molecules that are bound to the main skeleton due to the release of moisture from paprika are gradually released. as the Raman peak intensity of 1008.31 ㎝ ^-1, 1157.41 ㎝ ^-1 1520.96㎝ and ^-1 it can be seen that there is low as compared with the first. And after 10 days it is changed to a molecular structure other than paprika's molecular structure.

FIG. 8 normalizes the other peaks based on the Raman spectroscopy peak representing the maximum intensity in each Raman spectroscopy to compare both the paprika and the Raman spectroscopy spectra for the pesticides measured in this study. Spectral results are from below for sample holder, Triophante, Procymidone, Pencyncuron, Kresoxim, Tolclofos, Bensultap and paprika.

Raman spectrum of the pesticides unlike the spectrum of paprika showing a large strength at 1008.31 ㎝ ^-1, 1157.41 ㎝ ^-1 and ^-1 1520.96㎝ as seen by comparing the Raman spectrum of the pesticides Paprika is a large Raman spectral peaks than the paprika spectrum It is showing. Thus, Raman spectroscopy may be effective in distinguishing paprika from pesticides.

The above-mentioned embodiments are illustrative rather than limiting on the present invention, and those skilled in the art can design many other embodiments without departing from the scope of the present invention as defined by the appended claims. In addition, it is obvious that the technology of the present invention can be easily modified by those skilled in the art. As an example, the Raman spectrometer manufactured by the technical idea of the present invention is a chemical substance present on the surface of vegetables, fruits, and other materials. Can also be used for detection. Such modified embodiments should be included in the technical spirit described in the claims of the present invention.

1 is a schematic diagram of a Raman spectrometer according to an embodiment of the present invention.

2 is a schematic diagram of a focusing probe according to an embodiment of the present invention.

3 is a schematic diagram of a prism according to another embodiment of the present invention.

4 illustrates a change in laser output according to an applied voltage of a light source of the present invention.

5 (a) to 5 (f) and 6 (a) to 6 (f) show the Raman spectroscopy spectra of a chemical obtained by a Raman spectrometer according to an embodiment of the present invention.

Figure 7 shows the Raman spectroscopy spectrum of paprika obtained by a Raman spectrometer according to an embodiment of the present invention.

8 illustrates Raman spectroscopy spectra of paprika and chemicals obtained by a Raman spectrometer according to an embodiment of the present invention.

<Brief description of the major symbols in the drawings>

100 Raman spectroscopy 101 light source

102 connection probe 103 detector

103a: dispersion element 103b: detection element

104, 105: optical fiber 106: sample holder

Claims (14)

A light source for generating incident light A detector for receiving scattered light from a sample into which the incident light is input and generating a signal representing a spectral intensity of a specific wavelength band; And a focusing probe for focusing the incident light into the sample and focusing the scattered light and transmitting the scattered light to the detector. The Raman spectrometer of claim 1, further comprising a first optical fiber connecting the light source and the focusing probe and a second optical fiber connecting the focusing probe and the detector. The method of claim 2, wherein the focusing probe A first lens for refracting and passing the incident light introduced from the connection portion connected to the first optical fiber; A second lens for focusing the incident light transmitted through the first lens and injecting the light into the sample and refracting the scattered light scattered by the incident light introduced into the sample; A third lens which focuses the scattered light transmitted through the second lens and inputs it to a connection portion to which the second optical fiber is connected; Disposed between the first and third lenses and the second lens, the incident light passing through the first lens is transmitted without refraction to the second lens, and the scattered light passing through the second lens is reflected to the Raman spectrometer comprising a prism for transmitting to the third lens. 4. The Raman spectrometer of claim 3, wherein an optical filter is further disposed between the first lens and the prism or between the third lens and the prism. The method of claim 3, wherein the prism is A first prism through which incident light passing through the first lens passes without refraction; As the first prism contact surface, the incident light passing through the first prism is allowed to pass without refraction, and the first surface reflects the scattered light passing through the second lens and the scattered light reflected from the first surface to reflect the third light. Raman spectrometer comprising a second prism having a second surface to transmit to the lens. 6. The Raman spectrometer of claim 5, wherein the first and second prisms have the same refractive index. 6. The Raman spectrometer of claim 5, wherein the surfaces of the first and second prisms have an antireflective multilayer coating in which the refractive index is gradually changed. 7. The method of claim 6, wherein the angle formed by the scattered light passing through the first surface and the second lens or the scattered light reflected from the third surface and the first surface is more than the total reflection critical angle of the second prism. Raman spectrometer set large. 9. The method of claim 5, wherein the second prism comprises a third prism having the first surface and a fourth prism having one surface in contact with the third prism and having the third surface. Raman spectroscopy included. The Raman spectroscopy method which detects the chemical substance which remains on the surface of the said sample using the Raman spectroscopy of any one of Claims 1-8. The method according to claim 10, wherein the sample is a Raman spectroscopy method produced by cutting a region including a circular portion of the produce or the surface portion of the produce. The Raman spectroscopy method according to claim 10, wherein the sample is a powder produced by separating the surface portion of the agricultural product, or a liquid squeezed after separating the surface portion. Raman spectroscopic analysis of claim 11 or 12, wherein the produce comprises paprika. The Raman spectroscopy of claim 10 wherein the chemical is any one of Bensultap, Tolclofos-methyl, Flufenoxuron, Kresoxim-methyl, Metalaxyl, Pencycuron, Procymidone, Triophanate, Chlorpyrifos, Carbofuran, Carbendazaim, and Diazinon

Images