JPH0817391A - Mass spectrum analysis - Google Patents

Abstract

PURPOSE:To estimate and identify the elemental compositions of mass spectra obtained by a mass spectrometer, by way of the simulation of isotope spectra and structural determination on the elemental composition. CONSTITUTION:The mass numbers, isotopes, and valences of elements are stored as data 1, and some data are captured into a computing part 2 as necessary. Measured values 4 consist of the mass numbers and peak strengths of mass spectra, and the mass numbers are used in the extraction of elemental compositions and the peak intensity in the evaluation of the similarity between isotope spectra. At the computing part 2, the result of simulation is checked with the measured values, and combinations of elements are arranged in the order of decreasing similarities. During this process, the degree of unsaturation is calculated as to the combinations of elements using the kinds, numbers and valences of the elements, and those which are irrational in terms of chemical structure are excluded based on the calculation. These computation results are displayed on output 3 as a numeric representation or a graph. When the output result shows that comparisons of the calculated and measured values of a single isotope spectrum and a plurality of isotope spectra, are superimposed, analysis is performed using synthesis, or sequential simulation, method.

Description

Detailed Description of the Invention

[0001]

The present invention relates to a mass spectrum analysis method,
In particular, the present invention relates to a mass spectrum analysis method suitable for analyzing a mass spectrum in which the type of element cannot always be specified.

[0002]

2. Description of the Related Art Mass spectrum analysis and quantitative analysis based on isotope ratios of elements have been widely used since the beginning of the spread of mass spectrometers. After that, as the measurement target has become higher in molecular weight, accurate mass measurement, that is, the millimass method has become the mainstream of the elemental composition identification method. This is done by using a large-scale device with high mass resolution to measure a minute mass difference between ions having the same mass number but different elemental compositions due to the mass deficiency effect of the element, and physically measuring it. This is a method of determining the elemental composition of ions.

Recently, a data search method has been widely used as a means for identifying a substance by a low-resolution mass spectrum. The standard data of 100,000 or more is compared with the mass spectrum obtained by the measurement, and the one with the highest degree of agreement is associated with the measurement sample. However, this method is difficult to apply to mixed substances or to mass spectra generated under special conditions.
Also, this method cannot identify the elemental composition of any peak in the mass spectrum.

Relatively recently, again, a technique relating to spectrum analysis using isotope ratios has been disclosed (Japanese Patent Laid-Open Publication No. (A) Sho 61-20855). The content is related to the method of displaying the analysis result regarding the isotope spectrum, and the millimass method is used as a means for narrowing down the possibility of composition elements.

As the mass spectrometer is applied to the industrial field, a quadrupole mass spectrometer, which is structurally small and simple, has been widely used. Although these kinds of devices are not suitable for strict measurement, the mass spectra provided by these devices have been required to have similar results according to the millimass method.

[0006]

The situation concerning the simulation of isotope spectra using the isotope ratio of elements will be described here. As the types and number of elements that make up a substance increase, it becomes more and more difficult to find a combination of elements that embody a designated mass number and calculate the isotope spectrum generation ratio. Further, the difference in the pattern coefficient between the isotope spectra caused by the substitution of the elemental species or the isotope may fall within the range of the measurement error of the mass spectrometer, and detection itself may become impossible. In addition, when isotope spectra having different elemental compositions are superposed, it is extremely difficult to identify them. In the past, these became technically great obstacles, and the analysis method of the spectrum depending on the spectrum intensity could not sufficiently exhibit its function.

The object of the present invention is to estimate or identify the elemental composition by analyzing even a mass spectrum obtained using a convenient device such as a quadrupole mass spectrometer with a relatively low resolution. It is to provide a mass spectrum analysis method capable of performing the same.

[0008]

The object of the present invention is achieved by the following means for solving problems.

1. A mass spectrometric method, which comprises the following steps.

(A) In the actually measured mass spectrum, the isotope spectrum containing the peak to be analyzed is the reference peak whose intensity is maximum or relatively strong.
(B) selecting an element considered to be involved in the isotope spectrum, and using the isotope having the largest isotope ratio among the isotopes of the selected element. Extracting a combination of elements corresponding to the reference peak, (c) calculating the production ratio of the isotope spectrum of the extracted combination of elements, and (d) the calculated production ratio. Comparing the measured value of the intensity of the isotope spectrum to obtain the similarity.

2. In the mass spectrum analysis method according to Solution 1, the combination of elements corresponding to the reference peak extracted in step (b) is a combination of elements satisfying the reference peak in terms of mass number. It is characterized by

3. The mass spectrum analysis method according to Solution 1, characterized in that the number of unsaturated bonds is obtained for the combination of elements extracted in step (b), and the abnormal combination of elements is excluded based on the result. To do.

4. The mass spectrum analysis method according to Solution 1, wherein the selection of the isotope spectrum in step (a) is performed by designating the mass number range of the spectrum.

5. The mass spectrum analysis method according to Solution 1, wherein the calculation of the production ratio of the isotope spectrum in step (c) is not performed for a combination of isotopes having an intensity equal to or less than a predetermined value.

6. The mass spectrum analysis method according to Solution 1, wherein the peak to be analyzed is the reference peak.

[0016]

In Solution 1, the combination of elements corresponding to the reference peak is extracted using the isotope having the largest isotope ratio among the isotopes of the elements considered to be involved in the selected isotope spectrum. Then, the production ratio of the isotope spectrum of the combination is calculated, and the similarity is calculated based on the comparison between the production ratio and the measured value of the intensity of the isotope spectrum. According to this, even with a mass spectrum obtained using a convenient device such as a quadrupole mass spectrometer with a relatively low resolution, it is possible to estimate or identify the elemental composition by analyzing this. Therefore, it becomes possible to improve the function of such a convenient device that could not be fully utilized in this direction. In addition, since the isotope spectrum is selected, it is sufficient to perform the analysis within the selected range, and thus the efficiency of the estimation or identification of the elemental composition can be improved.

The solving means 2 to 6 are based on the solving means 1. Therefore, the same results are expected by the solving means 2 to 6.

According to the solving means 5, the calculation of the production ratio of the isotope spectrum is not executed for the combination of isotopes having the intensities equal to or less than the predetermined value, so that the efficiency of the estimation or identification of the elemental composition can be further improved. Be promoted.

[0019]

[Example] Regarding the isotope spectrum observed in the mass spectrum, there is a problem of which range in terms of mass number belongs to the same isotope spectrum. Regarding this point, for example, with regard to some elements excluding organic substances or some elements other than heavy metals, the isotope ratio of the isotope with the smallest mass number is the largest, and the isotope ratio with the smallest mass number is relatively small. In the isotope spectrum, of the isotopes of each of the constituent elements, the peak intensity of the isotope ion having the minimum mass number, which is composed of only the isotope having the smallest mass number, is the maximum or relatively large. Shows a tendency to become. Hereinafter, this peak will be referred to as a reference peak. Therefore, in the observed mass spectrum, a peak whose intensity is higher than that of surrounding peaks can be generally considered to be the reference peak, and the isotope spectrum has a high mass from the reference peak. Disperse to the side.

The estimation or identification of the elemental composition is based on the standard
We will start by extracting the chemically relevant combinations of elements that satisfy the mass number of the black metal. Regarding the selection of elemental species for this purpose, for example, when measuring a reaction product, all elements contained in the reaction system are treated. Then, for each element, specify one each isotope with the highest isotope ratio, change the number of each element within the range considered to be reasonable as estimated from the mass number of the reference peak, and change the mass number. Addition processing is performed to extract those that match the mass number of the reference peak. In this process, the rationally unreasonable ones are excluded. In this way, all possible combinations of elements can be obtained without overlooking by a simple method. This process is equivalent to selecting one of the isotopes having the smallest mass number for organic compounds or compounds excluding some heavy metals.

When the combination of elements is extracted, the production ratio of each isotope spectrum is calculated. The calculation method itself is based on the conventionally used method.

Next, the isotope spectrum obtained by the measurement is compared with the calculation result. First, the calculated value is standardized by the measured value of the intensity of the reference peak, and it seems necessary or appropriate for the comparison. The sum of peak intensities is separately obtained within the range of the mass number to be determined, and the one having the smallest difference between the two is determined as the one having the best similarity in intensity. The least squares method is generally used for this determination, but the following formula is used for simplicity.

Similarity (DEV) = (sum of measured values-sum of calculated values) / sum of calculated values In the case where no combination of a single element agrees with the measured value, a plurality of elements A so-called spectrum synthesis technique is used in which the isotope spectra for the combination are superposed at an appropriate ratio and this is compared with the measured value. This makes it possible to quantitatively estimate the contribution of ions having different elemental compositions to the same peak. If two isotope spectra with different elemental compositions and mass numbers are present close to each other, first analyze the low mass number side isotope spectrum, and then use the results to analyze the high mass side. The intensity of the isotope spectrum of is corrected and the similar arithmetic processing is sequentially performed to estimate or identify their elemental composition.

The spectrum analysis algorithm is based on two basic concepts. One is the isotope spectrum simulation. This is a method that belongs to the category of pattern recognition. The other is a function that determines whether or not the combination of elements is chemically appropriate, and is a method that belongs to the category of structural analysis. The elemental composition of the spectrum is estimated or identified based on these two processing results.

FIG. 1 shows the flow of arithmetic processing. The mass number, the isotope ratio, and the valence of the element are stored as the data 1, and any data is taken into the arithmetic unit 2 as necessary. The measured value 4 consists of the mass number and the peak intensity of the mass spectrum. The mass number is used when extracting the elemental composition, and the peak intensity is used when evaluating the similarity of the isotope spectrum. In the calculation unit 2, the simulation result is further collated with the measured value, and the combination of elements is arranged in descending order of similarity. At the same time, the degree of unsaturation for the combination of elements is calculated using the type, number and valence of the elements, and based on this, those unreasonable in terms of chemical structure are excluded.
The results of these calculations are displayed at output 3 as a number table and a graph.

Based on the result of the output 3, the calculated value and the measured value of the single isotope spectrum are compared with each other, and in the case where a plurality of isotope spectra are superposed, a synthetic or sequential simulation is performed. Analysis is performed using the method of.

The positioning of the software relating to the present invention in the measurement system is shown in FIG. The test sample 6 is introduced into the mass spectrometer 7, and the mass spectrum is output as off-line data 8 to a hard copy or a floppy disk, or directly into a computer 9.
The test sample 6 may be a gas sample, a sample from a gas chromatograph, a sample from a liquid chromatograph, or a sample from a gas reactor. The software 5 relating to the present invention is used in the computer 9 for processing the data from the mass spectrometer 7. The processing result is displayed on the output 11. The output 11 is used alone for estimating or identifying the elemental composition, and in combination with the millimass method 10, the identification accuracy can be further improved.

The analysis result can be used as a control or monitor of the gas reaction system as shown in FIG.

An embodiment of the mass spectrum analysis method according to the present invention will be described with reference to FIG. First, the sample name is entered (S1) and the processing mode is entered (S1).
2). M is a mode when the kind of element is unknown, F
Represents the mode when the cleavage pattern is known. Then, the intensity of the mass spectrum peak to be processed is input (S4), and the constituent elements, the isotope ratio of each element, and the valence of each element are input (S5). Maximum number of entered elements
If I _MAX is greater than or equal to a predetermined value (for example, 6), input again so that it is less than that. In the case of mode F, the composition of the molecule is entered, and in the case of mode M, the number of carbons to be set is entered (S6). Then, if there is a hydrogen or halogen regulation, the regulation range, that is, the variation range is input (S7). Up to this point, the setting of the analysis target and the analysis condition is completed.

Based on the above input data, focusing on the peak having the maximum isotope ratio, that is, the isotope peak having the minimum mass number, possible combinations of elements are extracted (S).
8). In this case, the number of unsaturated bonds for the combination of elements is obtained using the type, number and valence of the elements, and the abnormal combination of elements is excluded based on this. Also,
When the number of the combinations becomes too large (for example, when the number QMAX is 75 or more), the input in step S5 or S6 is changed again. Then, the production ratio of the isotope spectrum peak of the extracted combination of elements is calculated (S9). In this case, for example, all isotope combinations having a production ratio of 1 / 10,000 or less of the reference peak are excluded from the calculation of the production ratio. After that, the calculated production ratio and the actually measured value of the intensity of the isotope spectrum are compared to obtain the similarity (S10), and the elements are sorted and displayed in descending order of similarity in elemental composition (S11).

In most cases, the analysis peak matches the reference peak, but even if it is not, it is analyzed as one peak in the isotope spectrum having the same elemental composition as the reference peak. It

The displayed elemental composition is copied if necessary, and then the spectrum to be displayed is selected (S12). In this case, S represents a component spectrum and C represents a synthetic spectrum. The component spectrum is a spectrum for each rearranged elemental composition, and the synthetic spectrum is a combination spectrum obtained by changing the synthesis ratio of the components. Then, a display mode is selected to determine whether the spectrum to be displayed is a linear graph (S) or a logarithmic graph (T), and the display is performed (S13). After that, the copy is taken if necessary, and the flow
Ends (S14). In this case, the flow returns to step S12 when the display is changed, to step S2 when the area is changed, and to step S1 when the sample is changed.

Al based on the above mass spectrum analysis method
An example of the analysis result (estimated composition) of lyl salicylate (C ₁₀ H ₁₀ O ₃ ) is shown in FIG. This is obtained by setting the analysis target and conditions as follows.

Sample name: Allyl salicylate Input element: C, H, N, O, S (N and O are added for reference) Range of change of the number of input elements: C-6 to 14 H-3 -36 N-0-4 O-0-6 S-0-3 Mass number change range (m / Z): 178-180 Mass number of standard peak (m / Z): 178 In FIG. 4, QD is The numbers of combinations of elements are shown, and the combinations are shown in order of similarity. Actually 74
, But the 31st and subsequent ones are omitted in the figure. DEV represents the degree of similarity, and the smaller the value, the higher the degree of similarity. In the TYP column, M is an index showing that the combination of elements is possible as a molecular structure, and F is an index showing that it is a basic structure. BC and BR are the number of double bond-equivalent unsaturated bonds existing inside, assuming that the combination of each element is an ion containing one linear structure or one ring structure. There can be no one with a negative value. However, in FIG. 4, those up to -1 with respect to BC are shown in consideration of cluster ions generated by a gas reaction or the like. Further, a combination of elements whose value is significantly larger than the number of carbon atoms may be valenceally possible, but may normally be chemically excluded. In addition, for peaks that are known to be molecular ions in advance, combinations of elements with F described are excluded from candidates even if the degree of similarity is high.

The correct answer for the composition of Allyl salicylate is C ₁₀ H ₁₀ O ₃
Is. On the other hand, in the analysis result according to the example of the present invention, the estimated composition is C = 10, H = 10, N = from the QD number 1 in FIG.
It is 0, O = 3, and S = 0, that is, C ₁₀ H ₁₀ O ₃ , and it can be seen that this is in agreement with the correct answer. Figure 5 is QD number 1 in Figure 4
5 is a graph display example of the spectrum (component spectrum) of FIG.

FIG. 6 is an example schematically showing an example in which a combination of two elements is overlapped. By displaying a mark (horizontal line or triangle mark) showing the composition ratio or a graph with different colors in the middle of the calculated bar graph, the combination of multiple elements can be quantitatively identified and displayed. can do.

[0037]

According to the present invention, even a mass spectrum obtained by using a convenient device such as a quadrupole mass spectrometer having a relatively low resolution is analyzed to estimate the elemental composition or It is possible to identify and thus improve the function of such a convenient device that could not be fully utilized in this direction, and conduct the analysis within the selected isotope spectrum range. Is sufficient, the efficiency of estimation or identification of elemental composition can be improved. In addition, since the calculation of the generation ratio of the isotope spectrum is not executed for the combination of isotopes having the strength equal to or less than the predetermined value, the efficiency of the estimation or the identification of the elemental composition can be further improved. 5).

[Brief description of drawings]

FIG. 1 is a diagram for explaining the concept of a mass spectrum analysis method according to the present invention.

FIG. 2 is a diagram for explaining the positioning of the mass spectrum analysis method of the present invention in the overall measurement system.

FIG. 3 is a flowchart showing an embodiment of a mass spectrum analysis method according to the present invention.

FIG. 4 is a display example of an example of the estimated elemental composition obtained by the present invention.

FIG. 5 is a graph display example of a component spectrum according to the present invention.

FIG. 6 is a graph display example of a synthetic spectrum according to the present invention.

[Explanation of symbols]

1 ... Elemental data, 2 ... Calculation unit, 3 ... Output, 4 ... Mass spectrometer data, 5 ... Mass spectrum analysis software, 6 ... Measured Sample, 7 ... Mass spectrometer, 8 ... Mass spectrometer offline data, 9 ... Calculator, 10 ... Millimas method system, 11 ... Output

Claims (6)

[Claims] 1. A mass spectrum analysis method including the following steps. (A) The isotope spectrum containing the peak to be analyzed in the actually measured mass spectrum should be such that the peak having the maximum intensity or the relatively strong peak is included as the reference peak. (B) selecting an element considered to be involved in the isotope spectrum, and using the isotope having the largest isotope ratio among the isotopes of the selected element, the reference peak. And (c) calculating the production ratio of the isotope spectrum for the extracted combination of elements, and (d) calculating the production ratio of the isotope spectrum and the isotope spectrum. Find the similarity by comparing the measured value of strength. 2. Extracted in step (b),
The mass spectrum analysis method according to claim 1, wherein the combination of elements corresponding to the reference peak is a combination of elements satisfying the reference peak in terms of mass number. 3. The number of unsaturated bonds for the combination of elements extracted in the step (b) is calculated, and the abnormal combination of elements is excluded based on the result. Mass spectral analysis method. 4. The mass spectrum analysis method according to claim 1, wherein the isotope spectrum is selected in the step (a) by designating a mass number range of the spectrum. 5. The method according to claim 1, wherein the calculation of the production ratio of the isotope spectrum in the step (c) is not executed for a combination of isotopes having intensities equal to or less than a predetermined value. Mass spectral analysis. 6. The peak to be analyzed is the reference peak.
The mass spectrum analysis method according to claim 1, wherein