JP5682918B2 - Elemental quantitative analysis method and elemental quantitative analyzer by X-ray absorption edge method - Google Patents

Description

  The present invention relates to an elemental quantitative analysis method for absolute quantification of the surface density, content density, total amount, etc. of each element contained in an object to be measured by the X-ray absorption edge method, and an element capable of performing the quantitative analysis method The present invention relates to another quantitative analyzer.

  Attempts have conventionally been made to measure the density of elements contained from X-ray absorption. However, since X-ray absorption of a certain energy is a combination of absorption by all elements in the transmitting material, in order to measure the density of elements contained from X-ray absorption, it is necessary to know the contained elements. There is. In addition, it is necessary to measure the absolute absorption obtained by subtracting the transmitted X-ray from the incident X-ray, and there is a problem that the measurement apparatus and measurement operation become complicated.

  On the other hand, it is known that the absorption edge jump in the X-ray absorption spectrum has energy inherent to the element, and its magnitude is proportional to the density of the element on the X-ray transmission path. In addition, since the absorption edge jump in the X-ray absorption spectrum is obtained by measuring the transmitted X-ray from the object to be measured, the X-ray transmission path can be measured without measuring the incident X-ray and the absolute absorption. There is an advantage that measurement data on the density of each element can be obtained.

  Attention has been paid to this advantage, and attempts have been made to measure the content of elements by using the jump at the absorption edge (see Patent Document 1), but an X-ray light source including characteristic X-rays is sometimes used. The measurement of the content of known elements has been stopped.

The present inventors studied to quantify the density of each element on the X-ray transmission path using the absorption edge jump in the X-ray absorption spectrum. During the examination process, the “mass absorption edge jump coefficient, C _Δμ (cm ² / g)”, which represents “absorption edge jump per 1 cm of optical path length with the density of element 1 g / cm ³ ”, was obtained. It was found that quantitative analysis for each element on the X-ray transmission path is possible based on the measured value of the absorption edge jump of the measured object whose surface density is unknown.

  The mass absorption edge jump coefficient necessary for quantification for each element can be obtained by measuring the absorption edge jump of a standard sample whose surface density is known. In addition, since the mass absorption edge jump coefficient is empirically known to be a function of the atomic number, an estimated value can be used for an element for which a standard sample cannot be obtained. Such a mass absorption edge jump coefficient needs to be accurately determined, but it is known that there is a fine structure reflecting the oxidation number and local structure of the element near the absorption edge. The inventors have also clarified that the absorption edge jump amount may be determined using an absorption edge jump amount determination algorithm that is not affected by the structure of the absorption edge.

In order to quantify many elements contained using the above-described absorption edge jump, a white continuous X-ray light source capable of measuring the absorption edge jump over the energy range covering all the energy inherent to each element is required. It becomes. However, in a normal X-ray tube, strong characteristic X-rays having a sharp peak from the target appear and saturate the detector, so that it is difficult to measure with high accuracy in a wide energy range. Therefore, the present inventors were able to realize elemental quantitative analysis using absorption edge jump by using radiated light as a white continuous X-ray light source having no characteristic X-rays.
However, in order to use synchrotron radiation, a large-scale device such as a high-energy electron storage ring is required. In various processes in the material manufacturing process, etc., an absorption edge jump is used by a small device. It was impossible to perform quantitative analysis by element flexibly.

Japanese Patent No. 11-287643 JP 2010-56062 A

  The present invention solves the problems existing in the prior art as described above, and uses an absorption edge jump without using a large-scale device such as a synchrotron radiation device (high energy electron storage ring). Provided is an elemental quantitative analysis method capable of absolute quantification of the surface density, average density, total amount, etc. of each element contained in a measurement object, and an elemental quantitative analysis apparatus capable of performing the quantitative analysis method. This is the issue.

  The present inventor can continuously generate continuous X-rays without characteristic X-rays in an energy region of a predetermined value or more without using a large-scale device such as a synchrotron radiation device (high energy electron storage ring) or the like. Invented an X-ray light source. The elemental quantitative analysis by the X-ray absorption edge method of the present invention has become possible with a small apparatus by utilizing such a novel continuous X-ray light source.

The present invention has the following features including the continuous X-ray light source.
(1) A carbon-based cold cathode electron source, made of carbon or silicon carbide as a conductive light element having an atomic number smaller than that of titanium, and electrons emitted from the cold cathode electron source are incident on the incident surface and are incident in the incident direction. In contrast, a target that emits X-rays forward and a shielding member that shields X-rays other than the X-rays generated by the target are provided, and characteristic X-rays in an energy region of a predetermined value or more according to the type of light element The object to be measured can be irradiated with continuous X-rays from a continuous X-ray light source that can irradiate the object to be measured with continuous X-rays with no peaks. Absorption edge jump of each element contained in the X-ray absorption spectrum of an object is obtained, and the mass absorption edge jump is an absorption edge jump per 1 cm of optical path length with a density of 1 g / cm ³ of each element determined in advance by a standard sample. Person in charge The content based on the absorption edge jump of each element, elemental specific quantitative analysis method characterized by determining the surface density of the X-ray trajectory for each element contained in the object to be measured and.
(2) Use a two-dimensional detector arranged on the surface as an energy discrimination type detector, or move each object to be measured in a two-dimensional direction perpendicular to the irradiation X-ray to include each region. The elemental quantitative analysis method according to (1), wherein the density distribution for each element is obtained.
(3) A carbon-based cold cathode electron source, made of carbon or silicon carbide as a conductive light element having an atomic number smaller than that of titanium, and electrons emitted from the cold cathode electron source are incident on the incident surface, In contrast, a target that emits X-rays forward and a shielding member that shields X-rays other than the X-rays generated by the target are provided, and characteristic X-rays in an energy region of a predetermined value or more according to the type of light element A continuous X-ray light source capable of irradiating an object to be measured with continuous X-rays having no peak, an energy discrimination type detector for detecting the X-ray intensity of the X-ray transmitted through the object to be measured, and an energy discrimination type detection with obtaining the absorption edge jump of containing each element in the X-ray absorption spectrum of the object to be measured based on the detection value of the vessel, previously the optical path length per 1cm of the density of the element by element 1 g / cm ³ as determined by the standard sample and the like An analyzer that obtains the surface density on the X-ray transmission path for each element contained in the object to be measured based on the mass absorption edge jump coefficient, which is an absorption edge jump, and the absorption edge jump amount of each element. Quantitative analyzer for each element.
(4) The elemental quantitative analysis apparatus according to (3), further comprising a crystal spectroscope that divides X-rays from a continuous X-ray light source and irradiates a non-measurement object with the spectral X-rays.
(5) The elemental quantitative analysis apparatus according to (3), wherein the target is plate-shaped and emits X-rays from a surface opposite to an electron incident surface.
(6) The elemental quantitative analysis apparatus according to (3), wherein the target is configured to make electrons incident on the incident surface at an angle of 45 degrees or less.
(7) The elemental classification according to any one of (3) to (6) above, wherein a two-dimensional detector arranged on the surface is used as the energy discrimination type detector, and the analyzer obtains the density distribution for each contained element. Quantitative analyzer.
(8) Any of the above (3) to (6), further comprising a measured object driving means for moving the measured object in a two-dimensional direction perpendicular to the irradiation X-ray, wherein the analyzer obtains the density distribution for each contained element. The elemental quantitative analysis apparatus according to item 1.

When trying to quantify contained elements using the mass absorption coefficient as in the prior art, all contained elements need to be known and absolute absorption must be measured. In the quantitative analysis using the end jump, it is not necessary to know the contained elements in advance and it is not necessary to measure the absolute absorption, so that the measuring device and the measuring operation are not complicated. Moreover, since a large-scale device such as a high-energy electron storage ring is not used, the entire analyzer can be miniaturized.
In the present invention, a continuous X-ray light source that generates X-rays of a continuous X-ray spectrum having no characteristic X-ray peak in an energy region of a predetermined value or more according to the type of light element selected as a target is used. The absorption edge of all contained elements with a large atomic number of (in the atmosphere, elements heavier than Ti, or elements with an atomic number larger than the element used for the target when the optical path is replaced with helium or vacuum) By measuring the jump amount at the observed position, the content rate and absolute amount of all the contained elements can be easily quantified.
When the target element is dilute, the absorption spectrum of only the target element is obtained by measuring the base material of the measured object that does not contain the target element instead of the X-ray light source intensity under the same conditions as the light source intensity. And the sensitivity of the target element can be improved.

The schematic diagram which shows the elemental quantitative analysis apparatus of this invention. The figure which shows the light source spectrum of the continuous X-ray obtained by the continuous X-ray light source of this invention. The figure which shows the spectrum after copper foil permeation | transmission of a continuous X ray. Drawing which shows the absorption spectrum of copper foil. Drawing explaining the subtraction method of background absorption. The figure explaining the determination method of the absorption edge jump amount. Of certified reference material (CRM8116-a) (thickness 2mm, one piece) of metal (Cr925 ± 30mg / kg, Hg928 ± 38mg / kg, Pb926 ± 24mg / kg, Cd92.1 ± 4.9mg / kg) in resin Drawing which shows a measurement example. Drawing which shows the spectrum of the Cr K absorption edge (5989eV) vicinity of the CRM8116-a. The figure which shows the spectrum of L absorption edge vicinity of Hg (L3 12278eV L2 14122eV L1 14843eV) and Pb (L3 13030eV L2 15203eV L1 15864eV) of same CRM8116-a. The schematic diagram which shows another Example (what comprises a crystal spectrometer) of the quantitative analysis apparatus according to element of this invention.

  The elemental quantitative analysis by the X-ray absorption edge method of the present invention is based on the mass absorption edge jump coefficient and the measurement value of the absorption edge jump of the object to be measured. The basis for this is as described below.

  In the present invention, a continuous X-ray light source that generates X-rays of a continuous X-ray spectrum having no characteristic X-ray peak in an energy region of a predetermined value or more according to the type of light element selected as a target is used. Therefore, since the light source spectrum is a gentle curve in the energy region above the predetermined value, all elements larger than the predetermined atomic number of the object to be measured (heavy elements over Ti in the atmosphere, the optical path is replaced with helium or vacuum) In this case, the absorption edge can be clearly observed in the X-ray spectrum transmitted through the object to be measured for the element having an atomic number larger than that of the element used for the target. There is a fine structure in the vicinity of the absorption edge that reflects the oxidation number and coordination structure of the element. By using a low-resolution energy discrimination detector, however, no fine structure is observed and the net absorption edge is consequently observed. A jump is observed. However, since the apparent absorption edge jump may be reduced due to low resolution, the net absorption edge jump can be obtained by using the absorption edge jump amount determination method described below. Even when a high-resolution detector is used, a net absorption edge jump that eliminates the influence of the fine structure can be obtained by using the absorption edge jump amount determination method described below.

The absorption edge jump is proportional to the number of atoms on the X-ray optical path of the absorbing element and follows the Lambert-Beer rule. The excitation probability (absorption edge jump) of a specific inner-shell electron of a net isolated atom excluding the influence of the fine structure near the absorption edge is proportional to the number of atoms on the optical path, and the optical path length with the density of element 1g / cm ³ When the absorption edge jump per 1 cm is the mass absorption edge jump coefficient, C _Δμ (cm ² / g), the following equation (1) holds.
Δμ = C _Δμ Dl (1)
(Δμ is the measured absorption edge jump amount, D is the element density (g / cm ³ ), l is the optical path length (cm))

Therefore, if the mass absorption edge jump coefficient is used, the surface density (Dl (g / cm ² )) of the element can be obtained from the absorption edge jump amount by the following equation (2).
Dl = Δμ / C _Δμ (2)
If l (cm) of the object to be measured is known, the density D (g / cm ³ ) can be obtained, and if the area is known, the total amount (g) can be obtained.

  The mass absorption edge jump coefficient is described below for (A) a method for obtaining a standard solution of each element as a measurement object using synchrotron radiation, and (B) a method for estimating based on an empirical formula for each element of the present invention. Although it can be obtained using a quantitative analyzer, it is usually within 10% of any error, and within 20% even if the measurement conditions are poor, such as 0.1 wt% or less. This error can be applied to the quantitative analysis of the present invention.

(A) Method for obtaining a standard solution of each element as a measurement object using synchrotron radiation The present inventors have so far used a precision cell using synchrotron radiation, and a mass absorption edge jump by a standard solution of each element. The coefficient has been determined. The determination procedure is as follows.
In the absorption spectrum showing the absorption edge jump, in order to remove the influence of the fine structure near the absorption edge, as shown in FIG. 5, the portion on the lower energy side from the absorption edge is optimally obtained by adding the constant term to the Victoreen equation (3) The constant term A is determined by conversion.
In the absorption spectrum showing the absorption edge jump, this equation (3) is extrapolated to be background absorption. At this time, the difference in slope between 1000 and 1500 eV on the high energy side of the absorption edge is made equal to the difference in slope of the Victreen coefficient corresponding to before and after the absorption edge. After subtracting the background absorption, the part on the higher energy side from the absorption edge is smoothed by the partitioned Cubic Spline method, etc., and an absorption curve corresponding to the absorption of the isolated atom is obtained by removing the influence of the structure near the absorption edge. The inflection point or half-value energy of the absorption edge jump is defined as the absorption edge, and the value obtained by extrapolating the absorption curve of the isolated atom at that position is obtained as the absorption edge jump amount (Δμ). From Δμ, the concentration of the standard solution (g / cm ³ ), and the optical path length l (cm) of the cell, the mass absorption edge jump coefficient C _Δμ (cm ² / g) is obtained by Equation (1).
Tables 1 and 2 show values of the mass absorption edge jump coefficient C _Δμ obtained by the inventor for various elements by this method.

(B) Method of estimation based on empirical formula As a result of fitting the mass absorption edge jump coefficient of the K absorption edge with the power function to the value of the mass absorption edge jump coefficient obtained by the above method (A), the atomic number (Z ) To C _Δμ = exp (18.10-3.702 ln Z) (in the range of Z = 29-78). A similar relationship is obtained for the L absorption edge.
Based on this empirical formula, the mass absorption edge jump coefficient can be estimated from the atomic number even for an element for which a standard solution cannot be obtained.

  Comparing the mass absorption edge jump coefficient estimated based on the empirical formula of (B) above and the mass absorption edge jump coefficient obtained based on the mass absorption coefficient obtained from the theoretical calculation of Victoreen, Henke, McMaster, etc. Since both are relatively well matched with an error within 10%, the mass absorption end jump coefficient obtained with either one is usually within 10% with a content of 0.1 wt% or less. It was found that even those with poor measurement conditions can be applied with an error of about 20%.

By observing the absorption edge by this method using such a mass absorption edge jump coefficient, the element can be found from the energy, and the difference between the absorption amount on the low energy side and the absorption amount on the high energy side of the absorption edge, The areal density (Dl (g / cm ² )) of the element is obtained directly by the equation (2).
If processing similar to that in the case of the radiated light described in (A) above is performed, a more accurate absorption edge jump and a highly accurate surface density based thereon can be obtained.

  In the present invention, as shown in FIG. 1, a continuous X-ray light source and an energy discrimination detector (for example, measurement of absorption edge jump of each element contained in the object to be measured and quantitative analysis by element such as surface density) An elemental quantitative analyzer including an “energy dispersive detector” and an analyzer (not shown) is used.

  The continuous X-ray light source in the present invention is composed of a carbon-based cold cathode electron source and a conductive light element having an atomic number smaller than that of titanium. A target that emits X-rays forward and a shielding member (not shown) that shields X-rays other than the X-rays generated by the target are provided.

  The carbon-based cold cathode electron source emits electrons from the front end portion of the carbon nanostructure by a field emission phenomenon even at room temperature. Such a carbon-based cold cathode electron source is not particularly limited, but those described in Patent Document 2 can be suitably used.

  The target is made of a conductive light element having an atomic number smaller than that of titanium. Electrons emitted from the cold cathode electron source are incident on the incident surface and emit X-rays forward with respect to the incident direction. An X-ray tube using a normal heavy metal target has a reflective structure in which electrons are incident at an angle perpendicular to or perpendicular to the incident surface of the target and X-rays are extracted from the incident surface. In the case of a light element target, electrons incident with the same incident energy penetrate into the interior of the heavy metal target, and the X-ray emission angle dependency increases as the energy increases, so the electrons are perpendicular to the target incident surface. Alternatively, a reflection type structure that uses X-rays that are incident at an angle close to vertical and emitted backward with respect to the incident direction cannot obtain a sufficient X-ray dose. The reason why the reflection type structure is used for the heavy metal target is that if the transmission type is used, the X-ray self-absorption in the target is large and the efficiency is low. On the other hand, the light element target has an extremely low X-ray absorption coefficient compared to heavy metals, and has less self-absorption within the target. Therefore, in the present invention, as shown in FIG. 1, a transmissive target structure is used and X-rays emitted forward with respect to the incident direction of electrons are used, or 45 degrees or less (more preferably 20 degrees with respect to the incident surface). The X-rays are used in which electrons are incident on the reflective target at a shallow angle (less than or equal to degrees) and emitted forward in the incident direction. The X-ray emission angle used in either case is preferably an angle of 45 degrees or less with respect to the incident direction of electrons. In either case, the effective focal spot size can be reduced by making the angle formed between the X-ray emission direction and the target emission surface smaller than the angle formed between the electron incidence direction and the target incidence surface.

  Preferable examples of the light element having a smaller atomic number than titanium constituting the target include beryllium, carbon, magnesium, aluminum, silicon, etc., and these elements may be used alone, It may be used as a composite such as pasting or coating, or may be used as a compound such as silicon carbide. Diamond or silicon crystals have low conductivity when the purity is high, but the conductivity can be increased by doping. Beryllium or the like can be used when the output of X-rays is small, but carbon having a high melting point and high emissivity is suitable when X-rays with a large output are required. Carbon can take various structures such as graphite, diamond, amorphous, and diamond-like carbon structures. Although these simple substances can be used as targets, diamond has a different characteristic that it has a high thermal conductivity and graphite has a high conductivity. Therefore, these may be combined to constitute a target.

  The transmission type target of the present invention is configured as a plate-like body, and the thickness thereof is set so that a necessary X-ray dose is emitted from a surface opposite to the incident surface. Although the numerical value of the thickness is not particularly limited, it can be usually 0.1 to 5 mm (preferably 0.2 to 1 mm). In the case of a transmission target, the incident direction of the electron beam is X-rays forward even if it is perpendicular to the incident surface, and the effect of the present invention can be obtained. The incident area on the target can be increased with respect to the size of the electron beam, and cooling is facilitated. The thickness of the reflective target of the present invention is not limited.

  The target may be fixed to the cold cathode electron source, but may be configured to be movable so that it can be easily cooled during use. For example, in the case of a stationary carbon target where the target is stationary, the heat generated by electron beam incidence can be removed by heat conduction and heat radiation from several hundred to 1 kW, but an X-ray source with an output on the order of kW or more. Then, cooling cannot catch up with a fixed target. In this case, a high output X-ray can be generated if the target has a movable structure and heat is removed by thermal radiation while the target is moving. As such a movable mode, a reciprocating linear movement may be used, or the movement locus may draw a circle or an ellipse. In addition, the target can be configured to be rotatable.

  Since the X-ray light source of the present invention uses a light element for both the electron source and the target, a predetermined value corresponding to the type of the light element (300 eV when carbon is selected as the light element of the target, 1900 eV when silicon is selected) In the above energy region, white X-rays having no characteristic X-ray peak are emitted from the target (see FIG. 2).

  However, among X-ray light sources, electrons are scattered after being incident on the target and hit the X-ray tube container to generate characteristic X-rays, or X-rays generated from the target hit the container to generate fluorescent X-rays. There is also. A shielding member is provided to shield X-rays generated from other than these targets from being emitted in the irradiation direction.

In the shielding member, only the X-rays generated at the target reach the irradiation region of the continuous X-ray light source of the present invention, and the X-rays generated by the X-rays other than the target enter the irradiation region of the continuous X-ray light source of the present invention. It is configured not to reach.
As such a shielding member, for example, a collimator made of an element having a high X-ray absorption coefficient such as molybdenum and having a through hole can be used. The through hole may be a straight hole whose diameter does not change or a tapered hole whose diameter changes. By selecting an appropriate tapered hole, the irradiation range in the irradiation region can be adjusted appropriately.

  A shielding member such as a collimator in which a through hole is formed is provided between the target and the irradiation area, and the position and direction of the through hole so that X-rays generated at the target reach the irradiation area through the through hole. Is set. For example, when an electron beam from a cold cathode electron source collides perpendicularly with the incident side surface of the target and X-rays are emitted from the back surface thereof, the axis of the through hole is on an extension of the traveling direction of the electron beam. Thus, the through hole is provided. With such a setting, the characteristic X-rays and fluorescent X-rays generated outside the target are difficult to enter the through-hole, and even if it can enter the through-hole, It is difficult to pass through the through-hole due to attenuation in the middle. Further, even if there is a characteristic X-ray or fluorescent X-ray that exits the through hole, the irradiation direction is greatly deviated from the axis of the through hole, so that the irradiation range of the irradiation region cannot be reached.

  The energy discrimination detector in the elemental quantitative analysis apparatus of the present invention detects the X-ray intensity of X-rays transmitted through the object to be measured. Since the energy discrimination type detector usually has a limited range of measurement intensity, it is necessary to adjust the light source intensity so that appropriate transmitted X-rays enter the detector according to the X-ray absorption of the object to be measured. However, even if the light source intensity is changed by changing the current and voltage of the X-ray source, the amount of jump at the absorption edge is not affected, and thus the light source intensity can be adjusted.

The energy discriminating type detector may detect a point-like portion, but may be a one-dimensional detector or a two-dimensional detector. If a one-dimensional detector or a two-dimensional detector is used, the density distribution for each element of the object to be measured can be easily obtained.
Further, without using a two-dimensional detector, a density distribution chart for each element can be drawn by measuring each region by moving the sample in two dimensions.
From the density distribution diagram of the entire object to be measured, the total amount of each element contained in the object to be measured can be obtained.
Furthermore, it is possible to convert from a density distribution chart obtained by rotating the object to be measured into a three-dimensional distribution chart.

  The analyzer in the elemental quantitative analyzer according to the present invention obtains the absorption edge jump amount of each element contained in the X-ray absorption spectrum of the object to be measured based on the detection value of the energy discrimination detector, and is determined in advance with a standard sample or the like. Based on the mass absorption edge jump coefficient for each element and the absorption edge jump amount of each contained element, the surface density on the X-ray transmission path is obtained for each element contained in the object to be measured. A computer including a memory unit, a calculation unit, a display unit, and the like for storing a mass absorption end jump coefficient and the like can be provided.

  Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited to the examples, and various setting adjustments and design changes can be made without departing from the gist of the present invention. Needless to say.

(Example 1)
Figure 7 shows certified reference materials including 4 types of hazardous metals (Cr925 ± 30mg / kg, Hg928 ± 38mg / kg, Pb926 ± 24mg / kg, Cd92.1 ± 4.9mg / kg) in ABS resin of AIST. An example in which one (1.47 g) disk (diameter 30 mm, thickness 2 mm, area 7.0686 cm ² ) (CRM8116-a) was measured is shown. Because the absorption of the resin is larger than the contained metal, it is difficult to measure when the light source spectrum measured in the atmosphere is used as incident X-rays, but by measuring a resin disc that does not contain metal as a blank The dynamic range of the detector was almost the same, and the spectrum of a trace amount of metal could be measured by extending the integration time (8000 seconds). FIG. 8 is a Cr K absorption edge, and FIG. 9 is a spectrum near the L absorption edge of Hg and Pb. Cd was low in content, and no absorption edge was observed during this integration time.
Cr (K) C _Δμ = 486.45cm ² / g (McMaster)
Δμ = 0.069 Dl = 1.4184 × 10 ^-4 g / cm ²
1.0026 × 10 ^-3 g, 682.067mg / kg per disc, 74% of certified value

Hg (L3) C _Δμ = 97.459cm ² / g (McMaster)
Δμ = 0.0153029 Dl = 1.5701884 × 10 ^-4 g / cm ²
1.1099 × 10 ^-3 g, 755.036 mg / kg per disc, 81% of the certified value

Pb (L3) C _Δμ = 93.586cm ² / g (McMaster)
Δμ = 0.017165 Dl = 1.8341418 × 10-4g / cm ²
1.29648 × 10 ^-3 g, 881.960mg / kg per disc, 95% of the certified value
The error increased because the absolute amount of metal was very small, but the error was about 20% of the certified value.

(Example 2)
FIG. 10 shows another embodiment of the elemental quantitative analyzer of the present invention. Using a crystal spectrometer (condensing crystal), X-rays from a continuous X-ray light source are dispersed with a crystal spectrometer and irradiated onto a non-measurement object (sample), allowing high-resolution X-ray absorption spectra to be measured. Is possible. This improves the quantitative accuracy by absorption edge jump, and at the same time, the information on the chemical state (oxidation number, chemical bonding state, ligand, etc.) and local structure of the absorbing element can be obtained from the structure of the absorption edge. It is possible to perform quantification by structure.

  According to the present invention, non-destructive non-destructive element-by-element quantification can be easily performed with a relatively small apparatus, so that various methods including development of materials, members, devices, etc., and in-situ measurement in various manufacturing processes, etc. It can be applied to simple measurement.

Claims (8)

A carbon-based cold cathode electron source, made of carbon or silicon carbide as a conductive light element having an atomic number smaller than that of titanium. Electrons emitted from the cold cathode electron source are incident on the incident surface and forward with respect to the incident direction. A target that emits X-rays, and a shielding member that shields X-rays other than the X-rays generated by the target, and has a characteristic X-ray peak in an energy region of a predetermined value or more according to the type of light element. The object to be measured can be irradiated with continuous X-rays from a continuous X-ray light source that can irradiate the object to be measured with no continuous X-rays, and the transmitted X-rays are detected with an energy discrimination detector, calculated absorption edge jump of containing each element in the linear absorption spectrum before and mass absorption edge jump coefficient is the absorption edge jump per optical path length 1cm density element by element 1 g / cm ³ determined in advance by the standard sample, etc. Containing, based on the absorption edge jump of each element, elemental specific quantitative analysis method characterized by determining the surface density of the X-ray trajectory for each element contained in the measurement object.   By using a two-dimensional detector arranged on the surface as an energy discrimination type detector, or by measuring each region by moving the object to be measured in two dimensions perpendicular to the irradiation X-ray, The elemental quantitative analysis method according to claim 1, wherein a density distribution is obtained. A carbon-based cold cathode electron source, made of carbon or silicon carbide as a conductive light element having an atomic number smaller than that of titanium. Electrons emitted from the cold cathode electron source are incident on the incident surface and forward with respect to the incident direction. A target that emits X-rays, and a shielding member that shields X-rays other than the X-rays generated by the target, and has a characteristic X-ray peak in an energy region of a predetermined value or more according to the type of light element. A continuous X-ray light source capable of irradiating an object to be measured with continuous X-rays, an energy discriminating detector for detecting the X-ray intensity of the X-ray transmitted through the object to be measured, and detection by an energy discriminating detector with obtaining the absorption edge jump of containing each element in the X-ray absorption spectrum of the object to be measured based on the value, pre-absorbed per optical path length 1cm density of another element elements determined in a standard sample such as 1 g / cm ³ And an analyzer for determining the surface density on the X-ray transmission path for each element contained in the object to be measured based on the mass absorption edge jump coefficient that is a jump and the absorption edge jump amount of each element. Quantitative analyzer for each element.   4. The elemental quantitative analysis apparatus according to claim 3, further comprising a crystal spectroscope that divides X-rays from a continuous X-ray light source and irradiates the object to be measured with the spectral X-rays.   The elemental quantitative analysis apparatus according to claim 3, wherein the target is plate-shaped and emits X-rays from a surface opposite to an electron incident surface.   The elemental quantitative analysis apparatus according to claim 3, wherein the target is an electron incident on an incident surface at an angle of 45 degrees or less.   The elemental quantitative analysis apparatus according to any one of claims 3 to 6, wherein a two-dimensional detector arranged on a surface is used as an energy discrimination type detector, and the analysis apparatus obtains a density distribution for each contained element.   The element according to any one of claims 3 to 6, further comprising an object driving means for moving the object to be measured in a two-dimensional direction perpendicular to the irradiation X-ray, wherein the analyzer obtains a density distribution for each contained element. Another quantitative analyzer.