JP2004093495A - Total reflection prism and total reflection apparatus using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a total reflection prism for improving the light collection efficiency in total reflection measurement. <P>SOLUTION: The total reflection prism 22 is provided with an abutting part 38 including a sample face 36 abutting on a sample 32 and a light entrance/emission part 42 including a light entrance/emission face 40 for inputting an incident light 30 having an incident angle of a critical angle or more to an abutting face between the sample face 36 and the sample 32 and outputting a total reflection light 34 from the abutting face. The abutting part 38 is constituted of a hard material with high reflectance in comparison with the sample 32. A region in contact with the light entrance/emisssion part 42 is formed in an inverted triangle shape cross section. The light input/output part 42 is constituted of a material having a wide transmission wavelength range. It characterized in that a region in contact with the abutting part 38 is formed in a recess for exactly matching with the inverted triangle shape, and the abutting part 38 and the light entrance/emission part 42 are in. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a total reflection prism and a total reflection device using the same, and particularly to a mechanism for improving the light collection efficiency.
[0002]
[Prior art]
In order to obtain various optical data of a sample, analyzers such as a Fourier transform infrared spectrophotometer (FTIR) for measuring reflected light from the sample or transmitted light from the sample are well known.
Meanwhile, in FTIR, a total reflection measurement method is applied to a sample in which measurement of reflected light or transmitted light by a general method is difficult (for example, see Patent Document 1).
That is, a total reflection prism having a higher refractive index than the sample is placed on the sample, and light is incident on the prism by an external lens.
[0003]
When the angle of incidence from the prism to the sample is larger than the critical angle, the incident light is totally reflected at the interface between the sample and the prism. At this reflection point, light slightly enters the sample. Therefore, when the sample absorbs light, the light totally reflected at the interface decreases accordingly.
This is condensed by a lens, and the characteristics of the total reflection light at the interface between the sample and the prism are analyzed to analyze the surface of a polymer film or semiconductor, or when the sample shows extremely strong light absorption. Also, optical information can be obtained from the sample.
[0004]
[Patent Document 1]
U.S. Pat. No. 5,965,889
[0005]
[Problems to be solved by the invention]
By the way, in the total reflection measurement, the light use efficiency is lower than that of the general reflection light measurement or transmitted light measurement, and therefore, improvement of the light collection efficiency is demanded.
According to the present inventors, in order to most effectively improve the light collection efficiency in the total reflection measurement, it is necessary to improve the light transmission characteristics of the total reflection prism, particularly to increase both the transmission wavelength range and the transmittance. Although it was found to be very important, there was no appropriate technology that could solve this problem.
[0006]
An object of the present invention is to provide a total reflection prism and a total reflection apparatus using the same, which can improve the light collection efficiency in total reflection measurement. .
[0007]
[Means for Solving the Problems]
The inventors of the present invention have further studied the improvement of the light collection efficiency in the total reflection measurement, and as a result, the total reflection prism is generally formed of one type of material. By dividing the structure into at least two parts and configuring each part with a material optimal for its function, the transmission wavelength range can be expanded and the transmittance can be improved. As a result, it has been found that the light collection efficiency in the total reflection measurement can be greatly improved, and the present invention has been completed.
[0008]
That is, in order to achieve the above object, the total reflection prism according to the present invention includes a sample surface that is in contact with the sample, and an incident light in which the incident angle to the contact surface between the sample surface and the sample is equal to or larger than the critical angle. A light-entering and light-exiting surface having a light-entering and light-exiting surface from which light is incident and totally reflected from the contacting surface; And a unit. The contact portion is made of a material that is harder than the sample and has a higher light refractive index, and a contact portion with the light input / output portion is formed in an inverted triangular cross section. The light entering / exiting portion is formed of a material having a long transmission wavelength range, and has a concave portion having a shape in which a contact portion with the contact portion is in close contact with the inverted triangle. The contact portion and the light incident / exit portion are closely adhered to each other.
[0009]
The contact portion between the abutting portion and the light entering / exiting portion, that is, the contact surface on the incident side is oriented in a direction perpendicular to the incident optical axis, and the contact surface on the exit side is perpendicular to the total reflection optical axis on the exit side. It is particularly preferable that they are oriented in the direction in which light loss at these contact surfaces can be significantly reduced.
For this reason, the contact portion between the contact portion and the incident / outgoing light portion is formed in an inverted triangular cross section when the incident side contact surface is orthogonal to the incident optical axis and the exit side contact surface is orthogonal to the total reflection optical axis. If so, the shape is not limited to the original inverted triangular cross section, but includes the deformed shape. For example, the contact surface between the contact portion and the light-in / out portion may have an inverted triangular cross section, or may include a shape such as an inverted trapezoidal cross section in which the back portion (apex) of the contact portion is flattened. The term “contact portion and light input / output portion being in close contact with each other” means that at least the incident side contact surfaces and the outgoing side contact surfaces are in close contact with each other.
In the present invention, the lower limit of the transmission wavelength range is 250 to 700 cm. ^-1 Is preferably included in the range.
[0010]
Further, in the present invention, the contact portion is selected from the group consisting of diamond, silicon, and germanium, and the light incident and exit portions are KRS-5 (thallium bromide (TlBr) -thallium chloride (TlCl)), KBr, CSI Preferably, it is selected from the group consisting of: In particular, it is preferable that the abutting portion is made of diamond and the light entering and exiting portion is made of KRS-5.
In the present invention, it is preferable that the light entering and exiting portions have spherical light entering and exiting surfaces.
[0011]
Further, in the present invention, the light input / output portion is provided with a hole penetrating to a back portion on the opposite side of the sample surface of the contact portion in a direction orthogonal to the sample surface passing through the center position, and further includes a prism support. Preferably, it is provided.
Here, the prism support is inserted into the hole of the light entrance / exit portion, and directly supports the back of the contact portion in a direction orthogonal to the sample surface.
[0012]
In order to achieve the above object, a total reflection device according to the present invention includes, in the total reflection prism, a sample box main body, a prism holder, a fixed body, a holder support, and an elastic body. When the fixed body is removed, the holder support preferably uses the restoring force of the elastic body to raise the prism holder to a predetermined height with respect to the main body.
Here, the prism holder is detachably provided to the main body while holding the total reflection prism.
The fixed body fixes the prism holder to the main body.
[0013]
The holder support has a main body side end provided in the main body in a state where the holder side end is in contact with the prism holder, and is movable together with the prism holder within a predetermined distance in a mounting / detaching direction of the prism holder. I do.
The elastic body is provided between the main body side end of the holder support and the main body, and shrinks with the prism holder fixed to the main body.
[0014]
In the present invention, the sample holder, the holder for the holder, the guide groove, and the steady rest are provided. It is preferable that the front end of the steady rest always abuts the guide groove, and the steadying of the press holding body with respect to the guide shaft is performed in the guiding direction of the press holding body and in a direction orthogonal to the guiding direction. .
Here, the sample holder presses the sample placed on the sample surface of the total reflection prism in a direction orthogonal to the sample surface.
[0015]
Further, the guide shaft has an axial direction coinciding with a direction orthogonal to the sample surface of the total reflection prism.
The holder holds the sample holder, moves along the guide axis in a direction perpendicular to the sample surface of the total reflection prism, and moves the sample to the sample holder perpendicular to the sample surface of the total reflection prism. Press in the direction.
[0016]
The guide groove is provided in a guide direction of the guide shaft.
The steady rest is provided so as to fit into the guide groove of the guide shaft via the holding member, and moves together with the holding member along the guide groove.
[0017]
Further, in the present invention, the incident-side reflection optical element including a concave mirror that converges light and makes the boundary surface between the sample surface and the sample of the total reflection prism incident at an angle of incidence equal to or greater than a critical angle; It is preferable to include an output-side reflection optical element including a concave mirror that collects the total reflection light from the boundary surface between the sample surface and the sample.
[0018]
Further, in the total reflection device, the light-collecting position of the reflection optical element may be set on the optical axis of the reflection optical element passing through a center position of a boundary surface between the sample and the total reflection prism when the total reflection prism is not provided. Although located farther than the center position of the surface, in a state where the total reflection prism is present, light is transmitted to the concave mirror of the reflection optical element, It is preferable that the light is converged by the light entering and exiting surfaces of the reflecting prism.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a schematic configuration of a total reflection measuring apparatus using a total reflection prism according to an embodiment of the present invention.
The total reflection measuring device 10 shown in FIG. 1 is made of FTIR, and includes an infrared light source 12, an interferometer 14, a sample box (total reflection device) 16, a detector 18, and a computer 20.
The sample box 16 includes a total reflection prism 22, an incident-side reflective optical element 24, and an output-side reflective optical element 26.
[0020]
The coherent light 28 from the light source 12 is incident on the interferometer 14, and the coherent light 30 from the interferometer 14 irradiates a sample 32 mounted on a sample surface 36 of the total reflection prism 22. That is, the interference light 30 from the interferometer 14 is incident on the boundary surface between the total reflection prism 22 and the sample 32 at an incident angle equal to or greater than the critical angle by the incident side reflection optical element 24. Totally reflected light 34 from the boundary surface is collected by the output side optical element 26 and detected by the detector 18. The interferogram from the detector 18 is Fourier-transformed by the computer 20 to obtain a spectrum of each wavelength.
[0021]
What is characteristic in the present embodiment is that the total reflection prism 22 is configured such that the incident angle to the contact portion 38 including the sample surface 36 contacting the sample 32 and the interface between the sample surface 36 and the sample 32 are critical. The light entering / exiting portion 42 including the light entering / exiting surface 40 from which the light 30 having an angle or more enters and the total reflected light 34 from the contact surface exits is made of different optimal materials.
The contact portion 38 is made of diamond which is harder than the sample 32 and has a high light refractive index.
[0022]
The input / output light section 42 has a long transmission wavelength range of KRS-5 (transmission wavelength range of 5000 to 250 cm). ^-1 ).
FIG. 2 is an enlarged view of the total reflection prism 22 according to the present embodiment.
The total reflection prism 22 shown in FIG. 2 includes a contact portion 38 and a light input / output portion 42.
The contact portion 38 has a contact surface (contact portion) 44 with the light incident / exit portion 42 formed in a conical shape (an inverted triangular longitudinal section) with an opening angle of 90 °, and the sample surface 36 is formed in a planar shape.
[0023]
The light input / output portion 42 has a contact surface (contact portion) 46 with the contact portion 38 formed in a concave shape that receives a cone (an inverted triangular cross section), and the contact portion 38 and the light input / output portion 42 at least allow light to pass through. The boundary portion is closely adhered, and the infrared light that enters or exits from the light entrance / exit portion is almost perpendicular to the interface.
[0024]
The total reflection prism 22 according to the present embodiment is configured roughly as described above, and its operation will be described below.
Although the conventional total reflection prism is made of a single material, the present invention can improve the optical efficiency by making the following improvements.
In other words, if the total reflection prism is composed of diamond only, the diamond having a size of 2000 cm ^-1 A sharp drop in light transmittance in the vicinity is noticeable.
In addition, if it is composed only of general ZnSe, it may be crushed or broken by a pressing force on a hard sample. Moreover, the lower limit of the transmission wavelength range is 700 cm. ^-1 Not very wide.
[0025]
Therefore, in the present embodiment, the total reflection prism 22 has two types of double structures of the contact part 38 and the light input / output part 42. A thin but hard diamond with a high light refractive index is used for the contact portion 38, and KRS-5 having good transmission characteristics, that is, KRS-5 having a long transmission wavelength range is used for the light input and output light portion 42. By closely adhering the contact portion 38 with the contact portion 38, the transmission wavelength range can be expanded, the light collection efficiency can be improved, and the transmittance can be improved.
[0026]
Here, the selection of the material of the abutting portion 38 and the light entering / exiting portion 42 is very important. In the present embodiment, the material of the abutting portion 38 is selected from a number of optical elements as compared with the sample. A diamond that is hard and has a high light refractive index is selected.
As the material of the light input / output part 42, KRS-5 (a transmission wavelength range of 5,000 to 250 cm) having a long transmission wavelength range while maintaining a light transmittance at each wavelength at a predetermined or higher value. ^-1 ).
[0027]
Here, in the selection of the optical element, usually, only the light transmittance of the light transmission characteristics is used as a reference, but in the present embodiment, the light transmittance at each wavelength has a higher value than a predetermined value. Of course, focusing on a particularly long transmission wavelength range, KRS-5 is selected from a number of optical element materials.
By combining the diamond and the KRS-5 in this way, compared to the diamond alone, it is 2000 cm. ^-1 The sharp drop in light transmittance in the vicinity is greatly improved by the combination with KRS-5. Moreover, the characteristics of the long transmission wavelength range of KRS-5 are provided as they are.
[0028]
In addition, by using diamond for the contact portion, it is possible to significantly reduce the possibility that the sample surface is crushed or damaged as compared with KRS-5 alone.
In addition, the shape of the contact portion and the light entering / exiting portion is such that the contact surface of the contact portion with the light entering / exiting portion is formed in a conical shape with an opening angle of 90 °, while the contact surface of the light entering / exiting portion with the contact portion is as described above. It is formed in a concave shape that can receive the cone in a tightly contacted state, and the infrared light that enters or exits from the light entrance / exit portion is almost perpendicular to the interface, so that the reflection loss due to the difference in the refractive index is reduced. . Thereby, the light collection efficiency can be further improved.
[0029]
This significant improvement in light-collecting efficiency is achieved by the fact that the interface between the contact portion and the light-in / out portion is closely adhered as in the present invention, and the contact surface of the contact portion with the light-in / out portion is formed in a conical shape or the like. Only when the combination of the above-mentioned steps (in which the light is incident on and out of the contact surface in a perpendicular direction to reduce the reflection loss at the contact surface significantly), the light loss is greatly reduced. It can be obtained effectively.
On the other hand, for example, if there is a gap such as an air gap between the abutting portion and the incoming / outgoing light portion, the loss of light, the influence of light interference becomes very large, and the improvement effect is greatly reduced. In order to improve the light collection efficiency, it is particularly preferable that these interfaces are closely adhered.
[0030]
Also, if there is a gap such as an air gap, it is necessary to adjust the optical position between the contact portion and the light-in / out portion, but it is very difficult to adjust these positions, and the optical position between the contact portion and the light-in / out portion is difficult. In some cases, it is not possible to perform a proper position adjustment properly, which also lowers the light collection efficiency. On the other hand, in the present embodiment, the contact portion and the light incident / exit portion are closely adhered, so that their optical position adjustment is unnecessary, and the optical position adjustment of the contact portion and the light incident / exit portion is not required. Can be appropriately performed, so that the light collection efficiency can be improved.
[0031]
Further, by forming the light entrance and exit surfaces of the light entrance / exit portion in a hemispherical shape, the light entrance / exit surface can be used as a condenser lens, so that the luminous flux on the sample surface can be reduced. In addition, by reducing the material of the contact portion, the absorption of light possessed by the material can be reduced. Thereby, the light collection efficiency in the total reflection measurement can be further improved.
As described above, according to the total reflection prism according to the present embodiment, the contact portion and the light incident / outgoing portion are separated, and diamond is selected as the material of the contact portion from among a number of optical element materials. KRS-5 was selected as the material of the part.
[0032]
As a result, in the total reflection prism according to the present embodiment, the transmission wavelength range is expanded and the transmittance is improved. Thereby, the light collection efficiency in the total reflection measurement of the present embodiment can be improved.
The present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention.
[0033]
<Material>
The material of the contact portion is preferably diamond, and the combination of KRS-5 is particularly preferable as the material of the light input / output portion. In addition, the material of the contact portion is selected from the group consisting of silicon and germanium. Is preferably selected from the group consisting of KBr and CSI.
[0034]
<Sample box>
For example, it is particularly preferable to use the following as the sample box 16.
FIG. 3 is a schematic perspective view of the sample box 16.
In the sample box 16 shown in the figure, an entrance side reflection optical element 24 and an exit side reflection optical element 26 are arranged inside.
A pipe (not shown) for supplying a purge gas is provided in the sample box 16 so that the optical path of the optical element can be purged, and the optical element in the sample box 16 can be purged.
[0035]
<Prism holder>
Further, since the prism is fixed in a state where it is positioned on the holder, the prism can be exchanged with the holder and the reproducibility of positioning can be obtained. Therefore, it is particularly preferable to use a prism holder as described below.
The prism holder 50 shown in the figure holds a total reflection prism on an upper part of the prism holder 50 with at least a part of the sample surface 36 exposed.
Since the space between the total reflection prism 22 and the prism holder 50 is sealed by packing (not shown), a liquid sample can be measured.
[0036]
(Prism holding mechanism)
In the total reflection device, in order to obtain a good spectrum, it is necessary to accurately and strongly press the sample against the tip of the prism, that is, the contact portion.
Here, in order to avoid that the pressing force from the contact portion is transmitted to the light entering and exiting portion and the distortion is generated in the light entering and exiting portion, an air gap may be provided between the contact portion and the light entering and exiting portion. However, the influence of reflection loss, occurrence of optical interference, and the like increases, which may cause a decrease in light collection efficiency. In addition, the presence of an air gap and the direction in which the prism is held are different from the pressing direction, so that the prism may not be pressed firmly against the measured object.
[0037]
Therefore, in the present embodiment, the prism is held as shown in FIG.
FIG. 7A is a diagram of the holding state of the prism as viewed from the side, and FIG. 7B is a diagram of the same prism holding state as viewed from above.
That is, the light input / output unit 42 is provided with the hole 54 penetrating to the back 52 on the opposite side of the sample surface 36 of the contact part 38 in the direction orthogonal to the sample surface 36 passing through the center position.
The prism holder 50 includes a support rod (prism support) 56 that is inserted into the hole 54 of the light input / output part 42 and directly supports the back part 52 of the contact part 38 in a direction orthogonal to the sample surface 36.
[0038]
Since the rigid contact portion 38 that comes into contact with the sample is mechanically supported directly from the back side of the sample surface 36 by the support rod 54 fixed to the prism holder 50, the prism 22 is attached to the sample, that is, Even if the sample surface 36 is firmly pressed, the prism 22 can be reliably prevented from being distorted or damaged.
[0039]
(Prism holder lifting mechanism)
It is particularly preferable to provide a prism holder lifting mechanism described below.
In the prism of the total reflection device, the prism may be removed from the sample box due to dirt, scratches, or the like on the prism due to the sample.
Conventionally, since the prism holder is too thin, conventionally, the screw of the prism holder was removed, the prism was picked up with tweezers, or the whole total reflection device was removed downward, but this was troublesome.
[0040]
Therefore, in the present embodiment, as shown in FIG. 5A, the prism holder 50 is detachably provided to the main body 58 of the sample box while holding the total reflection prism 22. The prism holder 50 is fixed to the main body 58 by a fixing screw (fixed body) 60.
Also, as shown in FIG. 5B, the main body 58 includes a hollow screw 62, a pin (holder support) 64, and a spring (elastic body) 66.
[0041]
The pin 64 has a main body side end 64b provided on a spring 66 in a state in which the holder side end 64a is in contact with the lower part of the prism holder 50, and a predetermined distance in a mounting / detaching direction of the prism holder 50, that is, a vertical direction in the drawing. And the movable part together with the prism holder 50.
The spring 66 is provided on the main body 58 in a state of being inserted in the hollow screw 62, the upper end is provided on the main body side end 64 b of the pin 64, and the other end is provided on the inner bottom wall of the hollow screw 62. ing.
[0042]
Then, when removing the prism 22, when the fixing screw 60 is removed, as shown in FIG. 6, the pin 64 uses the restoring force of the spring to move the prism holder 50 to the main body 58 to a predetermined height h. For example, the prism 22 can be lifted to a height that can be easily grasped with a finger, so that it can be easily grasped with a finger and the prism 22 can be removed together with the prism holder 50.
[0043]
<Stabilizing mechanism>
It is also particularly preferable to have the steady rest mechanism described below.
That is, in the total reflection device, in order to obtain a good spectrum, it is necessary to accurately and strongly press the sample against the tip of the prism.
For this purpose, it is conceivable to press the sample against the sample surface using a sample holder.In the past, attempts have been made to increase the mechanical dimensional accuracy of the guide mechanism of the sample holder to prevent axial deviation. The effect of reducing the vertical run-out was not sufficient.
[0044]
Therefore, in the present embodiment, the guide mechanism shown in FIG. 7 is provided with a steady rest mechanism as described below. FIG. 2A is a view of the steady rest mechanism viewed from the side, and FIG. 2A is a view of the same steady rest mechanism viewed from the back.
First, the following guide mechanism is used.
The guide mechanism holds a holding shaft (guide shaft) 68 provided on the main body 58 of the sample box 16 and a sample holder 70 for pressing a sample placed on the sample surface of the total reflection prism 22. A gear holder (press holding body) 72 that moves in the vertical direction in FIG.
[0045]
The presser shaft 68 is provided with a linear gear 74 in the vertical direction in the drawing, which is the guide direction.
The gear holder includes a circular gear 76 and is engaged with the gear 74 of the presser shaft 68.
The circular gear 76 is interlocked with a knob 78. When the knob 78 is rotated, the circular gear 76 also rotates in the same direction, and the gear holder is moved along the holding shaft 68 via the linear gear 74. 72 is moved up and down in the figure.
[0046]
Here, in the present embodiment, a steadying mechanism as described below is used for the guide mechanism.
That is, the guide groove 80 is cut in the guide direction of the presser shaft 68.
The steady rest 82 is provided such that the tip end thereof fits in the guide groove 80 of the holding shaft 68 via the gear holder 72.
The steady rest 82 moves together with the gear holder 72 along the guide groove 80 with the tip of the steady rest 82 always pushing the guide groove 80 of the holding shaft 68 with the screw 84.
[0047]
That is, when the knob 78 is turned, the gear holder 72 moves downward in the drawing along the holding shaft 68, and the sample holder 70 comes into contact with the sample 32 as shown in FIG. Move it down until it reaches the value and stop moving.
[0048]
The tip of the steady rest 82 is always in close contact with the guide groove 80 during the measurement as well as during the movement of the sample holder 70, and the gear holder 72 is always mechanically pressed against the holding shaft 68. Without the need for precision, the sample holder is held in the vertical direction I, which is the guide direction of the gear holder 72, as shown in FIG. 7A, and in the left-right direction J, which is orthogonal to the guide direction as shown in FIG. 70 can be sufficiently stopped.
It is important that the pressure for pressing the sample is within a certain range (from the pressure at which the sample adheres to the pressure at which the prism is not broken). For this purpose, it is also preferable to use the following.
[0049]
The holding part is detachable.
The holding part can be replaced with one with a pressure monitor.
The pressure monitor includes a pressure sensor, a display unit, and a power supply.
The display unit is on the upper surface of the presser unit, and displays the pressed pressure numerically.
The pressure monitor allows the same pressure to be applied to the same sample.
The presser can be replaced with a motor driven one.
The motor drive presser can be monitored for up, down, and pressure values by a computer or the like.
[0050]
<Reflective optical element>
Conventionally, in an FTIR having no function of a microscope, a lens is usually used to focus light on a prism. Therefore, there were the following disadvantages.
The wavelength range that can be measured is determined by the material of the lens. The commonly used lens material is ZnSe, and the wavelength range used is 5000-750 cm. ^-1 Met.
In addition, most of the light use efficiency largely depends on the transmittance of the lens, and most of the lenses used usually have a large relative refractive index, and the transmittance is about 70%, and the light use efficiency is improved. Room was left.
[0051]
Therefore, in the present embodiment, a reflective optical element such as an ellipsoidal mirror (concave mirror) is used for condensing light on the prism in order to improve the light use efficiency, and the spherical light entrance and exit surfaces of the total reflection prism are used. The lens is used to condense the light.
That is, in the present embodiment, the entrance side reflection optical element and the exit side reflection optical element are provided in the main body 58 of the sample box 16.
[0052]
As shown in FIG. 9, the incident-side reflection optical element includes a plane mirror 88, a plane mirror 90, and an incident-side elliptical mirror (concave mirror) 24.
The emission-side reflection optical element includes an emission-side elliptical mirror (concave mirror) 26, a plane mirror 92, and a plane mirror 94.
Then, in the sample box 16, as shown in FIG. 10, the incident light 30 is incident on the contact surface between the prism 22 and the sample, and the totally reflected light 34 is emitted. 2A is a diagram viewed from above, FIG. 2B is a diagram viewed from the side, and FIG. 2C is a diagram viewed from the front.
[0053]
That is, the incident light 30 from the interferometer (not shown) to the sample box is incident on the entrance-side elliptical mirror 26 via the plane mirrors 88 and 90. The elliptical mirror 26 converges the light 30 from the plane mirror 90 and makes the light 30 incident on the interface between the sample surface of the total reflection prism 22 and the sample at a critical angle or more.
Totally reflected light 34 from the boundary surface is condensed by the emission-side ellipsoidal mirror 26, further reflected by the reflection mirrors 92 and 94, exits from the main body 56 of the sample box, and is detected by a subsequent detector (not shown). Is done.
[0054]
Here, when the condensing position of the ellipsoidal mirror is in a state without the total reflection prism 22, the optical axis of the ellipsoidal mirror passing through the center position 96 of the boundary surface between the sample 32 and the total reflection prism 22, as shown in FIG. Although located at a point 98 in the figure on the X, which is farther than the center position 96 of the boundary surface, in the state where the total reflection prism 22 is present, the center position 96 of the boundary surface between the sample 32 and the total reflection prism 22 is obtained. Thus, the light 30 is converged by the elliptical mirror, the light entering and exiting surfaces 40 of the total reflection prism 22.
[0055]
As described above, in the present embodiment, in addition to converging light with an ellipsoidal mirror, the light entrance and exit surfaces of the total reflection prism that are directly in contact with the sample are configured to have a hemispherical shape, thereby providing a lens effect. Can be. Therefore, since the light flux on the sample surface can be reduced, the material of the contact portion can be made thinner, and the absorption of the light of the material can be reduced. Thereby, the light collection efficiency in the total reflection measurement can be further improved.
[0056]
In addition, since all reflection optical elements are used without using a transmission optical element such as a lens in the light collection system, the wavelength range to be used is not limited by the light collection optical system, but is determined by the material of the prism. For example, if KRS-5 is used, 5000-250 cm ^-1 Can be measured over a long range.
[0057]
When a reflective optical element is used in the light condensing system as in the present embodiment, the light utilization efficiency is determined by the material coated on the element. For example, in the case of aluminum coating, ^-1 In the range of 97 to 99%.
By using the sample box 16 as described above, the light collection efficiency in the total reflection measurement can be further improved.
[0058]
【The invention's effect】
As described above, according to the total reflection prism of the present invention, the contact portion including the sample surface is formed of a hard material, and the light input and output portion including the light input and output surfaces is formed of a material having a long transmission wavelength range. Therefore, the transmission wavelength range can be expanded and the transmittance can be improved. Thereby, the light collection efficiency in the total reflection measurement can be improved.
In the present invention, the contact portion is selected from the group consisting of diamond, silicon, and germanium, and the light input / output portion is selected from the group consisting of KRS-5, KBr, and CSI. Since the efficiency can be further improved, the light collection efficiency in the total reflection measurement can be further improved.
Further, in the present invention, the light entrance and exit surfaces of the light entrance / exit portion are spherical, so that the light collection efficiency in the total reflection measurement can be further improved.
Further, according to the total reflection apparatus of the present invention, by providing a hole in the light entrance / exit portion and providing a prism support that directly supports the back of the contact portion in a direction perpendicular to the sample surface, the total reflection in the total reflection measurement can be achieved. The light efficiency can be further improved.
Further, in the present invention, when the fixed body is removed, the holder support uses the restoring force of the elastic body, and raises the prism holder to a predetermined height with respect to the main body, thereby improving the light collection efficiency in the total reflection measurement. It can be further improved.
Further, in the present invention, by using a steady rest that is always in close contact with the guide groove, and by performing the steady rest of the press holding body with respect to the guide shaft in the guide direction of the press holding body and in a direction orthogonal to the guiding direction. Light collection efficiency in reflection measurement can be further improved.
In the present invention, the total reflection measurement is performed by using a reflective optical element including a concave mirror as the optical system on the incident side and the exit side to the total reflection prism, and the incident and exit surfaces of the entrance and exit sections are spherical. Can be further improved.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a schematic configuration of a total reflection measuring device using a total reflection prism according to an embodiment of the present invention.
FIG. 2 is an enlarged view of the total reflection prism shown in FIG.
FIG. 3 is an explanatory diagram of a schematic configuration of a sample box shown in FIG. 1;
FIG. 4 is an explanatory diagram of a schematic configuration of the prism holder shown in FIG.
FIG. 5 is an explanatory diagram of a schematic configuration of a prism holder lifting mechanism shown in FIG. 3;
6 is an explanatory diagram of a state in which the prism holder shown in FIG. 5 is lifted.
7 is an explanatory diagram of a schematic configuration of a holding mechanism suitable for the sample box shown in FIG. 3;
FIG. 8 is an explanatory diagram of a use state of the holding mechanism shown in FIG. 7;
9 is an explanatory diagram of a schematic configuration of a reflection optical element arranged in the sample box shown in FIG.
FIG. 10 is an explanatory diagram of a use state of the reflective optical element shown in FIG.
11 is an explanatory diagram of a light condensing state by the reflection optical element and the total reflection prism shown in FIG.
[Explanation of symbols]
16 Sample box (total reflection device)
22 Total reflection prism
36 Sample surface
38 Contact section
40 Light input and output surface
42 Light I / O part

Claims (10)

A sample surface abutting on the sample,
Incident light whose incident angle to the contact surface between the sample surface and the sample is equal to or greater than the critical angle is incident, and light incident and light exit surfaces from which total reflection light from the contact surface is emitted,
In a total reflection prism with
A contact portion including the sample surface, and a light input and output portion including the light input and output surfaces,
The contact portion is harder than the sample, is made of a material having a high light refractive index, a contact portion with the light input and output portion is formed in an inverted triangular cross section,
The input / output light portion is formed of a material having a long transmission wavelength range, and a concave portion having a shape in which a contact portion with the contact portion is in close contact with the inverted triangle is formed,
A total reflection prism, wherein the contact portion and the light incident / exit portion are closely adhered. The total reflection prism according to claim 1,
A total reflection prism, wherein a lower limit of the transmission wavelength range is included in a range of 250 to 700 cm ^-1 . The total reflection prism according to claim 1 or 2,
The contact portion is selected from the group consisting of diamond, silicon, and germanium,
A total reflection prism, wherein the light input / output section is selected from the group consisting of KRS-5, KBr, and CSI. The total reflection prism according to claim 3,
The contact portion is a diamond,
The incident light section is a KRS-5, and is a total reflection prism. The total reflection prism according to any one of claims 1 to 4,
A total reflection prism, wherein the light entering and exiting portions have spherical light entering and exiting surfaces. The total reflection prism according to any one of claims 1 to 5,
The input / output light portion is provided with a hole penetrating to a back portion on the opposite side of the sample surface of the contact portion in a direction orthogonal to the sample surface passing through the center position,
The total reflection device further includes a prism support that is inserted into the hole of the light entrance / exit portion and directly supports the back of the contact portion in a direction perpendicular to the sample surface. The total reflection prism according to any one of claims 1 to 5,
The body of the sample box,
While holding the total reflection prism, a prism holder detachably provided to the main body,
A fixed body for fixing the prism holder to the main body,
In a state in which the holder side end is in contact with the prism holder, the main body side end is provided in the main body, and a holder support that is movable together with the prism holder within a predetermined distance in a mounting / detaching direction of the prism holder.
An elastic body provided between the main body side end of the holder support and the main body, and contracted in a state where the prism holder is fixed to the main body;
A total reflection device, wherein when the fixed body is removed, the holder support uses the restoring force of the elastic body to raise the prism holder to a predetermined height with respect to the main body. The total reflection prism according to any one of claims 1 to 5,
A sample holder for pressing a sample placed on the sample surface of the total reflection prism in a direction orthogonal to the sample surface,
A guide shaft having an axial direction coinciding with a direction orthogonal to the sample surface of the total reflection prism,
Holding the sample holder, moving the sample holder along a guide axis in a direction orthogonal to the sample surface of the total reflection prism, and holding the sample holder in the sample holder in a direction orthogonal to the sample surface of the total reflection prism. Presser holder for pressing,
A guide groove provided in a guide direction of the guide shaft;
A steady rest provided so as to fit into the guide groove of the guide shaft via the holding member, and moving together with the holding member along the guide groove;
Wherein the tip of the steady rest is always exactly in contact with the guide groove, and in the guiding direction of the press holding body and in a direction orthogonal to the guiding direction, the steady holding of the press holding body with respect to the guide shaft is performed. Total reflection device. The total reflection prism according to claim 5,
An incident-side reflecting optical element including a concave mirror that converges the light and makes the light incident on the interface between the sample surface and the sample of the total reflection prism at a critical angle or more,
An emission-side reflection optical element including a concave mirror that collects total reflection light from a boundary surface between the sample surface and the sample of the total reflection prism,
A total reflection device comprising: The total reflection device according to claim 9,
The light-collecting position of the reflective optical element is farther than the center position of the boundary surface on the optical axis of the reflective optical element passing through the center position of the boundary surface between the sample and the total reflection prism when the total reflection prism is not provided. However, in the state where the total reflection prism is present, the light is transmitted to the concave mirror of the reflection optical element, the light entering and exiting the total reflection prism so as to be at the center position of the boundary surface between the sample and the total reflection prism. A total reflection device characterized by being converged by a surface.

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