[0001] The present invention relates to a diffraction grating for an X-ray Talbot interferometer,
a method of manufacturing the same, and an X-ray Talbot interferometer.
[0002] There is known a Talbot effect, in which a diffraction grating is used and self images
of the diffraction grating are formed at specific distances from the diffraction grating
when light from a coherent light source passes through the diffraction grating. In
recent years, there has been developed an X-ray Talbot interferometer that uses this
Talbot effect so as to detect a phase shift of a transmitted X-ray. An image obtained
by the phase shift of an X-ray using the Talbot effect is advantageous in having higher
contrast particularly in a substance having a small atomic number than a conventional
image obtained by an absorbed amount of a transmitted X-ray.
[0003] As such an X-ray Talbot interferometer, there is known a structure illustrated in
FIG. 9. The X-ray Talbot interferometer 1000 includes a first diffraction grating
1010, a second diffraction grating 1020, and an X-ray image detector 30 (see International
Patent
WO 2004/58070 A). As illustrated in FIGS. 10A and 10B, the first diffraction grating 1010 and the
second diffraction grating 1020 have grooves 1010a and 1020a formed in a metal plate
at predetermined intervals in one direction. The groove transmits the X-ray, while
a ridge portion 1010b between neighboring grooves transmits the X-ray after shifting
the phase by π/2, and a ridge portion 1020b blocks (absorbs) the X-ray. As a material
of the diffraction grating, gold (Au) having high X-ray absorbing power is usually
used.
[0004] In this X-ray Talbot interferometer, when the X-ray is irradiated from an X-ray source
to the first diffraction grating via a sample, the X-ray transmitted through the groove
portion 1010a and the X-ray transmitted and diffracted through the ridge portion 1010b
interfere with each other. Then, self images of the first diffraction grating 1010
are formed at positions of integral multiples of a Talbot distance d2/2λ of the first
diffraction grating 1010 (d represents a period of the diffraction grating, and λ
represents a wavelength of the X-ray) as the Talbot effect. The self image has a distortion
due to a sample 4, and the distortion has information of the sample. The second diffraction
grating 1020 is disposed at a position where the self image of the first diffraction
grating 1010 is formed. Then, a distribution of the X-ray transmitted through the
second diffraction grating 1020 has moire fringes because the first self image is
overlaid. Therefore, this X-ray distribution is detected by the X-ray image detector,
and image analysis is performed so that an image of the sample 4 is obtained. In order
to improve image contrast, it is preferred that the groove portion 1020a of the second
diffraction grating 1020 have a high X-ray transmittance, while the ridge portion
1020b have a low X-ray transmittance. Therefore, it is preferred that the second diffraction
grating 1020 be an amplitude diffraction grating having a larger thickness than the
first diffraction grating 1010.
[0005] Here, in order to generate the Talbot effect, it is necessary that the ridge portions
(X-ray absorbing portions) of the diffraction grating have a period securing coherency
of the X-ray. Therefore, the thickness of the ridge portion is required to be approximately
10 µm or smaller. Further, in a phase diffraction grating, the contrast of the self
image becomes highest when a phase shift amount becomes π/2. Therefore, in order to
realize this, it is necessary to set a thickness of the ridge portion (depth of the
groove) at approximately 1 to 10 µm, and fine machining and manufacturing technique
are required.
[0006] On the other hand, in order to function as the amplitude diffraction grating, it
is preferred that the groove portion 1020a of the diffraction grating have a high
X-ray transmittance and the ridge portion 1020b have a low X-ray transmittance. Therefore,
it is required to form the groove to have a large depth of approximately 10 to 100
µm even when gold is used. Therefore, an aspect ratio expressed by (depth of groove)/(width
of groove) of the diffraction grating becomes very large, and hence production of
the diffraction grating becomes difficult.
[0007] Therefore, there is disclosed a technique of manufacturing the diffraction grating
for the X-ray Talbot interferometer, in which a deep groove is formed in a resin by
X-ray lithography using an X-ray mask, and the X-ray absorbing portion is formed in
the groove by an electroforming method (see Japanese Patent Application Laid-open
No.
2006-259264).
[0008] In addition, there is disclosed a technique including the steps of patterning and
removing a photosensitive resin on a surface of a silicon substrate by a lithography
method, etching the silicon substrate, from which the photosensitive resin is removed,
by an ICP plasma etching method so as to form a slit groove, then depositing an insulator
material in the slit groove, further etching the remaining photosensitive resin and
the silicon substrate by the ICP plasma etching method so as to form a second slit
groove, and forming an X-ray absorbing metal portion in the second slit groove by
the electroforming method (see Japanese Patent Application Laid-open No.
2009-42528).
[0009] However, in the technique described in Japanese Patent Application Laid-open No.
2006-259264 or Japanese Patent Application Laid-open No.
2009-42528, the electroforming is performed in the fine groove (slit), and hence it is more
difficult to perform the electroforming securely as the aspect ratio of the groove
becomes higher. In addition, when a resist resin is used for forming the groove having
a high aspect ratio, there is a problem that it is difficult to manufacture the diffraction
grating with high accuracy because the resin is a soft insulator, which may be deformed
so that neighboring ridge portions come into contact with each other (sticking). Further,
in order to form the groove having a high aspect ratio, it is necessary to use synchrotron
radiation light so that exposure is performed by the X-ray having high linearity,
which largely increases manufacturing cost.
[0010] Therefore, an object of the present invention is to provide a diffraction grating
for an X-ray Talbot interferometer, a method of manufacturing the same, and an X-ray
Talbot interferometer, the method enabling easy and highly accurate manufacturing
of a diffraction grating having grooves with a high aspect ratio.
[0011] A diffraction grating for an X-ray Talbot interferometer according to an exemplary
embodiment of the present invention includes a plurality of ridge-like X-ray absorbing
portions formed on a substrate along one direction at predetermined intervals through
cutting of a metal film.
[0012] The period and the depth of the groove portions formed on the substrate in this way
depend on resolution and stability of a cutting machine. Therefore, when a superfine
nano machine that can realize a nanometer-level machining resolution and stability
is used, diffraction performance of the X-ray diffraction grating is improved. In
addition, the superfine nano machine is less expensive than a facility used in the
X-ray lithography and is not required to use the X-ray mask, and hence manufacturing
cost of the X-ray diffraction grating can be reduced.
[0013] In addition, a roughness of a side wall of the groove portion formed in the cutting
process and a radius of a round corner formed by the side wall and the bottom surface
of the groove portion (hereinafter referred to as "curvature radius of a cut corner
portion") depend on a shape of a cutting tool used for cutting. If a monocrystal diamond
cutting tool is used, a roughness and a round corner radius (curvature radius)of the
cutting blade can be 0.1 µm or smaller. As a result, diffraction performance of the
X-ray diffraction grating can be improved.
[0014] Further, the aspect ratio expressed by (depth of groove)/(width of groove) is preferably
three or larger. When the monocrystal diamond cutting tool having high hardness is
used for machining, the X-ray diffraction grating having a high aspect ratio can be
manufactured.
[0015] Note that, conventionally, the ridge is formed of a resist as a soft insulator, and
then the X-ray absorbing portion is formed by electroforming. Therefore, it is difficult
to form the X-ray absorbing portion precisely because the resist may be inclined or
come into contact with each other. However, in the present invention, the ridge portion
serving as the X-ray absorbing portion is formed by machining a metal as a conductor
having a higher Young's modulus than that of the resist by one order of magnitude.
Therefore, it is possible to form the X-ray absorbing portion precisely.
[0016] It is preferred that a width of each of the plurality of ridge-like X-ray absorbing
portions be the same as a width of each of groove portions, and the width of the each
of the plurality of ridge-like X-ray absorbing portions and the width of the each
of the groove portions be 4 µm or smaller.
[0017] The X-ray has a short wavelength and a small diffraction angle, and hence, in order
to obtain effective interference, it is necessary to set a large distance between
the X-ray source and the grating, a small period of the diffraction grating, and low
energy of the X-ray so that the wavelength becomes long. When each of the groove portion
and the ridge portion has a width of 4 µm or smaller, an effective interference image
can be obtained at a practical distance between the X-ray source and the grating (3
m or smaller) and practical X-ray energy (10 to 40 keV). In addition, when the groove
portion and the ridge portion have the same width, a phase image has the highest sharpness.
[0018] When a resin is interposed in a groove portion between neighboring X-ray absorbing
portions of the plurality of ridge-like X-ray absorbing portions, the X-ray absorbing
portions are not inclined or do not come into contact with each other.
[0019] According to an exemplary embodiment of the present invention, there is provided
a method of manufacturing a diffraction grating for an X-ray Talbot interferometer,
the method including: forming a metal film on a substrate; and cutting the metal film
along one direction in a predetermined period so as to form a plurality of groove
portions, to thereby form a ridge-like metal layer between neighboring groove portions
of the plurality of groove portions.
[0020] It is preferred that a material to be used for the substrate include at least one
element of carbon, silicon, and aluminum as a main component.
[0021] With the use of the above-mentioned material for the substrate, the X-ray transmittance
can be enhanced so that a diffraction characteristic can be improved.
[0022] It is preferred that the method further include forming an intermediate layer between
the substrate and the metal film, the intermediate layer having a smaller hardness
than the substrate and containing an element having a smaller effective atomic number
than an element contained in the metal film.
[0023] The substrate is usually harder than the metal film, and hence the cutting tool is
worn out when cutting the substrate. However, with the formation of the intermediate
layer between the metal film and the substrate, the metal film can be securely cut
by an amount corresponding to the thickness thereof so that a deep groove portion
can be formed. In addition, through cutting a part of the intermediate layer that
is softer than the substrate, it is possible to prevent the cutting tool from being
worn out.
[0024] In addition, the X-ray absorption and phase shift amounts depend on a thickness of
the metal film, and hence it is preferred that a cutting residue of the metal film
do not exist in the bottom of the groove portion. Here, as to a movement of the cutting
machine when machining a large number of grooves, the cutting tool is moved only in
the direction along the groove in one groove cutting, and a constant direction of
the depth of the groove is maintained so that the machining can be performed at high
speed. In this case, in order to eliminate the cutting residue of the metal film,
it is preferred that the substrate including the metal film and the intermediate layer
be flat. However, each film thickness and unevenness of the substrate when the substrate
is mounted to the cutting machine have a variation of a few microns or smaller each.
Therefore, the flatness of the substrate including the metal film and the intermediate
layer is set to be preferably 10 µm or smaller, and further the intermediate layer
is formed into a thickness equal to or larger than this flatness. Thus, the cutting
residue of the metal film does not remain, and it is possible to prevent the cutting
tool from being worn out by cutting the substrate. As the hardness, Vickers' hardness
can be adopted.
[0025] It is preferred that the resin include at least one of polyimide and a para-xylene
polymer because such a resin is superior in mechanical strength and has high durability
with respect to an X-ray, particularly in phase imaging.
[0026] It is preferred to fill the resin containing polyimide in the each of the plurality
of groove portions by a vacuum injection method because polyimide can flow into a
deep portion of the groove portion.
[0027] It is preferred to fill the para-xylene polymer in the each of the plurality of groove
portions by a vacuum vapor deposition method because the para-xylene polymer can flow
into the deep portion of the groove portion.
[0028] In the above-mentioned cutting, it is preferred to use a cutting tool having a cutting
blade made of monocrystal diamond because monocrystal diamond has high hardness and
enables precise machining of the groove.
[0029] An X-ray Talbot interferometer according to an exemplary embodiment of the present
invention uses the above-mentioned diffraction grating for an X-ray Talbot interferometer.
[0030] According to the present invention, the diffraction grating for an X-ray Talbot interferometer
having grooves with a high aspect ratio can be manufactured easily with high accuracy.
[0031] Embodiments of the present invention will now be described by way of further example
only and with reference to the accompanying drawings, in which:
FIG. 1 is a diagram illustrating a schematic structure of an X-ray Talbot interferometer
according to an embodiment of the present invention;
FIGS. 2A and 2B illustrate cross sections of a first diffraction grating and a second
diffraction grating, which are taken along an x direction;
FIG. 3 is a perspective view illustrating a structure of a diffraction grating for
the X-ray Talbot interferometer according to the embodiment of the present invention;
FIG. 4 is a perspective view illustrating a tool main body to which a monocrystal
diamond cutting tool is mounted;
FIG. 5 is a perspective view illustrating the monocrystal diamond cutting tool;
FIG. 6 is a plan view of the monocrystal diamond cutting tool viewed from the point
A of FIG. 5;
FIG. 7 is a diagram illustrating a method of forming each unit metal layer using the
monocrystal diamond cutting tool;
FIGS. 8A to 8D are a process charts illustrating an example of a method of manufacturing
the diffraction grating for the X-ray Talbot interferometer;
FIG. 9 is a diagram illustrating a schematic structure of a conventional X-ray Talbot
interferometer; and
FIGS. 10A and 10B illustrate cross sections of a first diffraction grating and a second
diffraction grating of a conventional X-ray Talbot interferometer, which are taken
along an x direction.
[0032] Hereinafter, an embodiment of the present invention is described. FIG. 1 is a diagram
illustrating a schematic structure of an X-ray Talbot interferometer 100 according
to the embodiment of the present invention. The X-ray Talbot interferometer 100 includes
an X-ray source 2, a first diffraction grating 10, a second diffraction grating 20,
and an X-ray image detector 30. The first diffraction grating 10 and the second diffraction
grating 20 are disposed in parallel with a predetermined distance therebetween in
a z direction. The X-ray source 2 is disposed to be opposed to the first diffraction
grating 10 along the z direction. In addition, the X-ray image detector 30 is disposed
to be opposed to the second diffraction grating 20 along the z direction. Further,
a sample 4 to be observed is disposed between the first diffraction grating 10 and
the X-ray source 2 along the z direction.
[0033] The first diffraction grating 10 and the second diffraction grating 20 have a plurality
of groove portions 10a and 20a that are formed to extend along one direction parallel
to a plane thereof (y direction in FIG. 1) and be spaced apart from one another in
a predetermined period (see the cross section of the groove portions of FIGS. 2A and
2B). The groove portions 10a and 20a transmit the X-ray, while a strip-like ridge
portion 10b between the neighboring groove portions 10a transmits the X-ray after
shifting the phase by π/2, and a ridge portion 20b blocks (absorbs) the X-ray. The
groove portions 10a and 20a, and the ridge portions 10b and 20b extend in the Y direction
of FIG. 1. As a material of the diffraction grating, it is preferred to use gold having
high X-ray absorbing power. Note that, in this embodiment, a width (interval) of the
ridge portion 10b and a width (interval) of the groove portion 10a are the same, and
a width (interval) of the ridge portion 20b and a width (interval) of the groove portion
20a are the same.
[0034] In the X-ray Talbot interferometer 100, when the X-ray is irradiated from the X-ray
source 2 to the first diffraction grating 10 via the sample 4, the X-ray transmitted
through the groove portion 10a interferes with the X-ray transmitted and diffracted
through the ridge portion 10b. Then, the self image having the same pattern as that
immediately after transmission is formed at a position separated by the Talbot distance.
In other words, the first diffraction grating 10 constitutes the phase diffraction
grating that performs phase modulation on the irradiated X-ray. Here, in order to
generate the Talbot effect, it is necessary to adjust the period d of the ridge portion
(X-ray absorbing portion) of the first diffraction grating 10 (see FIG. 2A) so as
to secure coherency of the X-ray irradiated from the X-ray source 2.
[0035] In addition, the second diffraction grating 20 disposed to the rear of the first
diffraction grating 10 (position of the self image) diffracts the X-ray diffracted
by the first diffraction grating 10 so as to form an image contrast, and the X-ray
image detector 30 disposed to the rear of the second diffraction grating 20 detects
the diffracted X-ray. In order to improve the image contrast, it is preferred that
the groove portion 20a of the second diffraction grating 20 have a high X-ray transmittance
and the ridge portion 20b have a low X-ray transmittance. Therefore, it is preferred
that the second diffraction grating 20 be an amplitude diffraction grating having
a larger thickness than the first diffraction grating 10.
[0036] Here, the sample 4 is disposed in front of the first diffraction grating 10 and the
irradiated X-ray passes through the sample 4 in a slightly different light path, and
hence a manner of an interference pattern varies in accordance with the phase difference
at this time. Therefore, the self image is deformed. When the second diffraction grating
20 is overlaid at a position of the self image, a moire fringe is generated in a Talbot
interference image (image contrast), which is detected by the X-ray image detector
30. An amount of modulation of the generated moire fringe by the sample 4 is proportional
to an angle of bending of the irradiated X-ray by the sample 4. Therefore, through
analysis of the moire fringe, the sample 4 and an internal structure thereof can be
measured.
[0037] Note that, a fringe scan method as one of analyzing methods of the moire fringe focuses
attention on the fact that a phase of the moire fringe is changed by shifting the
first diffraction grating 10 and the second diffraction grating 20 relatively in the
X direction. In other words, the phase of the moire fringe is changed so as to obtain
a plurality of Talbot interference images, and then the plurality of Talbot interference
images are combined by an integral process. Thus, the phase image (the sample 4 and
the internal structure thereof) can be obtained.
[0038] In addition, it is also possible to obtain a tomographic image (CT image) of the
sample 4 by rotating the sample 4 so as to obtain differential phase images from many
irradiation directions, and by combining the differential phase images by the integral
process or the like.
[0039] Note that, the X-ray Talbot interferometer 100 of the present invention includes
a Talbot-Lau interferometer in which a multi-slit is disposed between the X-ray source
2 and the sample 4. When the multi-slit is not used, it is necessary to use a microfocus
X-ray source as the X-ray source 2. In contrast, a usual X-ray source can be used
in the Talbot-Lau interferometer.
[0040] The X-ray has a short wavelength, and hence, in order to secure coherency, the thickness
of the ridge portion of the first diffraction grating 10 and the second diffraction
grating 20 is required to be approximately 10 µm or smaller. Further, in the phase
diffraction grating, the contrast of the self image becomes highest when a phase shift
amount becomes π/2. Therefore, in order to realize this, it is necessary to set the
thickness of the ridge portion (depth of the groove) at approximately 1 to 10 µm,
and fine machining and manufacturing techniques are required. For instance, when the
ridge portion of each diffraction grating is formed of gold, it is necessary to set
the thickness of the ridge portion to approximately 1 to 3 µm. When the ridge portion
is formed of copper, it is necessary to set the thickness of the ridge portion to
approximately 3 to 10 µm.
[0041] On the other hand, in order to function as the amplitude diffraction grating, it
is necessary to set a high X-ray transmittance of the groove portion of the diffraction
grating and to set a low X-ray transmittance of the ridge portion. Therefore, it is
required to set the thickness of the ridge portion (depth of the groove) to a large
value of approximately 10 to 100 µm even when gold is used. Therefore, the aspect
ratio expressed by (depth of groove)/(width of groove) of the diffraction grating
becomes quite as large as three or larger (ten or larger in some cases).
[0042] For this reason, it is necessary to form the X-ray absorbing portion (ridge portion)
finely and to form a shape of the side wall thereof to be sharp (in other words, clearly
defined such that a roughness of the side wall of the groove and a radius of a round
corner formed by the side wall and the bottom surface (curvature radius of a cut corner
portion) are fine). The inventors of the present invention found that a fine X-ray
absorbing portion (groove portion) having the side wall with a sharp shape can be
formed by cutting a metal film using, for example, a monocrystal diamond cutting tool
that has a high hardness and enables precise machining of the groove.
[0043] FIG. 3 illustrates a structure of the diffraction grating 20 for the X-ray Talbot
interferometer according to the embodiment of the present invention. The diffraction
grating 20 for the X-ray Talbot interferometer is the second diffraction grating (amplitude
diffraction grating) 20 described above with reference to FIG. 1, and the aspect ratio
expressed by (depth of groove)/(width of groove) is preferably three or higher. Note
that, the present invention can be applied also to the first diffraction grating 10
as the phase diffraction grating, but is preferably applied at least to the above-mentioned
amplitude diffraction grating having a high aspect ratio.
[0044] The diffraction grating 20 for the X-ray Talbot interferometer includes a substrate
22, a plurality of ridge-like X-ray absorbing portions 20b which are made of a metal
and formed on the substrate 22 along one direction at predetermined intervals, and
a resin 26 interposed in the groove portion 20a between the neighboring X-ray absorbing
portions. The X-ray absorbing portion 20b is formed by cutting a metal film (described
later). It is preferred that a roughness of a side wall 20s of the X-ray absorbing
portion 20b and a curvature radius of a cut corner portion formed by the side wall
20s and the bottom of the groove portion be 0.1 µm or smaller each. Preferably, the
roughness of the side wall 20s has an arithmetical mean height Ra of 0.1 µm or smaller,
as defined in JIS B0601. Preferably, the plurality of ridge-like X-ray absorbing portions
20b contain gold as a main component and are formed of one of crystals each having
an average grain diameter of 0.1 µm or smaller and amorphous gold. Note that, the
roughness of the side wall, squareness, and straightness mostly depend on a shape
of the cutting tool. Accuracy of a moving mechanism of a superfine nano machine described
later is higher than roughness of the surface of the cutting tool.
[0045] In addition, an intermediate layer 24 is interposed between the X-ray absorbing portion
20b and the substrate 22.
[0046] It is preferred that the substrate 22 be made of a material having at least one main
component selected from the group consisting of carbon, silicon, and aluminum, for
example, in order to increase the X-ray transmittance. As a specific example of composition
of the substrate 22, there is an amorphous carbon wafer or a silicon wafer, a silicon
nitride membrane or a silicon carbide membrane, a 3000-series aluminum sheet, an aluminum-magnesium
alloy sheet, or the like, for example.
[0047] With the use of the above-mentioned material as the substrate 22, the X-ray transmittance
can be enhanced so that a good diffraction characteristic can be obtained. In addition,
the X-ray absorption and phase shift amounts depend on a thickness of the metal film,
and hence it is preferred that a cutting residue of the metal film does not exist
in the bottom of the groove portion. Here, as to a movement of the cutting machine
when machining a large number of grooves, the cutting tool is moved only in the direction
along the groove in one groove cutting operation, and a constant direction of the
depth of the groove is maintained so that the machining can be performed at high speed.
In this case, in order to eliminate the cutting residue of the metal film, it is preferred
that the substrate including the metal film and the intermediate layer be flat. However,
both film thickness and unevenness of the substrate when the substrate is mounted
to the cutting machine have a variation of a few microns or smaller each. Therefore,
the flatness of the substrate including the metal film and the intermediate layer
is set to be preferably 10 µm or smaller, and further the intermediate layer is formed
into a thickness equal to or larger than this flatness. Thus, it is possible to prevent
the cutting residue of the metal film from remaining, and to prevent the cutting tool
from being worn out by cutting the substrate.
[0048] The intermediate layer 24 contains an element having a lower hardness (Vickers' hardness)
than that of the substrate and a smaller effective atomic number than that of the
metal film (the metal film serving as the X-ray absorbing portion 20b). This element
may be a light element that is soft and easily transmits the X-ray, such as a metal
(for example, aluminum). The intermediate layer 24 may be a resin. The intermediate
layer 24 prevents the cutting tool from cutting the substrate 22 through excessive
cutting when the metal film on the substrate 22 is cut so as to form the X-ray absorbing
portion 20b. The substrate 22 is usually harder than the metal film, and hence the
cutting tool is worn out by cutting the substrate 22. However, with the formation
of the intermediate layer 24 between the metal film and the substrate 22, the metal
film can be securely cut by an amount corresponding to the thickness thereof to form
the deep groove portion. In addition, a part of the intermediate layer 24 softer than
the substrate 22 is cut to prevent the cutting tool from being worn out. Note that,
the intermediate layer itself has small X-ray absorption and phase change, and hence
there is no problem even in a case where a part of the intermediate layer 24 is cut
when forming the X-ray absorbing portion 20b.
[0049] The intermediate layer 24 may be an aluminum layer or a multilayer film including
an aluminum layer. However, the intermediate layer 24 is not an essential structure.
[0050] The X-ray absorbing portion 20b can be formed by cutting a metal film containing
gold as a main component, for example, a pure gold plating film, or a film of gold-nickel
alloy plating or gold-nickel-tungsten alloy plating containing 90% or higher weight
ratio of gold, which efficiently absorbs the X-ray so that a characteristic of the
diffraction grating is improved. Note that, the metal film includes not only a pure
metal but also an alloy as described above.
[0051] The resin 26 is filled in the groove after the groove portion is formed so as to
hold the X-ray absorbing portion 20b and prevent the X-ray absorbing portion 20b from
being inclined or deformed. In particular, it is preferred to use at least one of
polyimide and a para-xylene polymer as the resin 26 because such a material is superior
in mechanical strength and has high durability with respect to an X-ray, particularly
in phase imaging. As the para-xylene polymer, there is a polymer in which a part or
a whole of hydrogen of the benzene ring of the para-xylene polymer or para-xylene
is substituted with chlorine, or a polymer in which α-hydrogen atoms of para-xylene
are substituted with fluorine, and parylene N, parylene C, parylene D, and parylene
HT (all of which are registered trademarks) are commercially available.
[0052] Next, with reference to FIGS. 4 to 7, the cutting tool, which has a cutting blade
made of monocrystal diamond and is suitable for cutting the metal film to form the
X-ray absorbing portion 20b, is described. The monocrystal diamond has high hardness
and enables precise machining of the groove.
[0053] FIG. 4 illustrates a tool main body (cutter) 400 to which a monocrystal diamond cutting
tool 200 is mounted. The monocrystal diamond cutting tool 200 is mounted to a tip
of a base metal 300 having a substantially trapezoidal shape so as to constitute the
tool main body 400. The cutting blade of the monocrystal diamond cutting tool 200
(see FIG. 5) protrudes from the tip of the base metal 300. The tool main body 400
is fixed to a holder of the cutting machine (not shown), and the monocrystal diamond
cutting tool 200 can cut an object to be cut to form the groove therein as described
later.
[0054] As illustrated in FIG. 5, the monocrystal diamond cutting tool 200 has a rake surface
201, two first flanks 203 and 204 that are side surfaces each adjacent to the rake
surface 201, a front flank 205 that is adjacent to the rake surface 201 and is opposed
to a cutting surface of an object to be cut, a front cutting blade 210 formed at a
boundary between the rake surface 201 and the front flank 205, and two first cutting
blades 213 and 214 formed at a boundary between the rake surface 201 and the first
flank 203 and between the rake surface 201 and the first flank 204. Shapes of the
front flank 205 and the rake surface 201 are not limited, and the shapes may be a
flat surface or a curved surface. The rake surface 201 has a predetermined rake angle
of zero degrees or a rake angle slightly inclined in a positive direction so as to
scoop cutting waste.
[0055] The first flank 203, 204 or the front flank 205 is formed by etching with a focused
ion beam (FIB). The etching with the FIB enables machining of a complicated shape,
and has an advantage that any crystal surface can be machined. Therefore, even a (111)
plane of diamond that is the hardest crystal plane can be easily machined. In contrast,
in a case of polishing with a grindstone, for example, the (111) plane of diamond
cannot be polished.
[0056] It is preferred to set a width W1 of the front cutting blade 210 to 4 µm or smaller
because a fine groove portion suitable for the diffraction grating for the X-ray Talbot
interferometer can be formed.
[0057] FIG. 6 is a plan view of the monocrystal diamond cutting tool 200 viewed from the
point A of FIG. 5. An interval W2 between the first flanks 203 and 204 is equal to
or smaller than the width W1 of the front cutting blade 210. In other words, a part
satisfying W2≤W1 constitutes the first flanks 203 and 204, and a width of a part on
a rear end side of the first flanks 203 and 204 (part opposite to the front cutting
blade 210) is larger than W2 so as to secure the strength. In addition, if W2≤W1 is
satisfied, a contact area between the monocrystal diamond cutting tool 200 and the
object to be cut is reduced in the cutting process, and hence the tool is less liable
to chatter vibration so that precise cutting process can be performed. In particular,
as illustrated in FIG. 6, in case where a length L of the first flanks 203 and 204
from the front cutting blade 210 is set three times or more as large as the width
W1 of the front cutting blade and the deep groove is formed through cutting, when
W2≤W1 is satisfied, the effect of reducing the contact area (friction) with the object
to be cut is increased.
[0058] Note that, in this embodiment, the part extending in parallel at the width W1 from
the front cutting blade 210 toward the rear end constitutes the first cutting blades
213 and 214, and the first cutting blades 213 and 214 are formed only in the vicinity
of the front cutting blade 210.
[0059] The monocrystal diamond cutting tool 200 (tool main body 400) described above is
mounted to the cutting machine, and can form the groove portion 20a as illustrated
in FIG. 7. Here, the period and the depth of the groove portions formed through cutting
depend on a resolution of the superfine nano machine, and hence it is preferred to
use the superfine nano machine having a nanometer-level resolution as the cutting
machine. As the superfine nano machine, FANUC ROBONANO α-0iB manufactured by FANUC
CORPORATION, for example, is commercially available. This superfine nano machine has
a resolution of 1 nm in a linear axis by controlling a linear motor and a synchronous
built-in servomotor so that five axes are directly driven simultaneously with high
accuracy.
[0060] Using such a machine, as illustrated in FIG. 7, the monocrystal diamond cutting tool
200 performs a drag cutting process on a metal film 20x along one direction (an arrow
direction in FIG. 7) leaving the ridges having a predetermined width W3 in the direction
perpendicular to the one direction. Thus, the metal film 20x is cut to form the groove
portions 20a, and the ridge-like X-ray absorbing portion 20b can be formed between
the neighboring groove portions 20a. Note that, it is preferred that W1 =W3 be satisfied.
[0061] Here, the monocrystal diamond cutting tool 200 cuts the metal film 20x to form the
groove portion 20a, and hence it is possible to perform appropriate machining, in
which the roughness of side surfaces of the groove portion and the curvature radius
of the cut corner portion formed by the side surface and the bottom surface of the
groove portion are 0.1 µm or smaller each. Compared with the conventional technique
in which electroforming is performed in the fine groove (slit) formed using a resist
resin to manufacture the diffraction grating, a high precision diffraction grating
can be obtained.
[0062] In addition, the width of the groove portion 20a is the same as the width W1 of the
front cutting blade 210, and a depth L of the groove portion 20a to be formed through
cutting is up to a vertical length of the first flanks 203 and 204. In this case,
in order to manufacture the second diffraction grating (amplitude diffraction grating)
illustrated in FIG. 1, it is necessary to set the aspect ratio expressed by (depth
of groove)/(width of groove) to a high value (for example, three or higher). Therefore,
with use of the monocrystal diamond cutting tool having high hardness, even when the
cutting tool is elongated so that L/W1 becomes three or larger, the metal film can
be cut sufficiently deeply. In particular, when the monocrystal diamond cutting tool
satisfying W2≤W1 is used as described above, the contact area (friction) with the
object to be cut is reduced so that the groove portion 20a having a high aspect ratio
can be securely formed through cutting.
[0063] Next, with reference to FIGS. 8A to 8D, an example of a method of manufacturing the
diffraction grating 20 for the X-ray Talbot interferometer is described.
[0064] First, the intermediate layer 24 is formed on the silicon wafer substrate 22 as necessary,
and then a metal film 20bx is formed on the intermediate layer 24 (FIG. 8A; metal
film forming step). As the intermediate layer 24, an aluminum film is formed by ion
plating or sputtering vapor deposition. When the intermediate layer 24 is formed of
copper, electric copper plating is used. A thin chromium vapor deposition film may
be formed between the substrate 22 and the intermediate layer 24 for securing adhesiveness
of the intermediate layer. As the metal film 20bx, a gold film is formed by electric
plating. In order to secure adhesiveness of the metal film 20bx, it is possible to
form a thin gold film on the surface of the intermediate layer 24 by vapor deposition,
and then to perform electric plating of gold.
[0065] Next, with use of the above-mentioned monocrystal diamond cutting tool 200, the metal
film 20bx is cut along one direction (direction perpendicular to the drawing sheet
of FIGS. 8A to 8D) at predetermined intervals so that the plurality of groove portions
20a are formed, and the ridge-like X-ray absorbing portion 20b is formed between the
neighboring groove portions 20a (FIG. 8B; cutting step). The cutting allowance in
the cutting depth direction is set to approximately 0.3 to 1 µm, and the cutting is
performed a plurality of times so that the groove portions 20a having a predetermined
depth are formed.
[0066] Then, if necessary, an uncured resin 26x is filled in the groove portion 20a (FIG.
8C; resin filling step). Here, the uncured resin 26x fills the groove portion 20a
and also covers the surface of the X-ray absorbing portion 20b.
[0067] As described above, it is preferred to use at least one or both of polyimide and
a para-xylene polymer as the uncured resin 26x. When polyimide is used, it is preferred
to fill polyimide in the groove portion 20a by the vacuum injection method because
polyimide can flow into a deep portion of the groove portion 20a. In addition, when
the para-xylene polymer is used, it is preferred to fill the para-xylene polymer in
the groove portion 20a by the vacuum vapor deposition method because the para-xylene
polymer can be deposited in the deep portion of the groove portion 20a.
[0068] Note that, the vacuum injection method is a method in which the substrate 22 having
the groove portions 20a is disposed in a system maintained in vacuum, and low molecular
weight polyimide is supplied to the system to flow into the groove portion 20a and
then is polymerized by ultraviolet rays or heat to cause a crosslinking reaction.
[0069] In addition, when the para-xylene polymer is filled by the vacuum vapor deposition,
a dimer of para-xylene is heated to approximately 175°C to evaporate in the vacuum.
After that, the vapor of the para-xylene dimer is heated to approximately 680°C to
be thermally decomposed substances. When the thermally decomposed substances of para-xylene
reaches the surface of the groove portion 20a or the X-ray absorbing portion 20b,
the thermally decomposed substances are reacted with each other into a stable vapor
deposition film.
[0070] The surface of the polymerized and cured resin 26x is ground or ashed so that the
upper surface of the X-ray absorbing portion 20b is exposed to be flushed with the
resin 26 (FIG. 8D). In the grinding process, for example, a fine grindstone is moved
to slide in the same direction as cutting of the groove 20a so that the resin pushed
out from the upper part is ground off. In addition, the ashing can be performed by
using a known ashing apparatus (technique) used in semiconductor technology, and for
example, photo excited ashing and plasma ashing can be used.
[0071] It should be understood that the present invention is not limited to the embodiment
described above, and that the present invention incorporates various modifications
within the scope of the present invention.
1. A diffraction grating (20) for an X-ray Talbot interferometer (100), comprising a
plurality of ridge-like X-ray absorbing portions (20b) formed on a substrate (22)
along one direction at predetermined intervals through cutting of a metal film (20bx).
2. A diffraction grating for an X-ray Talbot interferometer according to claim 1, wherein
a width of each of the plurality of ridge-like X-ray absorbing portions (22b) is the
same as a width (W3) of each of groove portions (20a) as cut portions of the metal
film, and the width of the each of the plurality of ridge-like X-ray absorbing portions
(20b) and the width of the each of the groove portions are 4 µm or smaller.
3. A diffraction grating for an X-ray Talbot interferometer according to claim 1 or claim
2, wherein a resin (26) is interposed in a groove portion (20a) between neighboring
X-ray absorbing portions (20b) of the plurality of ridge-like X-ray absorbing portions.
4. A diffraction grating for an X-ray Talbot interferometer according to any one of the
preceding claims, further comprising an intermediate layer (24) between the substrate
and the metal film, the intermediate layer having a smaller hardness than the substrate
and containing an element having a smaller effective atomic number than an element
contained in the metal film.
5. A method of manufacturing a diffraction grating (20) for an X-ray Talbot interferometer
(100), the method comprising:
forming a metal film (20bx) on a substrate (22); and
cutting the metal film along one direction in a predetermined period so as to form
a plurality of groove portions (20a), to thereby form a ridge-like metal layer (20b)
between neighboring groove portions of the plurality of groove portions.
6. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to claim 5, wherein a material to be used for the substrate (22) comprises
at least one element of carbon, silicon, and aluminum as a main component.
7. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to claim 5 or claim 6, further comprising forming an intermediate layer
(24) between the substrate and the metal film, the intermediate layer having a smaller
hardness than the substrate and containing an element having a smaller effective atomic
number than an element contained in the metal film.
8. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to any one of claims 5 to 7, further comprising filling a resin (26) in
each of the plurality of groove portions (20a).
9. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to claim 8, wherein the resin (26) comprises at least one of polyimide and
a para-xylene polymer.
10. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to claim 9, wherein the filling comprises filling the resin containing polyimide
in the each of the plurality of groove portions by a vacuum injection method.
11. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to claim 9 or claim 10, wherein the filling comprises filling the para-xylene
polymer in the each of the plurality of groove portions by a vacuum vapor deposition
method.
12. A method of manufacturing a diffraction grating for an X-ray Talbot interferometer
according to any one of claims 5 to 11, wherein the cutting comprises cutting using
a cutting tool (200) having a cutting blade made of monocrystal diamond.
13. An X-ray Talbot interferometer, comprising a diffraction grating for an X-ray Talbot
interferometer according to any one of claims 1 to 4