JP6203558B2 - Surface-enhanced Raman scattering element and manufacturing method thereof - Google Patents

Description

  The present invention relates to a surface-enhanced Raman scattering element and a method for manufacturing the same.

As a conventional surface-enhanced Raman scattering element, a device including a minute metal structure that causes surface enhanced Raman scattering (SERS) is known (see, for example, Patent Document 1 and Non-Patent Document 1). In such a surface-enhanced Raman scattering element, when a sample to be subjected to Raman spectroscopic analysis is brought into contact with a fine metal structure and the sample is irradiated with excitation light in this state, surface-enhanced Raman scattering occurs, For example, Raman scattered light enhanced to about 10 ⁸ times is emitted.

  Incidentally, for example, Patent Document 2 discloses that each of one surface of a substrate and the top surfaces of a plurality of microprojections formed on one surface of the substrate (or the bottom surfaces of a plurality of micro holes formed on one surface of the substrate). A micro metal structure in which a metal layer is formed so as to be in a non-contact state (so that the distance between the shortest portions is about 5 nm to 10 μm) is described.

JP 2011-33518 A JP 2009-222507 A

“Q-SERSTM G1 Substrate”, [online], OptScience, Inc. [searched July 5, 2013], Internet <URL: http: //www.optoscience.com/maker/nanova/pdf/Q- SERS_G1.pdf>

  As described above, when a so-called nanogap is formed in the fine metal structure, local electric field enhancement occurs when the excitation light is irradiated, and the intensity of surface enhanced Raman scattering is increased.

  Further, in the Raman spectroscopic analysis method described in Patent Document 1, it is desirable that the fine metal structure that exhibits the SERS effect does not easily peel off from the substrate and the shape is stable.

  Accordingly, an object of the present invention is to provide a surface-enhanced Raman scattering element that can increase the intensity of surface-enhanced Raman scattering by a suitable nanogap, and a method for manufacturing such a surface-enhanced Raman scattering element.

  The surface-enhanced Raman scattering element of the present invention is formed on a main surface, a fine structure portion formed on the main surface and having a plurality of convex portions, and formed on the fine structure portion, thereby generating surface-enhanced Raman scattering. A conductor layer that constitutes an optical function unit, and the conductor layer includes a base part formed along the main surface, and a plurality of projecting parts projecting from the base part at positions corresponding to the convex parts, respectively. And the thickness of the base part is larger than the height of the convex part.

  In this surface-enhanced Raman scattering element, the thickness of the base portion of the conductor layer is larger than the height of the convex portion of the fine structure portion. Therefore, compared with the case where there is no convex portion, the contact area is increased, so that the base portion is hardly peeled off from the fine structure portion, and the shape of the base portion is stabilized. Furthermore, since the protrusion of the fine structure does not exist in the protruding portion of the conductor layer from the base portion, the protruding portion is not easily affected by the deformation of the protruding portion due to thermal expansion and contraction. The shape is stabilized. Therefore, the gap formed in the conductor layer by the base portion and the protruding portion suitably functions as a nanogap in which local electric field enhancement occurs. Therefore, according to this surface-enhanced Raman scattering element, the intensity of surface-enhanced Raman scattering can be increased by a suitable nanogap.

  In the surface-enhanced Raman scattering element of the present invention, the convex portions may be periodically arranged along the main surface. According to this configuration, the intensity of surface enhanced Raman scattering can be increased.

  In the surface-enhanced Raman scattering element of the present invention, the conductor layer has a plurality of gaps by the base portion and the protruding portion so as to surround each of the protruding portions when viewed from the direction in which the protruding portions protrude. It may be formed. According to this structure, the gap which functions suitably as a nano gap can be increased.

  The method of manufacturing a surface-enhanced Raman scattering element according to the present invention includes a first step of preparing a substrate having a main surface on which a microstructure having a plurality of convex portions is formed, and surface-enhanced Raman scattering after the first step. The conductor layer constituting the optical function part to be generated has a base part formed along the main surface and a plurality of protrusions protruding from the base part at positions corresponding to the respective protrusions. A second step of forming on the fine structure portion, and in the second step, the conductor is vapor-phase grown so that the thickness of the base portion is larger than the height of the convex portion, thereby Form a layer.

  According to this method for manufacturing a surface-enhanced Raman scattering element, a surface-enhanced Raman scattering element having a suitable nanogap as described above can be manufactured.

  In the method for manufacturing the surface-enhanced Raman scattering element of the present invention, in the second step, the thickness of the protruding portion may be adjusted according to the thickness of the base portion. Since the thickness of the protruding portion can be increased as the thickness of the base portion is increased, the ratio between the thickness of the protruding portion and the interval between adjacent protruding portions is independent of the pitch of the protruding portion of the fine structure portion. Can be set to a desired value.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the surface enhancement Raman scattering element which can increase the intensity | strength of surface enhancement Raman scattering with a suitable nanogap, and the manufacturing method of such a surface enhancement Raman scattering element.

It is a top view of the surface enhancement Raman scattering unit to which the surface enhancement Raman scattering element of one embodiment of the present invention was applied. It is sectional drawing along II-II of the surface enhancement Raman scattering unit of FIG. It is a bottom view of the surface enhancement Raman scattering unit of FIG. It is a partially expanded sectional view along II-II of the surface enhancement Raman scattering unit of FIG. It is a partial expanded sectional view of the surface enhancement Raman scattering element of the surface enhancement Raman scattering unit of FIG. It is a block diagram of the Raman spectroscopic analyzer in which the surface enhancement Raman scattering unit of FIG. 1 was set. It is sectional drawing which shows the process of the manufacturing method of the surface enhancement Raman scattering element of FIG. It is sectional drawing which shows the process of the manufacturing method of the surface enhancement Raman scattering element of FIG. It is sectional drawing which shows the process of the manufacturing method of the surface enhancement Raman scattering element of FIG. 2 is a SEM photograph of the microstructure of the surface-enhanced Raman scattering element of Example 1. 2 is a SEM photograph of a cross section of an optical function part of the surface-enhanced Raman scattering element of Example 1. 4 is a SEM photograph of an optical function part of a surface-enhanced Raman scattering element of Example 2. 6 is a graph showing the relationship between Stokes shift and signal intensity for the surface-enhanced Raman scattering element of Example 2.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. In addition, in each figure, the same code | symbol is attached | subjected to the same or an equivalent part, and the overlapping description is abbreviate | omitted.

  As shown in FIGS. 1 and 2, the SERS unit (surface enhanced Raman scattering unit) 1 includes a SERS element (surface enhanced Raman scattering element) 2, a measurement substrate 3 that supports the SERS element 2 during measurement, and SERS. And a holding unit 4 that mechanically holds the element 2 on the measurement substrate 3. Note that “mechanically” means “by fitting members together without using an adhesive or the like”.

  The surface 3 a of the measurement substrate 3 is provided with a recess 5 that accommodates the SERS element 2 and the holding unit 4. On the other hand, as shown in FIGS. 2 and 3, wall portions 6 and 7 extending in a direction perpendicular to the thickness direction of the measurement substrate 3 are formed on the back surface 3 b of the measurement substrate 3. A plurality of lightening portions 8 are provided. As an example, the wall portion 6 is formed in an annular shape along the outer edge of the measurement substrate 3, and the wall portion 7 is formed in a lattice shape inside the wall portion 6. The measurement substrate 3 is formed in a rectangular plate shape. The recessed part 5 and each lightening part 8 are formed in a rectangular parallelepiped shape. Such a measurement substrate 3 is made of a material such as resin (polypropylene, styrene resin, ABS resin, polyethylene, PET, PMMA, silicone, liquid crystal polymer, etc.), ceramic, glass, silicon, etc. It is formed integrally using.

  As shown in FIG. 4, the SERS element 2 includes a substrate 21, a molding layer 22 formed on the substrate 21, and a conductor layer 23 formed on the molding layer 22. As an example, the substrate 21 is formed in a rectangular plate shape with silicon or glass or the like, and has an outer shape of about several hundred μm × several hundred μm to several tens of mm × several tens mm and a thickness of about 100 μm to 2 mm. ing.

  The molding layer 22 includes a fine structure portion 24, a support portion 25, and a frame portion 26. The fine structure portion 24 is a region having a periodic pattern formed on the surface layer on the opposite side of the substrate 21 in the central portion of the molding layer 22, and is formed on the surface (main surface) 21 a of the substrate 21 via the support portion 25. Is formed. The support portion 25 is a region that supports the fine structure portion 24 and is formed on the surface 21 a of the substrate 21. The frame portion 26 is an annular region that surrounds the support portion 25, and is formed on the surface 21 a of the substrate 21.

  As an example, the fine structure 24 has a rectangular outer shape of about several hundred μm × several hundred μm to several tens mm × several tens mm when viewed from one side in the thickness direction of the measurement substrate 3. doing. In the fine structure portion 24, a plurality of pillars having a thickness and height of about several nanometers to several hundreds of nanometers have a periodic pattern of several tens of nanometers to several hundreds nanometers along the surface 21a of the substrate 21. They are arranged periodically at a pitch. The support part 25 and the frame part 26 have a thickness of about several tens of nanometers to several tens of micrometers. Such a molding layer 22 is made by, for example, nanoimprinting a resin (acrylic, fluorine-based, epoxy-based, silicone-based, urethane-based, PET, polycarbonate, inorganic organic hybrid material, or the like) or low-melting glass disposed on the substrate 21. It is integrally formed by molding by the method.

  The conductor layer 23 is integrally formed on the fine structure portion 24 and the frame portion 26. In the fine structure portion 24, the conductor layer 23 reaches the surface of the support portion 25 exposed on the opposite side of the substrate 21. In the SERS element 2, the optical functional unit 20 that causes surface-enhanced Raman scattering is formed by the conductor layer 23 formed on the surface of the microstructure portion 24 and on the surface of the support portion 25 exposed on the opposite side of the substrate 21. It is configured. As an example, the conductor layer 23 has a thickness of about several nm to several μm. Such a conductor layer 23 is formed, for example, by vapor-depositing a conductor such as metal (Au, Ag, Al, Cu, Pt, etc.) on the molding layer 22 molded by the nanoimprint method.

  The bottom surface 5a of the recess 5 is provided with a recess 9 that accommodates a part of the SERS element 2 on the substrate 21 side. The recess 9 is formed in a shape having a complementary relationship with a part of the SERS element 2 on the substrate 21 side, and restricts the movement of the SERS element 2 in the direction perpendicular to the thickness direction of the substrate 21. Note that the SERS element 2 is not fixed to the inner surface of the recess 9 by an adhesive or the like, but only contacts the inner surface of the recess 9.

  The holding part 4 has a holding part 41 formed in an annular shape so as to surround the optical function part 20 when viewed from the thickness direction of the board 21, and extends from the holding part 41 to the back surface 3 b side of the measurement substrate 3. And a plurality of leg portions 42. On the bottom surface 5a of the recess 5, fitting holes 11 are provided so as to correspond to the leg portions 42, respectively. Each leg portion 42 is fitted in each fitting hole 11 in a state where the sandwiching portion 41 surrounds the optical function portion 20 and is in contact with the conductor layer 23 of the SERS element 2. As described above, the holding unit 4 formed separately from the measurement substrate 3 is mechanically fixed to the measurement substrate 3, and the SERS element 2 disposed in the recess 9 holds the measurement substrate 3. It is clamped by the clamping part 41 of the part 4. Thereby, the SERS element 2 is mechanically held with respect to the measurement substrate 3. The fitting hole 11 has a bottom and does not penetrate the measurement substrate 3.

  As an example, the clamping part 41 is formed so that the outer edge is rectangular and the inner edge is circular when viewed from the thickness direction of the substrate 21, and the leg part 42 has four corners of the clamping part 41. Each of the portions extends to the back surface 3b side of the measurement substrate 3. Since the inner edge of the clamping part 41 is circular, the action of local pressing force on the SERS element 2 is avoided. The leg part 42 and the fitting hole 11 are formed in the column shape. The holding part 4 having such a sandwiching part 41 and leg part 42 is made of a material such as resin (polypropylene, styrene resin, ABS resin, polyethylene, PET, PMMA, silicone, liquid crystal polymer, etc.), ceramic, glass, silicon, etc. It is integrally formed using techniques such as molding, cutting, and etching.

  Furthermore, the SERS unit 1 includes a cover 12 having light transparency. The cover 12 is disposed in the widened portion 13 provided in the opening of the recess 5 and covers the opening of the recess 5. The widened portion 13 is formed in a shape having a complementary relationship with the cover 12, and restricts the movement of the cover 12 in the direction perpendicular to the thickness direction of the cover 12. The surface 41 a of the holding part 41 of the holding part 4 is substantially flush with the bottom surface 13 a of the widened part 13. As a result, the cover 12 is supported not only by the measurement substrate 3 but also by the holding unit 4. As an example, the cover 12 is formed in a rectangular plate shape by glass or the like, and has an outer shape of about 18 mm × 18 mm and a thickness of about 0.15 mm. As shown in FIGS. 1 and 2, the temporary fixing film 14 is attached to the measurement substrate 3 so as to cover the cover 12 before the SERS unit 1 is used. The cover 12 is prevented from falling off.

  The configuration of the optical function unit 20 of the SERS element 2 described above will be described in more detail. As shown in FIG. 5, the fine structure portion 24 has a plurality of pillars (convex portions) 27 periodically arranged along the surface 21 a of the substrate 21. As an example, the pillar 27 is formed in a cylindrical shape having a thickness and a height of about several nanometers to several hundreds of nanometers, and about several tens of nanometers to several hundreds of nanometers (preferably, along the surface 21a of the substrate 21). , 250 nm to 800 nm).

  The conductor layer 23 includes a base portion 28 formed along the surface 21 a of the substrate 21, and a plurality of protruding portions 29 that protrude from the base portion 28 at positions corresponding to the pillars 27. The base portion 28 is formed in layers on the surface 25 a of the support portion 25. The thickness of the base portion 28 is about several nm to several hundred nm, and is larger than the height of the pillar 27. The protruding portion 29 is formed so as to cover each pillar 27 and has a shape constricted at least at the end portion on the substrate 21 side. In each protruding portion 29, at least an end portion (a portion located on the top portion 27 a of the pillar 27) 29 a on the opposite side of the substrate 21 protrudes from the base portion 28. In order to stably form such a structure, the thickness of the base portion 28 is preferably not more than 10 times the height of the pillar 27, and more preferably not more than 5 times the height of the pillar 27. preferable.

  In the conductor layer 23, a plurality of gaps G opened on the opposite side of the substrate 21 are formed by the base portion 28 and the protruding portion 29. The gap G is formed so as to surround each pillar 27 when viewed from the direction in which the pillar 27 protrudes (that is, the thickness direction of the substrate 21). As an example, the gap G is formed in a groove shape extending in an annular shape surrounding each pillar 27 when viewed from the direction in which the pillar 27 protrudes, and has a width of about 0 to several tens of nm. Yes. The base portion 28 and the protruding portion 29 may be connected at the deepest portion of the gap G or may be separated at the deepest portion of the gap G.

  A Raman spectroscopic analysis method using the SERS unit 1 configured as described above will be described. Here, as shown in FIG. 6, a stage 51 that supports the SERS unit 1, a light source 52 that emits excitation light, and collimation, filtering, and light collection necessary for irradiating the optical function unit 20 with the excitation light. Etc., an optical component 54 for performing collimation, filtering and the like necessary for guiding the Raman scattered light to the detector 55, and a detector 55 for detecting the Raman scattered light. At 50, a Raman spectroscopy method is performed.

  First, the SERS unit 1 is prepared, the temporary fixing film 14 is peeled off from the measurement substrate 3, and the cover 12 is removed from the measurement substrate 3. Then, a solution sample (or a powder sample dispersed in a solution such as water or ethanol) is dropped onto a region inside the holding unit 41 of the holding unit 4, so that the solution sample is placed on the optical function unit 20. Place. Subsequently, in order to reduce the lens effect, the cover 12 is disposed on the widened portion 13 of the measurement substrate 3 and the cover 12 is brought into close contact with the solution sample.

Thereafter, the measurement substrate 3 is placed on the stage 51, and the SERS unit 1 is set in the Raman spectroscopic analyzer 50. Subsequently, the solution sample is excited by irradiating the solution sample disposed on the optical function unit 20 with excitation light emitted from the light source 52 and passing through the optical component 53. At this time, the stage 51 is moved so that the excitation light is focused on the optical function unit 20. Thereby, surface-enhanced Raman scattering occurs at the interface between the optical function unit 20 and the solution sample, and Raman scattered light derived from the solution sample is enhanced to about 10 ⁸ times and emitted, for example. Then, the Raman scattering analysis is performed by detecting the emitted Raman scattered light with the detector 55 via the optical component 54.

  In addition to the method described above, the method for arranging the sample on the optical function unit 20 includes the following method. For example, the measurement substrate 3 is held, the SERS element 2 is immersed in a solution sample (or a powder sample dispersed in a solution such as water or ethanol), pulled up, blown, and the sample. May be dried. Alternatively, a small amount of a solution sample (or a powder sample dispersed in a solution such as water or ethanol) may be dropped on the optical function unit 20 and the sample may be naturally dried. Further, a sample that is powder may be dispersed on the optical function unit 20 as it is. In these cases, the cover 12 may not be arranged at the time of measurement.

  As described above, in the SERS element 2, the thickness of the base portion 28 of the conductor layer 23 is larger than the height of the pillar 27 of the fine structure portion 24. Therefore, compared with the case where the pillar 27 is not present, the contact area is increased, so that the base portion 28 is hardly peeled off from the fine structure portion 24, and the shape of the base portion 28 is stabilized. Further, since the pillar 27 of the fine structure 24 does not exist at the end 29a of the protrusion 29 of the conductor layer 23 that protrudes from the base 28, the protrusion 29 is affected by the deformation of the pillar 27 due to thermal expansion and contraction. It becomes difficult to receive, and the shape of the protrusion 29 is stabilized. Therefore, the gap G formed in the conductor layer 23 by the base portion 28 and the protruding portion 29 preferably functions as a nanogap in which local electric field enhancement occurs. Therefore, according to the SERS element 2, the intensity of surface enhanced Raman scattering can be increased by a suitable nanogap.

  In the SERS element 2, the pillars 27 are periodically arranged along the surface 21 a of the substrate 21. Thereby, the intensity | strength of surface enhancement Raman scattering can be increased.

  In the SERS element 2, the gap G is formed so as to surround each pillar 27 when viewed from the direction in which the pillar 27 protrudes. Thereby, the gap G which functions suitably as a nano gap can be increased.

  Next, a method for manufacturing the SERS element 2 will be described. First, as shown in FIG. 7A, a film base F is prepared, and a UV curable resin is applied to the surface of the film base F so that the UV curable resin layer R1 is formed on the film base F. Form. On the other hand, a master mold MM is prepared. The master mold MM includes a fine structure portion M24 corresponding to the fine structure portion 24, and a support portion M25 that supports the fine structure portion M24. On the support part M25, a plurality of fine structure parts M24 are arranged in a matrix. The microstructure M24 is subjected to a surface treatment with a release agent or the like so that it can be easily released in a later process.

  Subsequently, as shown in FIG. 7B, the master mold MM is pressed against the UV curable resin layer R1 on the film base F, and UV is irradiated in this state to cure the UV curable resin layer R1. Thus, the patterns of the plurality of fine structure portions M24 are transferred to the UV curable resin layer R1. Subsequently, as shown in FIG. 7C, the master mold MM is released from the UV curable resin layer R <b> 1 on the film base F to transfer the pattern of the plurality of fine structure portions M <b> 24. A mold (replica film) RM is obtained.

  Subsequently, as shown in FIG. 8A, a silicon wafer W to be a substrate 21 is prepared, and a UV curable resin is applied to the surface of the silicon wafer W, whereby a nanoimprint layer R2 to be a molding layer 22 is formed. Formed on the silicon wafer W. Subsequently, as shown in FIG. 8B, the replica mold RM is pressed against the nanoimprint layer R2 on the silicon wafer W, and the nanoimprint layer R2 is cured by irradiating UV in this state. The RM pattern is transferred to the nanoimprint layer R2. Subsequently, as illustrated in FIG. 8C, the replica mold RM is released from the nanoimprint layer R <b> 2 on the silicon wafer W to obtain the silicon wafer W on which a plurality of microstructures 24 are formed.

  As described above, the substrate 21 on which the fine structure portion 24 is formed is prepared at the wafer level (first step), and a metal such as Au or Ag is formed on the molding layer 22 by a vapor deposition method. The conductor layer 23 constituting the part 20 is formed on the fine structure part 24 (second step). At this time, vapor growth of a metal such as Au or Ag is performed so that the thickness of the base portion 28 of the conductor layer 23 is larger than the height of the pillar 27 of the fine structure portion 24. Subsequently, the SERS elements 2 are obtained by cutting the silicon wafer W for each fine structure portion 24 (in other words, for each optical function portion 20). Note that the metal may be vapor-phase grown after the silicon wafer W is first cut into a chip shape.

  Instead of the nanoimprint method described above, a thermal nanoimprint method, a mask having a two-dimensional pattern is formed by photoetching or electron beam drawing, and the fine structure portion 24 is formed on the substrate 21 by etching using the mask. It may be formed. In forming the conductor layer 23, a conductor such as metal may be vapor-phase grown by a vapor phase growth method (sputtering, CVD, or the like) other than the vapor deposition method.

  As described above, according to the manufacturing method of the SERS element 2, the nano-order gap G can be formed in the conductor layer 23 with a simple process and with good reproducibility, and the SERS element 2 can be mass-produced. Become.

  Further, as shown in FIG. 9, when forming the conductor layer 23, the thickness (outer diameter) D <b> 1 of the protruding portion 29 may be adjusted according to the thickness T of the base portion 28. Since the thickness D1 of the protruding portion 29 can be increased as the thickness T of the base portion 28 is increased, the thickness D1 of the protruding portion 29 is adjacent to the thickness D1 regardless of the pitch P of the pillars 27 of the fine structure portion 24. The ratio (duty ratio) D1 / (D1 + D2) with the distance D2 between the protrusions 29 to be fitted can be set to a desired value.

  Next, examples of the SERS element will be described. FIG. 10 is a SEM photograph of the microstructure of the SERS element of Example 1. In the fine structure portion of the SERS element of Example 1, the pillar is formed in a truncated cone shape having a thickness of 90 nm to 150 nm and a height of 150 nm, and has a period of 360 nm along the surface of the substrate. Are arranged. Au was vapor-deposited as a conductor layer on this fine structure portion so as to have a film thickness of 200 nm. FIG. 11 is a SEM photograph (SEM photograph of the optical function part taken from a direction perpendicular to the surface of the substrate) of the cross section of the optical function part of the SERS element of Example 1. In Example 1, the SERS element was folded and split, and the cross section was observed using SEM. As shown in FIG. 11, in the SERS element according to the first embodiment, the pillar 27, the base portion 28 of the conductor layer 23, and the protruding portion 29 (including the end portion 29 a protruding from the base portion 28) A number of suitably functioning gaps G were identified around the protrusion 29.

  FIG. 12 is an SEM photograph (SEM photograph of the optical function part taken from a direction inclined by 30 ° with respect to the direction perpendicular to the surface of the substrate) of the optical function part of the SERS element of Example 2. In Example 2, Au was vapor-deposited as a conductor layer so as to have a film thickness of 200 nm. As shown in FIG. 12, also in the SERS element of Example 2, a large number of gaps functioning suitably as nanogaps were confirmed around the protrusions.

  A specific method for producing the SERS element of Example 2 is as follows. First, a resin on a glass substrate is nano-imprinted using a mold in which holes having a hole diameter of 120 nm and a hole depth of 180 nm are arranged in a square lattice shape with a hole interval (distance between center lines of adjacent holes) of 360 nm. To form a fine structure. In the prepared microstructure, the pillar diameter was 120 nm, the height was 150 nm, and the pillar pitch (distance between the center lines of adjacent pillars) was 360 nm.

Then, Au was formed into a film by the resistance heating vacuum evaporation method as a conductor layer on the produced fine structure part, and the SERS element of Example 2 was obtained. The film formation condition of the conductor layer is “film thickness: as described above, vapor deposition rate: 0.02 nm / s, vacuum during film formation: 1.5 × 10 ⁻⁵ torr, substrate rotation: none, substrate temperature control. : None ”. In order to improve the adhesion of the conductor layer, Ti is formed as a buffer layer on the prepared microstructure by a resistance heating vacuum deposition method, and Au is formed as a conductor layer on the buffer layer by a resistance heating vacuum. You may form into a film by a vapor deposition method.

  FIG. 13 is a graph showing the relationship between Stokes shift and signal intensity for the SERS element of Example 2. Here, after immersing the SERS element of the SERS element of Example 2 in a mercaptobenzoic acid ethanol solution (1 mM) for 2 hours, rinsing with ethanol and drying with nitrogen gas, the sample is placed on the optical function part of the SERS element. Arranged. The sample was subjected to Raman spectroscopic measurement with excitation light having a wavelength of 785 nm. As a result, as shown in FIG. 13, a SERS spectrum of mercaptobenzoic acid was obtained.

  Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment. For example, the arrangement structure of the pillars 27 is not limited to a two-dimensional arrangement, but may be a one-dimensional arrangement, or is not limited to a square lattice arrangement, and may be a triangular lattice arrangement. Alternatively, it may not be a periodic array. The cross-sectional shape of the pillar 27 is not limited to a circle, and may be an ellipse or a polygon such as a triangle or a quadrangle. Further, the gap G is not limited to the one formed so as to surround the pillar 27 in an annular shape, and may be formed so as to surround the pillar 27 in another annular shape (such as an ellipse). . Further, the gap G is not limited to the one formed so as to continuously surround the pillar 27, and is formed so as to intermittently surround the pillar 27 in a state of being divided into a plurality of regions. There may be. Thus, the materials and shapes of the components of the SERS element 2 are not limited to the materials and shapes described above, and various materials and shapes can be applied.

  Here, when paying attention to a pair of adjacent convex portions (corresponding to the pillars 27), a conductor layer formed on the outer surface of one convex portion and a conductor formed on the outer surface of the other convex portion The width of the gap formed by the base portion and the protruding portion is smaller than the distance between the layers. This makes it possible to easily and stably form a narrow gap (a gap that suitably functions as a nanogap) that cannot be obtained only by the structure of the fine structure portion.

  Moreover, the fine structure part 24 may be indirectly formed on the surface 21a of the board | substrate 21 via the support part 25 like the said embodiment, for example, or it is directly on the surface 21a of the board | substrate 21. It may be formed. Further, the conductor layer 23 is indirectly formed on the microstructure portion 24 through some layer such as a buffer metal (Ti, Cr, etc.) layer for improving the adhesion of the metal to the microstructure portion 24. It may be formed directly on the fine structure 24.

  2 ... SERS element (surface enhanced Raman scattering element), 20 ... optical function part, 21 ... substrate, 21a ... surface (main surface), 23 ... conductor layer, 24 ... fine structure part, 27 ... pillar (convex part), 28 ... Base part, 29 ... Projection part, G ... Gap.

Claims (5)

A substrate having a main surface;
A microstructure formed on the main surface and having a plurality of pillars ;
A conductor layer that is formed on the microstructure part and constitutes an optical function part that causes surface-enhanced Raman scattering; and
The conductor layer includes a base portion formed along the main surface, and a plurality of protrusions protruding from the base portion at positions corresponding to the pillars ,
The thickness of the base portion is larger than the height of the pillar,
In the conductor layer, a plurality of gaps opened to the opposite side of the substrate are formed by the base portion and the protruding portion,
The surface-enhanced Raman scattering element , wherein the gap extends from a position on the opposite side of the substrate to the top of the pillar to a position on the substrate side with respect to the top of the pillar . The surface-enhanced Raman scattering element according to claim 1, wherein the pillars are periodically arranged along the main surface. 2. The plurality of gaps are formed in the conductor layer by the base portion and the protruding portion so as to surround each of the pillars when viewed from a direction in which the pillar protrudes. Alternatively, the surface-enhanced Raman scattering element according to 2. A first step of preparing a substrate having a main surface on which a microstructure having a plurality of pillars is formed;
After the first step, a base layer formed so as to extend along the principal surface and a base layer formed along the main surface, and a base layer that forms an optical function unit that causes surface-enhanced Raman scattering at the position corresponding to each of the pillars A second step of forming on the microstructure part so as to have a plurality of protrusions protruding from the part,
In the second step, the thickness of the base portion is larger than the height of the pillar , and the conductor layer is opened to the opposite side of the substrate by the base portion and the protruding portion. A plurality of gaps are formed, and the gap extends from a position on the opposite side of the substrate to the top of the pillar to a position on the substrate side with respect to the top of the pillar. A method for producing a surface-enhanced Raman scattering element, wherein the conductor layer is formed by vapor-phase-growing a conductor. Wherein as the second factory, to adjust the thickness of the projecting portion in accordance with the thickness of the base portion, the manufacturing method of the surface-enhanced Raman scattering element according to claim 4, wherein.