KR100912841B1 - Display panel with hybrid nano-pattern and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a surface product of a panel, and more particularly, the transparent front panel 10 is provided so that the light for the image emitted from the device body 1, the front panel 10 is the device body An inner surface on which light emitted from (1) is incident and an outer surface on which a nanopattern surface 11 on which a nanopattern is formed are formed, and the front panel 10 is made of a transparent material to form the nanopattern surface 11. Functional surface with a hybrid nanopattern which is provided as a surface product, and is diffusely reflected by the front panel of the nanopattern, which is a functional surface product having a hybrid nanopattern even when light is emitted from the outside. It is about a product.

Display, nanopattern, panel

Description

Functional surface product having hybrid nanopattern and manufacturing method thereof {DISPLAY PANEL WITH HYBRID NANO-PATTERN AND MANUFACTURING METHOD THEREOF}

The present invention relates to a surface product of a panel, and more particularly, the front panel of the device body is formed with a nanopattern surface, so that the hybrid nano to easily see the image content seen in the device is diffusely reflected even when light is emitted from the outside A functional surface product having a pattern.

In general, a panel product of a video device or a device for viewing the contents of the inside is mainly configured to allow a user to view the display contents of the product, and may be provided as an installation and guide item such as a clock, a frame, and a decorative product. . In addition, it consists of a front panel such as a panel of a multimedia device such as a computer monitor, a television, a video screen. And it can be configured as not only the instrument panel panel of the vehicle, but also the instrument panel panel of the aircraft, precision system.

These panels are mainly configured so that users can see the contents inside the device, and the representative one is called LCD monitor. That is, as the LCD monitor according to the prior art, as shown in Figure 1, which shows the Republic of Korea Patent No. 312784 (panel fixing structure of the LCD monitor), the rear cover 510 and the front case 520 to the LCD monitor 500 Configure. Therefore, the inside of the image display unit is configured, and the backlight is provided at the rear of the inside to illuminate the light evenly forward, and the liquid crystal display panel 530 is configured in front of the polarizing plate of the liquid crystal display panel 530. Various images are reflected by this.

However, in the conventional LCD monitor 500, since the front surface of the LCD display panel 530 forms a flat surface, when the external light source is reflected on the front surface of the LCD display panel 500, the LCD display panel 530. There is a problem that you can not see the video from the image at all.

In addition, even in the case of mobile communication terminals such as mobile phones and PDAs that seek information, it is difficult to check the contents of the LCD screen by external light such as sunlight or bright light of the surroundings. There is a need for a front panel product that can be used.

Literature Information of the Prior Art

Republic of Korea Patent No. 312784 (Published June 05, 2001)

The present invention for solving the problems described above is easily reflected by the front panel of the nano-pattern, which is a functional surface product having a hybrid nano-pattern even if the light from the outside is reflected on the product so that you can easily see the image content seen in the device The purpose is to.

In addition, the purpose of the mass production at a low cost to produce a front panel formed with a hybrid nano-pattern using a mold made once.

Functional surface product having a hybrid nanopattern according to the present invention for achieving the above object is provided with a transparent front panel 10 to transmit the light for the image emitted from the device body (1), the front panel 10 has an inner surface through which light emitted from the device body 1 is incident, and an outer surface of the front panel 10 has a nanopattern surface 11 having a nanopattern formed therein, whereby incident light is formed. It is provided so as to emit light forward, the front panel 10 is characterized in that the surface is provided with the nano-pattern surface 11 is formed of a transparent material.

The front panel 10 is any one of the transverse grooves 111, longitudinal grooves 112, lattice-shaped grooves 113, circular grooves 118, cylindrical grooves 119, polygonal column grooves 120 Two or more of the grooves or the horizontal row grooves 111, longitudinal row grooves 112, lattice row grooves 113, circular grooves 118, cylindrical grooves 119, polygonal column grooves 120 are selected It may be provided with a nano-pattern surface 11 formed of a compound groove made of,

The front panel 10 is any one of the projections or circular projections 114, cylindrical projections (115), circular projections 114, cylindrical projections 115, polygonal projections 116, square pyramidal projections (117), The polygonal pillar 116 and the square pyramidal projection 117 may be provided as a nano-pattern surface 11 formed of a compound projection consisting of two or more selected.

Furthermore, the method for producing a functional surface product having a hybrid nanopattern according to the present invention,

An aluminum deposition step (S01) of forming an aluminum layer 22 by depositing an aluminum film on the upper surface of the silicon base layer 21;

An electrolytic polishing step (S02) of forming an aluminum oxide layer (22 ') on the surface of the aluminum layer by electropolishing in the state in which the aluminum layer (22) is formed by the aluminum deposition step;

An aluminum etching step (S03) of removing the aluminum oxide layer (22 ') by etching to make it flat;

Anodizing to form a nanopatterned aluminum oxide layer 23 by anodizing on the aluminum layer 22 which has undergone the aluminum etching step (S04);

A nanoetching step (S05) of removing the oxidized aluminum oxide layer 23 to produce an aluminum layer 22 having a nanopattern formed thereon;

A metal master manufacturing step (S06) of manufacturing a metal master 24 of the nano-pattern nickel stamper by forming a nickel layer by Ni electroforming in the state where the nano-pattern is formed on the aluminum layer 22;

Nano pattern formed on the metal master 24 is characterized in that it comprises a nano-pattern front panel manufacturing step (S07) for manufacturing the front panel 10 in which the hybrid nano-pattern is formed by plastic injection.
In addition, the method for producing a functional surface product having a hybrid nanopattern according to the present invention,
An aluminum deposition step (S01) of forming an aluminum layer 22 by depositing an aluminum film on the upper surface of the silicon base layer 21;
An electrolytic polishing step (S02) of forming an aluminum oxide layer (22 ') on the surface of the aluminum layer by electropolishing in the state in which the aluminum layer (22) is formed by the aluminum deposition step;
An aluminum etching step (S03) of removing the aluminum oxide layer (22 ') by etching to make it flat;
Anodizing to form a nanopatterned aluminum oxide layer 23 by anodizing on the aluminum layer 22 which has undergone the aluminum etching step (S04);
A nanoetching step (S05) of removing the oxidized aluminum oxide layer 23 to produce an aluminum layer 22 having a nanopattern formed thereon;
A metal master manufacturing step (S06) of manufacturing a metal master 24 of the nano-pattern nickel stamper by forming a nickel layer by Ni electroforming in the state where the nano-pattern is formed on the aluminum layer 22;
The nano-pattern of the functional surface product having a hybrid nano-pattern is provided that includes a nano-pattern front panel manufacturing step (S07) for manufacturing the front panel 10, the hybrid nano-pattern is formed by plastic injection to the metal master 24 is formed. In the manufacturing method,
The anodization step (S04), in the electrolyte made of oxalic acid (Oxalic acid, C ₂ H ₂ O ₄ ), to be anodized using platinum as a cathode, the voltage is 90V, the distance between the electrodes is 8cm, the temperature is 7 ℃ , The time is made to 2 minutes, the stirring speed is provided to be 100rpm, the nano-etching step (S05) is 60 minutes in a 65 ℃ solution containing chromic acid (1.8 parts by weight) and phosphoric acid (6 parts by weight) It is provided to be etched, the nano-pattern front panel manufacturing step (S07), to form a secondary metal master (24 ') of the mold by Ni electroforming (Electroforming) on the metal master 24 of the hybrid nano-pattern, The secondary metal master 24 ′ is characterized in that the front panel 10 of the nanopattern is formed by a mold injection as a hybrid nanopattern.
Furthermore, the functional surface product, which is the front panel 10 manufactured by the method for producing a functional surface product having the hybrid nanopattern according to the present invention, is transparent so that the image light emitted from the device body 1 is transmitted. The front panel 10 is provided, the front panel 10 is provided with an inner surface on which the light emitted from the device body 1 is incident, the outer surface of the front panel 10 is formed with a nano-pattern The nano-pattern surface 11 is formed so that the incident light is emitted forward, the front panel 10 is made of a transparent material, the surface is provided with the nano-pattern surface 11 is formed, the front panel ( 10 is a groove of any one of the transverse row groove 111, the longitudinal row groove 112, the grid row groove 113, the circular groove 118, the cylindrical groove 119, the polygonal column groove 120; Or a composite groove made of two or more of the horizontal row groove 111, the longitudinal row groove 112, the grid row groove 113, the circular groove 118, the cylindrical groove 119, and the polygonal column groove 120; Or any one of circular protrusions 114, cylindrical protrusions 115, polygonal pillars 116, and square pyramid protrusions 117; Or a complex protrusion consisting of at least two selected from a circular protrusion 114, a cylindrical protrusion 115, a polygonal pillar protrusion 116, and a square pyramidal protrusion 117; Characterized in that provided with a nano-pattern surface 11 formed in any one of the shapes.

The present invention provided as described above is an effect that is easily reflected by the front panel of the nano-pattern, which is a functional surface product having a hybrid nano-pattern, even if reflected on the display product by the light from the outside to see the image content seen in the device There is.

In particular, since the shape of the pattern forms a nanopattern, the user can easily see the light emitted from the inside of the device, and there is an advantage in that the user can easily see the light reflected from the outside.

In addition, it is possible to continuously produce a front panel with a hybrid nanopattern using a mold manufactured once, and thus, mass production at low cost is possible.

Hereinafter, with reference to the accompanying drawings will be described in detail.

Figure 2 is a perspective view of a display that is a functional surface product of the present invention, Figures 3 to 13 is an enlarged view of the nanopattern of the front panel of the present invention. In particular, FIGS. 3 to 6 are enlarged views illustrating part B according to the pattern shape of FIG. 2. And Figures 7-13 illustrate exemplary enlarged cutaway views of the nanopatterned surface portions of the front panel.

14 is a flowchart illustrating a manufacturing method of the first embodiment of the front panel of the present invention, and FIG. 15 and FIG. 16 each illustrate an example of a process of the manufacturing method of the first embodiment of the front panel of the present invention. And Figure 17 shows a schematic illustration of the state that the external light source is shining on the front panel of the present invention.

That is, the functional surface product having a hybrid nanopattern according to the present invention is provided with a transparent front panel 10 such that the image light emitted from the inside of the device body 1 is transmitted as shown in FIGS. 2 to 17. In particular, the front panel 10 has an inner surface on which light emitted from the inside of the device body 1 is incident, and the outer surface of the front panel 10 has a nanopattern surface 11 having a nanopattern formed therein. The front panel 10 is formed of a transparent material and is a functional surface product having a hybrid nanopattern provided as a surface product on which the nanopattern surface 11 is formed. The front surface product of the front panel is located at the front of the device, and the user can visually view the video contents or the internal contents while looking at the surface of the surface product of the front panel of the device. In addition, such a surface product may be provided with a product forming the outer surface of the device having a functional. In particular, in the present invention, since the front surface of the front panel of the transparent material is provided as a surface product formed of nano-patterns, the image material seen from the inside can be easily seen, but the light having a special function of light reflected from the outside is diffusely reflected. It is a product.

That is, the surface product is a product to process the front surface of the front panel to improve the cyan, this functional surface product according to the present invention is illustrated that is applied to the display (A) in Figure 2, but is not limited thereto. If the product is manufactured to be visible to the user, it can be applied anywhere.

In other words, it is a product of the main body of the applied device, such as touch screen front panel of automation equipment and bank CD machine, monitor front panel of computer, front panel of TV receiver, instrument panel panel of automobile, aircraft, instrument panel panel of automation device, frame, It is possible to apply a variety of surface products such as front transparent plates of decorative products, transparent front plates of functional products such as watches, and front panels of mobile phones and PDAs. As described above, in the case of the product to which the functional surface product according to the present invention is applied, the reflected light emitted from the outside is prevented from being reflected in the direction of the user's view so that the user can see the contents of the device accurately. .

That is, as shown in FIG. 17, the light b emitted from the external light source a located in one direction of the front panel 10 is dispersed in various directions on the nanopattern surface 11 of the front panel 10. Almost no light is directed toward user c. Therefore, the user can easily see the image and the display contents seen from the device main body 1, since almost no light is reflected from the front panel 10 to the user side in any direction.

The front panel 10, which is a functional surface product having a hybrid nanopattern according to the present invention having excellent effects as described above, has a transverse row groove 111, a longitudinal row groove 112, and a grid row as shown in FIGS. The groove 113, and may be provided with a nano-pattern surface 11 formed of a row groove made of a compound groove, such as two or more string grooves.

And the front panel 10 is a circular protrusion 114, a cylindrical protrusion 115, a polygonal pillar 116, a square pyramidal protrusion 117, and a combination of two or more of these projections, as shown in Figs. It may be provided with a nano-pattern surface 11 is formed of a projection, such as a projection.

Furthermore, the front panel 10 is a groove which is a circular groove 118, a cylindrical groove 119, a polygonal pillar groove 120, and a compound groove having two or more such grooves as shown in FIGS. 11 to 13. It may be provided with the formed nanopattern surface (11).

In the example shown above, the front panel 10 is formed as a functional surface product having a hybrid nanopattern, which is a nanopattern 11 formed of a string groove, a protrusion, a groove, a compound groove, and a compound protrusion. The present invention is not limited to this, and a functional surface product having a hybrid nanopattern formed by a method of forming a nanopattern generally belongs to the present invention.

Such a nanopattern forming method of a functional surface product having a hybrid nanopattern according to the present invention may be provided in various ways. In particular, the hybrid nanopattern of stripes as shown in Figures 3 to 6 may be formed using a nanomask in which the nanopattern is formed. 7 to 13, the hybrid nanopattern having grooves or protrusions may be formed by injection using a mold.

Looking at the first embodiment of the method for producing a functional surface product having a hybrid nanopattern according to the present invention, as shown in Figs. 14 and 17, hybrid nano-pattern using an anodization method for aluminum. ) To form a mold, and using this to produce a functional surface product having a hybrid nanopattern by injection into a transparent material. The method of forming a hybrid nanopattern using the mold may be manufactured by the "Method of manufacturing a nanomaster having a hybrid nanopattern" of Korean Patent Application No. 10-2007-74204 filed by the applicant of the present invention.

That is, first, an aluminum film is deposited on the upper surface of the silicon base layer 21 to form the aluminum layer 22 (aluminum deposition step S01). Accordingly, in the example of the present invention, the aluminum layer 22 is formed on the upper surface of the silicon base layer 21 by vapor deposition, but may be provided as pure aluminum without the silicon base layer. In addition, after the aluminum layer 22 is thinly formed by vapor deposition, the aluminum layer 22 may be added to an electrolyte solution, and an aluminum plating process may be added to form a thicker aluminum layer, thereby forming a hybrid nanopattern.

Thereafter, in the state in which the aluminum layer 22 is formed by the aluminum deposition step, an aluminum oxide layer 22 'is formed on the surface of the aluminum layer by electropolishing (electrolytic polishing step S02), and the aluminum oxide layer 22' ) Is removed by etching to perform a flat aluminum etching step (S03). Thus, irregular surfaces are formed evenly by vapor deposition. This is to ensure that the nanopattern is formed at a constant height during anodization.

As described above, the anodization step (S04) of forming the nanopatterned aluminum oxide layer 23 by anodization is performed on the aluminum layer 22 which has undergone the aluminum etching step. Thus, in an electrolyte made of oxalic acid (C ₂ H ₂ O ₄ ), platinum is anodized using a cathode. At this time, the voltage is about 90V, the distance between the electrodes is about 8cm, the temperature is about 7 ℃, the time is about 2 minutes to anodize. In addition, the stirring speed may be provided to be 100rpm. In order to form a more diverse hybrid nanopattern, sulfuric acid (H ₂ SO ₄ ), phosphoric acid (H ₃ PO ₄ ) and the like can be used to include, and the temperature, oxidation time, voltage, electrolyte concentration, etc. By adjusting the depth of the nanopattern, the shape of the nanopattern will be adjusted.

The nano-etching step (S05) is performed to remove the anodized aluminum oxide layer 23 to manufacture the aluminum layer 22 having the nanopattern d formed thereon. This can be removed by etching for 60 minutes in a 65 ℃ solution containing chromic acid (1.8 parts by weight) and phosphoric acid (6 parts by weight).

In addition, a nickel layer is formed on the aluminum oxide layer 23 having pores formed in the anodization step or the aluminum layer 22 formed with a nano pattern in the nanoetching step with Ni electroforming to form a metal master of a nano pattern nickel stamper ( 24) is produced (metal master production step (S06)).

The nano-pattern front panel manufacturing step (S07) of manufacturing the front panel 10, the hybrid nano-pattern is formed by plastic injection into the metal master (24), which is a mold in which the nano-pattern is formed by the process using anodization as described above. Proceed. Therefore, when the front panel 10 is manufactured using the metal master 24 having the nanopattern formed by the aluminum layer 22 having the hybrid nanopattern formed thereon, the circular groove 118 and the cylindrical groove ( 119), hexagonal pillar grooves or polygonal pillar grooves 120, and two or more of these grooves such as a compound groove including a groove or a pillar groove.

That is, since the aluminum layer 22 in which the hybrid nanopattern is formed has a nanopattern shape as a groove, the metal master 24, which is a mold manufactured therefrom, forms protrusions, and the protrusion shape of the metal master 24 is formed. The hybrid nanopattern formed by injection into the hybrid nanopattern becomes a groove.

Accordingly, when the secondary metal master 24 ', which is a mold, is formed on the metal master 24 of the hybrid nanopattern having a projection shape by electroforming, the secondary metal master 24' is formed in the groove of the hybrid nanopattern. It is formed as. When the front panel 10 is formed by injection into a mold including the secondary metal master 24 ′, the nanopattern surface 11 of the front panel 10 has a circular protrusion 114 as shown in FIGS. 7 to 10. , It is possible to form a hybrid nanopattern having a shape such as a cylindrical protrusion 115, a hexagonal pillar, a polygonal pillar 116 or a square pyramidal protrusion 117, and a composite protrusion including two or more of these protrusions. .

In addition, the shape of the hybrid nanopattern of various forms may be manufactured by varying the type and concentration of the electrolyte solution, the time of anodization, the intensity of temperature and voltage, and the like.

In addition, another embodiment of manufacturing a functional surface product having a hybrid nanopattern of the present invention is to use a nanomask on which a nanopattern is formed.

That is, referring to the second embodiment of manufacturing a functional surface product having a hybrid nanopattern, first, a nanopattern is designed to produce a nanomask to match the nanodesigned pattern. After the photoresist is applied to the surface of the substrate, which is a substrate, and dried under heat, the photoresist is formed on the substrate, and the nanomask on which the nanopattern is formed is placed on the substrate. To do that. Thereafter, the nanopattern is formed by etching the portion where the photoresist is removed, and the remaining photoresist is removed to form a hybrid nanopattern on the substrate.

Such a method of forming a nanopattern may be prepared by referring to a method of forming a nanomask and a nanopattern in Korean Patent No. 726715, which has been patented by the present applicant.

Thus, the hybrid nanopattern of the present invention formed using the nanomask thus prepared has a horizontal row groove 111, a longitudinal row groove 112, a grid row groove 113, and 113 as shown in FIGS. 3 to 6. '), And may be formed of a compound row hop including two or more of these row grooves.

Furthermore, using the substrate on which the hybrid nanopattern is formed by the nanomask, a mold may be manufactured as in the manufacturing method of the first embodiment to form the nanopattern 11 of the functional surface product having the hybrid nanopattern by injection. Can be. In the case where the nano-pattern surface 11 is formed by injection using a mold having the hybrid nanopattern formed as described above, a plurality of front panels 10 may be manufactured by using a single nanopattern mold, thereby improving productivity. have.

Therefore, the functional surface product having the hybrid nanopattern of the present invention manufactured by the manufacturing method of the first embodiment and the second embodiment is formed on the front panel 10 of the device body 1, Even if light is reflected, it is diffusely reflected and scattered, so that the user can easily view the image content displayed on the device body (1). In other words, not only items such as watches, picture frames, and ornaments, but also contents from transparent windows, such as automobile instrument panels, aircraft instrument panels, electronic instrument panels, mobile communication terminals, PDA panels, monitor front panels, and touch screen front panels. There is an advantage in that it is easy to see the displayed contents even in a visual device for emitting light.

As an example, even in a display A in which a backlight is provided inside the device body 1 and a liquid crystal display panel in which a polarizing plate is provided in front of the backlight, the front of the liquid crystal display panel or the front of the device body 1 When the front panel 10, which is a functional surface product of the present invention, is installed, the light reflected from the outside is diffusely reflected on the nanopattern surface 11 of the front panel 10, and thus the image content shown by the liquid crystal display panel. There is always an advantage to see.

In addition, since the hybrid nanopattern surface 11 is formed on the front surface of the panel as shown in FIGS. 3 to 17, the impact can be absorbed by the bending of the hybrid nanopattern surface of the front panel as compared to the panel having a simple flat surface. , It has the advantage that it is not easily broken even from the impact from the outside.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art without departing from the spirit and scope of the invention described in the claims below In the present invention can be carried out by various modifications or variations.

1 is a perspective view of a display according to the prior art;

Figure 2 is a perspective view of a display of the present invention the surface product.

3 to 13 is an enlarged view of a nano pattern surface of the front panel of the present invention.

14 is a flowchart of a manufacturing method of the first embodiment of the present invention front panel;

15 and 16 are views illustrating a process for the manufacturing method of the first embodiment of the front panel of the present invention.

Figure 17 is a schematic illustration of a state in which an external light source is shining on the front panel of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: main unit 10: front panel

11: nano pattern surface 24: metal master

Claims (4)

An aluminum deposition step (S01) of forming an aluminum layer 22 by depositing an aluminum film on the upper surface of the silicon base layer 21; An electrolytic polishing step (S02) of forming an aluminum oxide layer (22 ') on the surface of the aluminum layer by electropolishing in the state in which the aluminum layer (22) is formed by the aluminum deposition step; An aluminum etching step (S03) of removing the aluminum oxide layer (22 ') by etching to make it flat; Anodizing to form a nanopatterned aluminum oxide layer 23 by anodizing on the aluminum layer 22 which has undergone the aluminum etching step (S04); A nanoetching step (S05) of removing the oxidized aluminum oxide layer 23 to produce an aluminum layer 22 having a nanopattern formed thereon; A metal master manufacturing step (S06) of manufacturing a metal master 24 of the nano-pattern nickel stamper by forming a nickel layer by Ni electroforming in the state where the nano-pattern is formed on the aluminum layer 22; The nano-pattern of the functional surface product having a hybrid nano-pattern is provided that includes a nano-pattern front panel manufacturing step (S07) for manufacturing the front panel 10, the hybrid nano-pattern is formed by plastic injection to the metal master 24 is formed. In the manufacturing method, The anodization step (S04), in the electrolyte made of oxalic acid (Oxalic acid, C ₂ H ₂ O ₄ ), to be anodized using platinum as a cathode, the voltage is 90V, the distance between the electrodes is 8cm, the temperature is 7 ℃ , The time is to be made to 2 minutes, the stirring speed is provided to be 100rpm, The nano-etching step (S05) is provided to be etched for 60 minutes in a 65 ℃ solution containing chromic acid (1.8 parts by weight) and phosphoric acid (6 parts by weight), In the nano-pattern front panel manufacturing step (S07), the secondary metal master 24 ', which is a mold, is formed again by Ni electroforming on the metal master 24 of the hybrid nano-pattern, and the secondary metal master ( 24 ') is a method of manufacturing a functional surface product having a hybrid nanopattern, characterized in that the front panel 10 of the nanopattern is formed by a mold injection as a hybrid nanopattern. In the functional surface product comprising the front panel 10 manufactured by the method for producing a functional surface product having a hybrid nanopattern of claim 1, The transparent front panel 10 is provided so that the light for the image emitted from the device body (1), The front panel 10 has an inner surface through which light emitted from the device body 1 is incident, and an outer surface of the front panel 10 is formed with a nano pattern surface 11 having a nano pattern formed thereon. Provided light is emitted to the front, The front panel 10 is made of a transparent material, the surface is provided with the nano-pattern surface 11 is formed, The front panel 10 is any one of the horizontal row groove 111, longitudinal row groove 112, lattice row groove 113, circular groove 118, cylindrical groove 119, polygonal pillar groove 120 Home; or A compound groove made of two or more of the horizontal row groove 111, the longitudinal row groove 112, the grid row groove 113, the circular groove 118, the cylindrical groove 119, the polygonal column groove 120; or A protrusion of any one of a circular protrusion 114, a cylindrical protrusion 115, a polygonal pillar protrusion 116, and a square pyramidal protrusion 117; or A complex protrusion formed by two or more of the circular protrusion 114, the cylindrical protrusion 115, the polygonal pillar 116, and the square pyramidal protrusion 117; Functional surface product having a hybrid nanopattern, characterized in that provided with a nanopattern surface 11 formed in any one of the shapes. delete delete

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