KR20200027396A - Metamaterial-based reflector, optical cavity structure including the same and vertical cavity surface emitting laser - Google Patents

Abstract

Disclosed are a metamaterial-based reflector, an optical cavity structure including the same, and a vertical cavity surface emitting laser, capable of easily controlling the characteristics of light. The metamaterial-based reflector may comprise: a first metamaterial layer including an array of a plurality of first nanostructures; and a second metamaterial layer disposed on the first metamaterial layer and including an array of a plurality of second nanostructures. An arrangement direction and arrangement method of the second nanostructures may be different from an arrangement direction and arrangement method of the first nanostructures. The first nanostructures may be arranged alongside each other in a first direction, and the second nanostructures may be arranged in a different direction from the first direction, or the arrangement direction of the second nanostructures may be changed depending on an area.

Description

Metamaterial-based reflector, optical cavity structure including the same and vertical cavity surface emitting laser

The disclosed embodiments relate to a reflector (mirror), an optical cavity structure comprising the same, and a vertical resonant surface emitting laser.

The vertical cavity surface emitting laser (VCSEL) has a shorter optical gain length compared to an edge emitting laser (EEL), enabling low power consumption and a two-dimensional array due to vertical emission. As it can be manufactured as a furnace, it is advantageous for high density integration and mass production. While the conventional EEL has an asymmetrical light output, the VCSEL provides a circularly symmetrical output mode, enabling efficient high-speed modulation with low noise by efficiently connecting to an optical fiber.

VCSEL is equipped with a distributed Bragg reflector (DBR) having a high reflectance of about 98% or more to construct a laser resonator. DBRs composed of pairs of two materials having different refractive indices usually require dozens of pairs of stacked structures in order to obtain high reflectance. In addition, DBR has low thermal conductivity (or high thermal resistance) due to phonon scattering occurring at the boundary between two materials. Complementing the shortcomings of DBR, there is a need for a technique and method capable of improving light control and emission characteristics.

Provided is a metamaterial-based reflector using a nanostructure array.

It provides a meta-material-based reflector that can easily control the properties of light such as polarization and convergence / divergence.

It provides an optical cavity structure and a vertical resonant surface emitting laser (VCSEL) to which the metamaterial-based reflector is applied.

According to an aspect, a first metamaterial layer including an array of a plurality of first nanostructures; And a second meta-material layer disposed on the first meta-material layer and including an array of a plurality of second nano-structures. The plurality of second nano-structures include the plurality of first nano-structures. Differently arranged metamaterial-based reflectors are provided.

The arrangement direction and arrangement method of the plurality of second nanostructures may be different from the arrangement direction and arrangement method of the plurality of first nanostructures.

The plurality of first nanostructures may be arranged alongside each other along a first direction, and the plurality of second nanostructures may be arranged in a different direction from the first direction, or an arrangement direction of the plurality of second nanostructures may be It may vary depending on the area.

The first meta-material layer may be a transmissive wave plate, and the second meta-material layer may be a reflective wave plate.

The plurality of first nanostructures may be arranged parallel to each other along a first direction, and the plurality of second nanostructures may be arranged parallel to each other along a second direction rotated by θ relative to the first direction. And θ may be less than 90 °.

The plurality of first nanostructures may be arranged alongside each other along a first direction, the plurality of second nanostructures may be arranged to rotate relative to the first direction, the rotation angle of the second nanostructure Can be changed depending on the region.

The metamaterial-based reflector may be configured to circularly polarize light passing therethrough.

An arrangement rule of the plurality of second nanostructures may be designed so that the metamaterial-based reflector acts as a converging mirror or a diverging mirror.

The first meta-material layer may be a first transmissive wave plate, the second meta-material layer may be a second transmissive wave plate, a distributed Bragg reflector disposed on the second meta-material layer ( Distributed Bragg reflector (DBR) may be further included.

The plurality of first nanostructures may be arranged parallel to each other along a first direction, and the plurality of second nanostructures may be arranged parallel to each other along a second direction rotated by θ relative to the first direction. And θ may be less than 90 °.

The plurality of first nanostructures may be arranged alongside each other along a first direction, the plurality of second nanostructures may be arranged to rotate relative to the first direction, the rotation angle of the second nanostructure Can be changed depending on the region.

The metamaterial-based reflector may be configured to linearly polarize light passing therethrough.

An arrangement rule of the plurality of second nanostructures may be designed so that the metamaterial-based reflector acts as a converging mirror or a diverging mirror.

According to another aspect, an optical device including at least one metamaterial-based reflector described above is provided.

According to another aspect, a gain layer for generating light; A distributed Bragg reflector disposed on the first surface of the gain layer; And a metamaterial-based reflector disposed on the second surface of the gain layer, wherein the metamaterial-based reflector comprises: a first metamaterial layer including an array of a plurality of first nanostructures; And a second metamaterial layer including an array of a plurality of second nanostructures on the first metamaterial layer, wherein the plurality of second nanostructures are optically arranged differently from the plurality of first nanostructures. An optical cavity structure is provided.

The plurality of first nanostructures may be arranged alongside each other along a first direction, and the plurality of second nanostructures may be arranged in a different direction from the first direction, or an arrangement direction of the plurality of second nanostructures may be It can be changed depending on the area.

The plurality of first nanostructures may be arranged parallel to each other along a first direction, and the plurality of second nanostructures may be arranged parallel to each other along a second direction rotated by θ relative to the first direction. And θ may be less than 90 °.

The plurality of first nanostructures may be arranged alongside each other along a first direction, the plurality of second nanostructures may be arranged to rotate relative to the first direction, the rotation angle of the second nanostructure Can be changed depending on the region.

The first meta-material layer may be a transmissive wave plate, and the second meta-material layer may be a reflective wave plate.

The first meta-material layer may be a first transmissive wave plate, the second meta-material layer may be a second transmissive wave plate, the meta-material-based reflector on the second meta-material layer A separate distributed Bragg reflector (DBR) may be further included.

The metamaterial-based reflector may be configured to circularly polarize light passing therethrough.

The metamaterial-based reflector may be configured to linearly polarize light passing therethrough.

An arrangement rule of the plurality of second nanostructures may be designed so that the metamaterial-based reflector acts as a converging mirror or a diverging mirror.

According to another aspect, there is provided a vertical cavity surface emitting laser comprising the optical cavity structure described above.

It is possible to implement a metamaterial-based reflector using a nanostructure array. It is possible to implement a metamaterial-based reflector that can easily control properties of light such as polarization and convergence / dissipation. The optical cavity structure and the vertical resonant surface emitting laser (VCSEL) to which the above-described metamaterial-based reflector is applied may be implemented.

1A and 1B are cross-sectional views showing a metamaterial-based reflector according to an embodiment.
2A is a plan view showing an array of first nanostructures included in the first metamaterial layer of FIGS. 1A and 1B, and FIG. 2B is a plan view showing an array of second nanostructures included in the second metamaterial layer.
3A and 3B are cross-sectional views showing metamaterial-based reflectors according to another embodiment.
4A is a plan view showing an array of first nanostructures included in the first metamaterial layer of FIGS. 3A and 3B, and FIG. 4B is a plan view showing an array of second nanostructures included in the second metamaterial layer.
5A and 5B are cross-sectional views showing metamaterial-based reflectors according to another embodiment.
6A is a plan view showing an array of first nanostructures included in the first metamaterial layer of FIGS. 5A and 5B, and FIG. 6B is a plan view showing an array of second nanostructures included in the second metamaterial layer.
7A and 7B are cross-sectional views showing metamaterial-based reflectors according to another embodiment.
8A is a plan view showing an array of first nanostructures included in the first metamaterial layer of FIGS. 7A and 7B, and FIG. 8B is a plan view showing an array of second nanostructures included in the second metamaterial layer.
9 is a cross-sectional view showing an optical cavity structure using an metamaterial-based reflector according to an embodiment.
10 is a cross-sectional view showing an optical cavity structure to which a metamaterial-based reflector according to another embodiment is applied.
11 is a cross-sectional view showing an optical cavity structure using a metamaterial-based reflector according to another embodiment.
12 is a cross-sectional view showing an optical cavity structure to which a metamaterial-based reflector according to another embodiment is applied.
13 is a cross-sectional view showing a vertical cavity surface emitting laser (VCSEL) including an optical cavity structure to which a metamaterial-based reflector is applied according to an embodiment.
14 is a cross-sectional view showing a vertical resonant surface emitting laser (VCSEL) including an optical cavity structure to which a metamaterial-based reflector is applied according to another embodiment.
15A is a cross-sectional view showing a vertical resonant surface emitting laser (VCSEL) including an optical cavity structure to which a metamaterial-based reflector is applied according to another embodiment.
15B is an exploded cross-sectional view of the vertical resonant surface emitting laser (VCSEL) of FIG. 15A.
15C is a plan view exemplarily showing an array of a plurality of nanostructures included in the metamaterial layer of FIG. 15B.
FIG. 16 is a graph showing reflectivity and phase change for the substructure of VCSEL of FIG. 15B.
17 is a graph showing the reflection phase of the superstructure of the VCSEL of FIG. 15B.
18 and 19 are images showing an array of nanostructures of a metamaterial layer that can be applied to a metamaterial-based reflector according to an embodiment.

Hereinafter, a metamaterial-based reflector according to embodiments, an optical cavity structure including the same, and a vertical resonant surface emitting laser will be described in detail with reference to the accompanying drawings. The width and thickness of the layers or regions illustrated in the accompanying drawings may be exaggerated for clarity and convenience of description. The same reference numerals throughout the detailed description indicate the same components.

1A and 1B are cross-sectional views illustrating a metamaterial-based reflector 100A according to an embodiment. Figure 1a shows the transmission characteristics of the incident light, Figure 1b shows the characteristics of the reflected light. The metamaterial-based reflector 100A may be referred to as a metasurface mirror or a nanostructure-based mirror.

1A and 1B, a metamaterial-based reflector 100A is formed on a first metamaterial layer M10 and a first metamaterial layer M10 including an array of a plurality of first nanostructures n10. Arranged, a second metamaterial layer M20 including an array of a plurality of second nanostructures n20 may be provided. The plurality of second nanostructures n20 may be arranged differently from the plurality of first nanostructures n10. The arrangement direction and arrangement method of the plurality of second nanostructures n20 may be different from the arrangement direction and arrangement method of the plurality of first nanostructures n10. For example, the plurality of first nanostructures n10 may be arranged side by side with each other along the first direction, and the plurality of second nanostructures n20 may be arranged in a direction different from the first direction. The first metamaterial layer M10 may be referred to as a first nanostructure array layer, and the second metamaterial layer M20 may be referred to as a second nanostructure array layer. Reference numeral m10 denotes a first material layer, and m20 denotes a second material layer. The refractive index of the first material layer m10 may be smaller than the refractive index of the first nanostructure n10, and the refractive index of the second material layer m20 may be smaller than the refractive index of the second nanostructure n20. Since the first and second material layers m10 and m20 may be in contact with them around the plurality of first and second nanostructures n10 and n20, respectively, they may be referred to as 'adjacent layers' or 'contact layers'. have. The first metamaterial layer M10 may be said to include a plurality of first nanostructures n10 and a first material layer m10 covering them, similarly, the second metamaterial layer M20 may include a plurality of It can be said that it includes a second nanostructure (n20) and a second material layer (m20) covering them. The first and second material layers m10 and m20 may be dielectric or insulator.

In this embodiment, the first metamaterial layer M10 may be a transmissive wave plate, and the second metamaterial layer M20 may be a reflective wave plate. For example, the first metamaterial layer M10 may be a transmissive quarter wave plate, and the second metamaterial layer M20 may be a reflective half wave plate. You can. In this case, the metamaterial-based reflector 100A can perform the function of a reflector (ie, a mirror) without a separate mirror member. The metamaterial-based reflector 100A may be referred to as a “bilayer metasurface mirror”. The second meta-material layer M20 may be designed as a reflective type according to a material, shape, size, pattern spacing, etc. of the second nanostructure n20, and may function as a reflective half-wave plate.

Referring to FIG. 1A, the metamaterial-based reflector 100A may be configured to circularly polarize the light that transmits it, that is, the transmitted light L30. When the incident light L10 is linearly polarized by + 45 ° to the X axis, the transmitted light L30 may be circularly polarized by the metamaterial-based reflector 100A.

Referring to FIG. 1B, light reflected by the metamaterial-based reflector 100A, that is, reflected light L20 may maintain a linearly polarized state of incident light (L10 in FIG. 1A). That is, the reflected light L20 may be linearly polarized by + 45 ° with respect to the X axis.

2A is a plan view showing an array of first nanostructures n10 included in the first metamaterial layer M10 of FIGS. 1A and 1B, and FIG. 2B is a second included in the second metamaterial layer M20 It is a plan view showing an array of nanostructures (n20).

Referring to FIG. 2A, a plurality of first nanostructures n10 may be arranged in parallel with each other along a first direction (eg, X-axis direction), and may be arranged in two dimensions.

Referring to FIG. 2B, the plurality of second nanostructures n20 may be arranged side by side along a second direction rotated by θ with respect to the first direction. Here, θ may be less than 90 °.

By changing the arrangement direction of the plurality of second nanostructures n20 with respect to the arrangement direction of the plurality of first nanostructures n10, the metamaterial-based reflector 100A composed of them is described with reference to FIGS. 1A and 1B. It can exhibit the optical properties as described.

3A and 3B are cross-sectional views illustrating a metamaterial-based reflector 100B according to another embodiment. 3A shows transmission characteristics of incident light, and FIG. 3B shows characteristics of reflected light.

3A and 3B, the metamaterial-based reflector 100B is on the first metamaterial layer M11 and the first metamaterial layer M11 including an array of a plurality of first nanostructures n11. As arranged, a second metamaterial layer M21 including an array of a plurality of second nanostructures n21 may be provided. The plurality of second nanostructures n21 may be arranged differently from the plurality of first nanostructures n11. For example, the plurality of first nanostructures n11 may be arranged side by side along the first direction, and the arrangement direction of the plurality of second nanostructures n21 may vary depending on the region of the second metamaterial layer M21. Can be changed. Reference numeral m11 denotes a first material layer, and m21 denotes a second material layer. The first meta-material layer M11 may be said to include a plurality of first nanostructures n11 and a first material layer m11 covering them, similarly, the second meta-material layer M21 may include a plurality of first meta-material layers M11. It can be said that it includes a second nanostructure (n21) and a second material layer (m21) covering them.

In this embodiment, the first metamaterial layer M11 may be a transmissive wave plate, and the second metamaterial layer M21 may be a reflective wave plate. For example, the first meta-material layer M11 may be a transmissive quarter wave plate, and the second meta-material layer M21 may be a reflective half wave plate. You can.

The metamaterial-based reflector 100B of this embodiment may function as a converging mirror or a diverging mirror. To this end, an arrangement rule of a plurality of second nanostructures n21 may be designed.

Referring to FIG. 3A, the metamaterial-based reflector 100B may be configured to circularly polarize light that transmits it, that is, transmitted light L31. When the incident light L11 is linearly polarized by + 45 ° to the X axis, the transmitted light L31 may be circularly polarized by the metamaterial-based reflector 100B.

Referring to FIG. 3B, light reflected by the metamaterial-based reflector 100B, that is, reflected light L21 may maintain a linearly polarized state of incident light (L11 in FIG. 3A). That is, the reflected light L21 may have a state that is linearly polarized by + 45 ° with respect to the X axis. The metamaterial-based reflector 100B may act as a converging mirror having a focal length f with respect to incident light linearly polarized by + 45 ° (L11 in FIG. 3A). To this end, the arrangement direction of the plurality of second nanostructures n21 may be changed according to the region of the second metamaterial layer M21, as described with reference to FIG. 4B. The reflected light L21 may have a converging wavefront having a focal length f. The metamaterial-based reflector 100B may act as a diverging mirror having a negative focal length, ie, -f, for incident light linearly polarized by -45 °.

Referring back to FIG. 3A, for the incident light L11 linearly polarized by + 45 °, the transmitted light L31 may be circularly polarized light having a converging wavefront corresponding to the focal length f.

FIG. 4A is a plan view showing an array of first nanostructures n11 included in the first metamaterial layer M11 of FIGS. 3A and 3B, and FIG. 4B is a second included in the second metamaterial layer M21 It is a plan view showing an array of nanostructures (n21).

Referring to FIG. 4A, the plurality of first nanostructures n11 may be arranged alongside each other along a first direction (eg, X-axis direction).

Referring to FIG. 4B, a plurality of second nanostructures n21 are arranged to rotate with respect to the first direction, and a rotation angle of the second nanostructures n21 may be changed according to an area. The rotation angle of the second nanostructure n21 may be gradually changed (increased) as it moves toward the outer side based on a predetermined point (eg, a center) of the second metamaterial layer M21. Thus, by changing the arrangement direction of the plurality of second nanostructures (n21) with respect to the arrangement direction of the plurality of first nanostructures (n11), by changing the rotation angle according to the region, metamaterial-based reflectors made of them (100B) ) May represent optical properties as described with reference to FIGS. 3A and 3B.

In the above embodiment, the first metamaterial layer (M10, M11) is a transmissive wave plate (transmissive wave plate), and the second metamaterial layer (M20, M21) is a reflective wave plate (reflective wave plate) Although described, according to another embodiment, the first meta-material layer may be a first transmissive wavelength plate, and the second meta-material layer may be a second transmissive wavelength plate. As such, when both the first and second metamaterial layers are transmissive wavelength plates, a separate mirror member, for example, a distributed Bragg reflector (DBR), may be further provided on the second metamaterial layer. . This will be described in more detail with reference to FIGS. 5A to 8B.

5A and 5B are cross-sectional views illustrating a metamaterial-based reflector 100C according to another embodiment. Figure 5a shows the transmission characteristics of the incident light, Figure 5b shows the characteristics of the reflected light.

5A and 5B, the metamaterial-based reflector 100C is formed on the first metamaterial layer M12 and the first metamaterial layer M12 including an array of a plurality of first nanostructures n12. As it is disposed, a second metamaterial layer M22 including an array of a plurality of second nanostructures n22 may be provided. The plurality of second nanostructures n22 may be arranged differently from the plurality of first nanostructures n12. For example, the plurality of first nanostructures n12 may be arranged alongside each other along the first direction, and the plurality of second nanostructures n22 may be arranged in a direction different from the first direction. Reference numeral m12 denotes a first material layer, and m22 denotes a second material layer.

In this embodiment, the first meta-material layer M12 may be a first transmissive wave plate, and the second meta-material layer M22 may be a second transmissive wave plate. In this case, the metamaterial-based reflector 100C may further include a separate mirror member provided on the second metamaterial layer M22, for example, a distributed Bragg reflector (DBR) (R12). . The second meta-material layer M22 may be designed as a transmissive type according to the material, shape, size, pattern spacing, etc. of the second nanostructure n22, and may function as a transmissive wavelength plate. The dispersion Bragg reflector R12 may be formed by alternately stacking two layers of materials having different refractive indices alternately at a thickness of about 1/4 of the oscillation wavelength. The reflectance of the dispersion Bragg reflector R12 may be controlled by adjusting the difference in refractive index between the two material layers of the dispersion Bragg reflector R12 and the number of times the pair of the two material layers are repeatedly stacked. The dispersion Bragg reflector R12 may be formed by alternately laminating amorphous silicon (a-Si) and silicon oxide (SiO ₂ ), but is not limited thereto, and the materials used may be different. Various materials that can form the difference in refractive index can be used.

Referring to FIG. 5A, the metamaterial-based reflector 100C may be configured to linearly polarize the light that transmits it, that is, the transmitted light L32. When the incident light L12 is linearly polarized by + 45 ° with respect to the X axis, the transmitted light L32 may be linearly polarized by -45 ° by the metamaterial-based reflector 100C.

Referring to FIG. 5B, the light reflected by the metamaterial-based reflector 100C, that is, the reflected light L22 may maintain a linearly polarized state of the incident light (L12 in FIG. 5A). That is, the reflected light L22 may have a state that is linearly polarized by + 45 ° with respect to the X axis.

FIG. 6A is a plan view showing an array of first nanostructures n12 included in the first metamaterial layer M12 of FIGS. 5A and 5B, and FIG. 6B is a second included in the second metamaterial layer M22 It is a top view showing an array of nanostructures (n22).

Referring to FIG. 6A, the plurality of first nanostructures n12 may be arranged alongside each other along a first direction (eg, an X-axis direction).

Referring to FIG. 6B, the plurality of second nanostructures n22 may be arranged side by side along a second direction rotated by θ with respect to the first direction. Here, θ may be less than 90 °.

By changing the arrangement direction of the plurality of second nanostructures n22 with respect to the arrangement direction of the plurality of first nanostructures n12, the metamaterial-based reflector 100C composed of them is described with reference to FIGS. 5A and 5B. It can exhibit the optical properties as described. The phase of the reflected light (L22 in FIG. 5B) can be controlled by adjusting the arrangement direction (rotation angle) of the second nanostructure n22 with respect to the arrangement direction of the first nanostructure n12.

When the incident light (input light) is polarized along any one of the polarization eigenstates of the metamaterial-based reflector 100C, when the incident light passes through the first metamaterial layer M12, its polarization is "elliptical polarization ”. When the elliptical polarized light passes through the second metamaterial layer M22, its polarization may be converted into linear polarization. In a special case in which the first metamaterial layer M12 acts as a quarter wave plate, the polarization state of light between the first and second metamaterial layers M12 and M22 is circular. You can.

7A and 7B are cross-sectional views illustrating a metamaterial-based reflector 100D according to another embodiment. 7A shows the transmission characteristics of incident light, and FIG. 7B shows the characteristics of reflected light.

7A and 7B, the metamaterial-based reflector 100D is formed on the first metamaterial layer M13 and the first metamaterial layer M13 including an array of a plurality of first nanostructures n13. As arranged, a second metamaterial layer M23 including an array of a plurality of second nanostructures n23 may be provided. The plurality of second nanostructures n23 may be arranged differently from the plurality of first nanostructures n13. For example, the plurality of first nanostructures n13 may be arranged side by side along the first direction, and the arrangement direction of the plurality of second nanostructures n23 may vary depending on the region of the second metamaterial layer M23. Can be changed. Reference numeral m13 denotes a first material layer, and m23 denotes a second material layer.

In this embodiment, the first meta-material layer M13 may be a first transmissive wavelength plate, and the second meta-material layer M23 may be a second transmissive wavelength plate. In this case, the metamaterial-based reflector 100D may further include a separate mirror member provided on the second metamaterial layer M23, for example, a distributed Bragg reflector (DBR) (R13). .

The metamaterial-based reflector 100D of this embodiment may function as a converging mirror or a diverging mirror. To this end, an arrangement rule of a plurality of second nanostructures n23 may be designed.

Referring to FIG. 7A, the metamaterial-based reflector 100D may be configured to linearly polarize light that transmits it, that is, transmitted light L33. When the incident light L13 is linearly polarized by + 45 ° with respect to the X-axis, the transmitted light L33 may maintain a linearly polarized state by + 45 °.

Referring to FIG. 7B, light reflected by the metamaterial-based reflector 100D, that is, reflected light L23 may maintain a linearly polarized state of incident light (L13 in FIG. 7A). That is, the reflected light L23 may have a state that is linearly polarized by + 45 ° with respect to the X axis. The metamaterial-based reflector 100D may function as a converging mirror having a focal length f with respect to incident light linearly polarized by + 45 ° (L13 in FIG. 7A), that is, a focusing mirror. . To this end, the arrangement direction of the plurality of second nanostructures n23 may be changed according to the region of the second metamaterial layer M23, as described with reference to FIG. 8B. The reflected light L23 may have a converging wavefront having a focal length f. The metamaterial-based reflector 100D may act as a diverging mirror having a negative focal length, that is, -f for incident light linearly polarized by -45 °.

Referring to FIG. 7A again, for incident light L13 linearly polarized by + 45 °, transmitted light L33 may be linearly polarized light having a converging wavefront corresponding to a focal length of 1/2 (ie, f / 2).

8A is a plan view showing an array of first nanostructures n13 included in the first metamaterial layer M13 of FIGS. 7A and 7B, and FIG. 8B is a second included in the second metamaterial layer M23 It is a plan view showing an array of nanostructures (n23).

Referring to FIG. 8A, the plurality of first nanostructures n13 may be arranged alongside each other along a first direction (eg, an X-axis direction).

Referring to FIG. 8B, a plurality of second nanostructures n23 are arranged to be rotated with respect to the first direction, and a rotation angle of the second nanostructures n23 may be changed according to a region. The rotation angle of the second nanostructure n23 may gradually change (increase) as it moves toward the outer side based on a predetermined point (eg, a center) of the second metamaterial layer M23. Thus, by changing the arrangement direction of the plurality of second nanostructures (n23) with respect to the arrangement direction of the plurality of first nanostructures (n13), by changing the rotation angle according to the region, the metamaterial-based reflector composed of them (100D) ) May represent optical properties as described with reference to FIGS. 7A and 7B.

Embodiments of the present application can implement a metamaterial-based reflector that can easily control the properties of light such as polarization and convergence / emission. In a bilayer metasurface mirror including two metamaterial layers, the arrangement direction of one nanostructure (ie meta-atoms) of the two metamaterial layers and the arrangement direction of another nanostructure (ie meta-atoms) By rotating with respect to, the reflection phase of the bilayer metasurface mirror can be changed. The bilayer metasurface mirror can be used to form a Fabry-Perot resonator cavity, and the resonant wavelength of the Fabry-Perot resonator cavity is the rotation of a nanostructure (ie meta-atoms) of one of the two metamaterial layers. It can be adjusted by angle. In addition, by changing the rotation angle of one nanostructure (ie meta-atoms) with respect to the arrangement direction of one of the two nanomaterial layers (ie meta-atoms) according to the region, a converging mirror or A divergent mirror can be produced.

Each of the first and second metamaterial layers M12 and M22 in the metamaterial-based reflector 100C described with reference to FIGS. 5A to 6B is transmissive and may have birefringent characteristics, and thus, at least partially It can act as a wave plate (ie, a phase retarder). A separate mirror member, for example, a distributed Bragg reflector (DBR) R12, may be further provided on the second metamaterial layer M22. When the second metamaterial layer M20 is designed as a reflective type, such as the metamaterial-based reflector 100A of FIGS. 1A to 2B, the separate mirror members ex and DBR may be excluded.

Assuming that the X-axis is the fast axis of the first meta-material layer M12, and the angle between the fast axes of the first and second meta-material layers M12 and M22 is θ, the Jones matrix for the entire layer (Jones matrix) ) Is given as in Equation 1 below.

In Equation 1, Γ ₁ is a retardation caused by the first metamaterial layer M12, Γ ₂ is a delay caused by the second metamaterial layer M22, and W (Γ) is a wavelength plate having a phase delay. Of Jones matrix, R (θ) means a rotation matrix (rotation matrix). After the incident light passes through the first meta-material layer M12, passes through the second meta-material layer M22, then passes through the second meta-material layer M22 in the opposite direction, and then the first meta-material layer (M12). Here, W (Γ) may be equal to Equation 2 below.

Equation 2 is a Jones matrix of a wave plate having a retardation of Γ. In addition, R (θ) may be as shown in Equation 3 below.

Equation 3 is a rotation matrix. When both the first and second metamaterial layers M12 and M22 act as quarter wave plates, that is, when Γ ₁ = Γ ₂ = π / 2, the T matrix is It can be expressed as 4.

The two polarization eigenstates of T can be linearly polarized along ± 45 ° with respect to the X axis. The reflection phase for these two polarizations may be equal to ± 2θ, and can be adjusted by rotating the optical axis of the second metamaterial layer M22 with respect to the optical axis of the first metamaterial layer M12. When the first metamaterial layer M12 is not a quarter wave plate, that is, Γ ₁ ≠ π / 2, polarization eigenstates may be linearly polarized, Phase shifts less than 2π can be achieved by changing θ.

In FIGS. 5A and 5B, the reflection coefficient for the incident light L12 linearly polarized by + 45 ° with respect to the X axis of the metamaterial-based reflector 100C may be e ^{− j2θ} . That is, if the incident light L12 is 1, the reflected light L22 may be e ^{− j2θ} . In addition, the reflection efficiency for incident light linearly polarized by -45 ° with respect to the X axis of the metamaterial-based reflector 100C may also be e ^{− j2θ} . In FIGS. 1A and 1B, the reflection efficiency for the incident light L10 linearly polarized by + 45 ° (or -45 °) with respect to the X axis of the metamaterial-based reflector 100A may also be e ^{− j2θ} .

In the above embodiments, the first nanostructures n10 to n13 and the second nanostructures n20 to n23 may have a shape dimension of a subwavelength. Here, the shape dimension of the sub-wavelength means that the thickness or width, which is a dimension defining the shape of the nanostructures (n10 to n13, n20 to n23), is smaller than the operating wavelengths of the reflectors 100A to 100D. The operating wavelength of the reflectors 100A to 100D may mean an oscillation wavelength or a resonance wavelength. At least one of the thickness, width, and spacing (ie, pitch) of the nanostructures (n10 to n13, n20 to n23) may be 1/2 or less of an oscillation wavelength or a resonance wavelength.

Nanostructures (n10 to n13, n20 to n23) may be formed of a dielectric or semiconductor material. For example, nanostructures (n10 to n13, n20 to n23) are single crystal silicon, poly-crystalline Si, amorphous silicon, Si ₃ N ₄ , GaP, TiO ₂ , AlSb, AlAs, AlGaAs, AlGaInP, BP, ZnGeP ₂ may include any one of the materials. Alternatively, the nanostructures (n10 to n13, n20 to n23) may be made of a conductive material. As the conductive material, a highly conductive metal material capable of surface plasmon excitation may be employed. For example, at least one selected from Cu, Al, Ni, Fe, Co, Zn, Ti, Ru, Rh, Pd, Pt, Ag, Os, Ir, Pt, and Au may be employed, and any one of them may be included. It may be made of an alloy. In addition, a two-dimensional material having good conductivity, such as graphene, or a conductive oxide may be employed. The nanostructures (n10 to n13, n20 to n23) may be made of a group III-V semiconductor compound. Alternatively, some of the plurality of nanostructures (n10 to n13, n20 to n23) may be made of a high refractive index dielectric material, and other parts may be made of a conductive material.

The nanostructures (n10 to n13, n20 to n23) may be anisotropic nanoelements or include anisotropic nanoelements. Nanostructures (n10 to n13, n20 to n23) may have a long axis and a short axis on the XY plane. The dimension in the long axis direction may be referred to as the length L, and the dimension in the short axis direction may be referred to as the width W. Meanwhile, the dimension in the Z-axis direction may be referred to as thickness (T) or height (H). The length L may be larger than the width W, and the nanostructures n10 to n13 and n20 to n23 on the XY plane may have a rectangular shape or the like. The nanostructures (n10 to n13, n20 to n23) have a generally rectangular shape, and their edges may have a rounded shape. The nanostructures (n10 to n13, n20 to n23) may have an oval shape or the like. The nanostructures (n10 to n13, n20 to n23) may have a cross shape or a similar shape.

The metamaterial-based reflector according to the embodiments may be applied to an optical Fabry-Perot cavity structure. Arranging a plurality of Fabry-Perot cavity structures, but arranging a plurality of Fabry-Perot cavity structures having different wavelengths and / or different beam profiles on the same chip, an optical narrowband filter ( optical narrowband filters, laser cavities, or sensors.

9 is a cross-sectional view showing an optical cavity structure using an metamaterial-based reflector according to an embodiment. The cavity structure of this embodiment is a metamaterial-based reflector described with reference to FIGS. 1A and 1B.

Referring to FIG. 9, the optical cavity structure includes an active layer 70 and a distributed Bragg reflector (DBR) 50 and an active layer 70 disposed on a first surface (eg, a lower surface) of the active layer 70. It may include a meta-material-based reflector (100A) disposed on the second surface (eg, the upper surface). Here, the metamaterial-based reflector 100A may be the same as the reflector 100A described with reference to FIGS. 1A and 1B. The active layer 70 may be disposed between the dispersion Bragg reflector 50 and the metamaterial-based reflector 100A. The active layer 70 may be a gain layer including a gain medium, and may serve to generate light. The active layer 70 may include, for example, a quantum well or a quantum dot, and may have a single layer or multi-layer structure.

The metamaterial-based reflector 100A includes a plurality of second nanostructures n20 on a first metamaterial layer M10 and a first metamaterial layer M10 including an array of a plurality of first nanostructures n10. A second meta-material layer (M20) including an array of may be provided, where the plurality of second nanostructures (n20) may be arranged differently from the plurality of first nanostructures (n10). Since the specific structure and function of the metamaterial-based reflector 100A are as described with reference to FIGS. 1A to 2B, repeated descriptions thereof are excluded.

The arrows L10a and L20a shown in the active layer 70 in FIG. 9 indicate light resonating between the dispersion Bragg reflector 50 and the metamaterial-based reflector 100A, and the arrows shown above the optical element (cavity structure) (L30a) represents the emitted light (laser). The resonant and amplified light (laser) between the distributed Bragg reflector 50 and the metamaterial-based reflector 100A may be emitted outside the optical element (cavity structure) under certain conditions. The emission light L30a may be circularly polarized light. The resonant wavelength of the cavity structure may be changed by a rotation angle of the plurality of second nanostructures n20 with respect to the plurality of first nanostructures n10.

10 is a cross-sectional view showing an optical cavity structure to which a metamaterial-based reflector according to another embodiment is applied. The cavity structure of this embodiment is a metamaterial-based reflector described with reference to FIGS. 3A and 3B.

Referring to FIG. 10, the optical cavity structure includes an active layer 70 and a dispersion Bragg reflector (DBR) 50 disposed on a first surface (lower surface) of the active layer 70 and a second surface (top surface) of the active layer 70. It may include a meta-material-based reflector (100B) disposed in. Here, the metamaterial-based reflector 100B may be the same as the reflector 100B described with reference to FIGS. 3A and 3B. The metamaterial-based reflector 100B includes a plurality of second nanostructures (n21) on a first metamaterial layer (M11) and a first metamaterial layer (M11) including an array of a plurality of first nanostructures (n11). A second meta-material layer M21 including an array of may be provided, where the plurality of second nanostructures n21 may be arranged differently from the plurality of first nanostructures n11. The specific structure and function of the metamaterial-based reflector 100B may be as described with reference to FIGS. 3A to 4B.

The arrows L11a and L21a shown in the active layer 70 in FIG. 10 indicate light resonating between the dispersion Bragg reflector 50 and the metamaterial-based reflector 100B, and the arrows shown above the optical element (cavity structure) (L31a) represents the emitted light (laser). The reflected light L21a reflected by the metamaterial-based reflector 100B may have a converging wavefront. The emission light L31a may be circularly polarized light having a converging wavefront.

11 is a cross-sectional view showing an optical cavity structure using a metamaterial-based reflector according to another embodiment. The cavity structure of this embodiment is a metamaterial-based reflector described with reference to FIGS. 5A and 5B.

Referring to FIG. 11, the optical cavity structure may include a dispersion Bragg reflector (DBR) 50, an active layer 70 and a metamaterial-based reflector 100C. Here, the metamaterial-based reflector 100C may be the same as the reflector 100C described with reference to FIGS. 5A and 5B. The metamaterial-based reflector 100C includes a plurality of second nanostructures (n22) on a first metamaterial layer (M12) and a first metamaterial layer (M12) including an array of a plurality of first nanostructures (n12). A second meta-material layer (M22) including an array of may be provided, and may further include a separate dispersion Bragg reflector (DBR) (R12) provided on the second meta-material layer (M22). . The specific structure and function of the metamaterial-based reflector 100C may be as described with reference to FIGS. 5A to 6B.

The arrows L12a and L22a shown in the active layer 70 in FIG. 11 indicate light resonating between the dispersion Bragg reflector 50 and the metamaterial-based reflector 100C, and the arrows shown above the optical element (cavity structure) (L32a) represents the emitted light (laser). The emission light L32a may be linearly polarized light.

12 is a cross-sectional view showing an optical cavity structure to which a metamaterial-based reflector according to another embodiment is applied. The cavity structure of this embodiment is a metamaterial-based reflector described with reference to FIGS. 7A and 7B.

Referring to FIG. 12, the optical cavity structure may include a dispersion Bragg reflector (DBR) 50, an active layer 70 and a metamaterial-based reflector 100D. Here, the metamaterial-based reflector 100D may be the same as the reflector 100D described with reference to FIGS. 7A and 7B. The metamaterial-based reflector 100D includes a plurality of second nanostructures (n23) on a first metamaterial layer (M13) and a first metamaterial layer (M13) including an array of a plurality of first nanostructures (n13). A second metamaterial layer (M23) including an array of may be provided, and a separate dispersion Bragg reflector (DBR) (R13) provided on the second metamaterial layer (M23) may be further included. The specific structure and function of the metamaterial-based reflector 100D may be as described with reference to FIGS. 7A to 8B.

The arrows L13a and L23a shown in the active layer 70 in FIG. 10 indicate light resonating between the dispersion Bragg reflector 50 and the metamaterial-based reflector 100D, and the arrows shown above the optical element (cavity structure) (L33a) represents emitted light (laser). The reflected light L23a reflected by the metamaterial-based reflector 100D may have a converging wavefront. The emission light L33a may be linearly polarized light and may have a flat wavefront. Due to the resonance characteristics in the cavity structure, the emission light L33a may have a flat wavefront rather than a converging wavefront.

9 to 12 illustrate and describe a case in which a cavity structure is formed using a distributed Bragg reflector (DBR) 50 at the bottom and metamaterial-based reflectors 100A to 100D at the top, according to another embodiment, A cavity structure may be configured by applying a first metamaterial-based reflector to the lower portion and a second metamaterial-based reflector to the upper portion. That is, the cavity structure may be configured by applying the metamaterial-based reflector according to the embodiment above and below the active layer 70, respectively.

13 is a cross-sectional view showing a vertical cavity surface emitting laser (VCSEL) including an optical cavity structure to which a metamaterial-based reflector is applied according to an embodiment.

Referring to FIG. 13, the vertical resonant surface emitting laser is a gain layer 270 generating light, a distributed Bragg reflector 250 disposed under the gain layer 270, and an upper portion of the gain layer 270. It may include a meta-material-based reflector 150.

The gain layer 270 may include an active layer including a semiconductor material. The active layer may include, for example, a III-V semiconductor material or a II-VI semiconductor material. As a specific example, the active layer may include a multi-quantum well (MQW) structure including InGaAs, AlGaAs, AlGaN, InGaAsP, InGaP or AlGaInP. Also, the active layer may include a quantum dot. The material or composition of the active layer is not limited to those illustrated and may vary. The gain layer 270 may further include a first clad layer and a second clad layer provided below and above the active layer. The first clad layer and the second clad layer may each include an n-type or p-type or intrinsic semiconductor material. The first clad layer and the second clad layer may be made of a semiconductor material such as an active layer, and may further include an n-type dopant or a p-type dopant.

The metamaterial-based reflector 150 and the distributed Bragg reflector 250 disposed above and below the gain layer 270 oscillate the light generated from the gain layer 270 to amplify and emit light in a specific wavelength band. Can be. To this end, the reflectivity of the dispersion Bragg reflector 250 and the metamaterial-based reflector 150 may be set to approximately 90% or more. The reflectance of the distributed Bragg reflector 250 may be higher than that of the metamaterial-based reflector 150, for example, about 98% or more, so that light can be emitted through the metamaterial-based reflector 150. In some cases, it is also possible to adjust the reflectance of the dispersion Bragg reflector 250 and the metamaterial-based reflector 150 to reversely control the direction in which light is emitted.

The dispersion Bragg reflector 250 may be formed by alternately stacking the first material layer 251 and the second material layer 252 having different refractive indices alternately to a thickness of about 1/4 of a desired oscillation wavelength. The distributed Bragg reflector 250 may be formed on the semiconductor substrate 200. The reflectance of the dispersion Bragg reflector 250 can be set to a desired value by adjusting the difference in refractive index between the two material layers 251 and 252 of the dispersion Bragg reflector 250 and the number of times the pair of the two material layers 251 and 252 are repeatedly stacked have. The dispersion Bragg reflector 250 may be formed to include a material of the same or similar series as the semiconductor material constituting the gain layer 270. For example, the first material layer 251 may be an Al _x Ga _(1-x) As layer (where x is 0≤x≤1) and the second material layer 252 may be Al _y Ga _{(1- y)} As layer (where y is 0≤y≤1, x ≠ y), but is not limited thereto. The distributed Bragg reflector 250 may be doped with n-type or p-type. The material of the dispersion Bragg reflector 250 is not limited to the above, and various materials capable of forming a difference in refractive index may be used for the first material layer 251 and the second material layer 252.

The vertical resonant surface emitting laser may further include an aperture layer 275 for adjusting the mode or beam size of the oscillated light. The opening layer 275 may be formed of a predetermined oxide. Here, the opening layer 275 is illustrated as being formed on the gain layer 270, but is not limited thereto. For example, the opening layer 275 may be disposed within the dispersion Bragg reflector 250. In addition, a plurality of opening layers 275 may be provided, or may be omitted. A contact layer 280 in contact with the gain layer 270 may be further provided on the opening layer 275. The contact layer 280 may be formed of a semiconductor material of the same type or similar type as the gain layer 270. The contact layer 280 may be doped with predetermined impurities.

The vertical resonant surface emitting laser may further include a first electrode 210 and a second electrode 290 spaced apart from the gain layer 270 to inject current into the gain layer 270. have. The first electrode 210 may be disposed to be electrically connected to the first surface of the gain layer 270, and the second electrode 290 may be electrically connected to the second surface of the gain layer 270. The first electrode 210 may be disposed on the substrate 200 exposed to the side of the dispersion Bragg reflector 250. The second electrode 290 may be disposed at an edge portion of the contact layer 280 and may be electrically connected to the gain layer 270 through the contact layer 280. However, the arrangement of the first and second electrodes 210 and 290 disclosed herein is exemplary and may be variously changed. For example, the first electrode 210 may be formed on the bottom surface of the dispersion Bragg reflector 250 or the bottom surface of the substrate 200.

The metamaterial-based reflector 150 includes a plurality of second nanostructures n25 on a first metamaterial layer M15 and a first metamaterial layer M15 including an array of a plurality of first nanostructures n15. A second metamaterial layer M25 including an array of may be provided, where the plurality of second nanostructures n25 may be arranged differently from the plurality of first nanostructures n15. Since the specific structure and function of the metamaterial-based reflector 150 are as described with reference to FIGS. 1A to 2B, repeated descriptions thereof are excluded. The metamaterial-based reflector 150 may be replaced with the reflector 100B described with reference to FIGS. 3A to 4B.

In FIG. 13, the arrow illustrated in the gain layer 270 represents light resonating between the distributed Bragg reflector 250 and the metamaterial-based reflector 150, and the arrow illustrated above the optical element (ie, VCSEL) is emitted. Light (laser). Resonant and amplified light (laser) between the distributed Bragg reflector 250 and the metamaterial-based reflector 150 may be emitted outside the optical element when a specific condition is reached. The emitted light can be circularly polarized.

14 is a cross-sectional view showing a vertical resonant surface emitting laser (VCSEL) including an optical cavity structure to which a metamaterial-based reflector is applied according to another embodiment.

Referring to FIG. 14, the metamaterial-based reflector 170 includes a plurality of first metamaterial layers M17 and a first metamaterial layer M17 including an array of a plurality of first nanostructures n17. A second metamaterial layer (M27) including an array of 2 nanostructures (n27) may be provided, and a separate distributed Bragg reflector (DBR) (R17) provided on the second metamaterial layer (M27) It may further include. The specific structure and function of the metamaterial-based reflector 170 may be as described with reference to FIGS. 5A to 6B. The metamaterial-based reflector 170 may be replaced with the reflector 100D described with reference to FIGS. 7A to 8B. The rest of the components except the metamaterial-based reflector 170 may be the same or similar to those described with reference to FIG. 13.

The arrow shown in the gain layer 270 in FIG. 14 represents light resonating between the dispersion Bragg reflector 250 and the metamaterial-based reflector 170, and the arrow shown above the optical element (ie, VCSEL) is emitted. Light (laser). The outgoing light can be linearly polarized.

In the above embodiments, the case where the metamaterial-based reflector includes two metamaterial layers has been described and described, but the metamaterial-based reflector includes three or more metamaterial layers arranged in the direction of light travel (vertical direction in the drawing). You may. Further, according to another embodiment, the metamaterial-based reflector may include one metamaterial layer and a mirror member, for example, a distributed Bragg reflector (DBR). This will be described in more detail with reference to FIGS. 15A to 15C.

15A is a cross-sectional view showing a vertical resonant surface emitting laser (VCSEL) including an optical cavity structure to which a metamaterial-based reflector is applied according to another embodiment.

Referring to FIG. 15A, the metamaterial-based reflector 190 includes a metamaterial layer M19 including an array of a plurality of nanostructures n19 and a distributed Bragg reflector (DBR) provided on the metamaterial layer M19 ( R19). A predetermined insertion layer N19 may be further provided between the metamaterial layer M19 and the contact layer 280 and the second electrode 290. The insertion layer N19 may be regarded as being included in the reflector 190. In some cases, the insertion layer N19 may not be provided. Other components except the metamaterial-based reflector 190 may be the same or similar to those described with reference to FIG. 13. The metamaterial-based reflector 190 includes one metamaterial layer M19 and a general mirror member, that is, a distributed Bragg reflector (DBR) R19. In this case, the metamaterial layer M19 may be a transmissive birefringent metasurface layer. The dispersion Bragg reflector (DBR) R19 may have, for example, a structure in which a-Si and SiO ₂ are alternately stacked, but the constituent materials may be different.

The arrow illustrated in the gain layer 270 in FIG. 15A represents light resonating between the distributed Bragg reflector 250 and the metamaterial-based reflector 190, and the arrow illustrated above the optical element (ie, VCSEL) is emitted. Light (laser). The emitted light may be linearly polarized light, and its wavelength may be adjusted by the design of the metamaterial-based reflector 190.

15B is an exploded cross-sectional view of the vertical resonant surface emitting laser (VCSEL) of FIG. 15A.

Referring to FIG. 15B, a vertical resonant surface emitting laser (VCSEL) has a structure in which a lower dispersion Bragg reflector 250 and an upper metamaterial-based reflector 190 are added to a gain layer 270 of a core. It can be said to have. At this time, the distributed Bragg reflector 250 may have a reflectance corresponding to R ₁ , and the metamaterial-based reflector 190 may have a reflectance corresponding to R ₂ . The reflectance R ₁ may be greater than the reflectance R ₂ .

15C is a plan view exemplarily showing an array of a plurality of nanostructures n19 included in the metamaterial layer M19 of FIG. 15B.

15C, a plurality of nanostructures n19 may be arranged in a predetermined direction. The plurality of nanostructures n19 may have a rectangular shape having a width of W _{x in} the X-axis direction and a width of W _{y in} the Y-axis direction. For example, the plurality of nanostructures (n19) may have a pillar shape formed of amorphous silicon (a-Si). However, the constituent materials and shapes of the plurality of nanostructures (n19) may be variously changed. For example, the plurality of nanostructures n19 may make a planar structure on the XY plane into a rectangular or elliptical structure or similar anisotropic structure.

FIG. 16 is a graph showing reflectivity and phase change for the substructure of VCSEL of FIG. 15B. That is, the reflectivity and phase change by the distributed Bragg reflector 250 are shown. Referring to FIG. 16, the dispersion Bragg reflector 250 exhibits high reflectance in a wavelength range of about 900 nm to 1000 nm.

FIG. 17 is a graph showing the reflection phase of the superstructure of the VCSEL of FIG. 15B, that is, the metamaterial-based reflector 190. (A) Graph is the result for X-polarized light, (B) Graph is the result for Y-polarized light.

Referring to FIG. 17, the reflectivity phase for X-polarized light can be changed to 2π or more at a wavelength of 900 nm to 1000 nm by changing W _x . Accordingly, the resonance wavelength of the metamaterial-based reflector 190 for X-polarized light can be adjusted by changing W _x . On the other hand, by changing W _x as a condition that can remove the Y-polarized resonance within the wavelength range of interest, the reflection phase for the Y-polarized light can be changed to less than 2 radians. At this time, the nanostructure (n19) is a-Si nano-posts, has a height of 420nm, Wy is 100nm, lattice constant (lattice constant) was 400nm. The distributed Bragg reflector R19 has 4 pairs of a-Si / SiO ₂ .

18 and 19 are images showing an array of nanostructures of a metamaterial layer that can be applied to a metamaterial-based reflector according to an embodiment.

Referring to FIGS. 18 and 19, the meta-material layer may include cylinder-shaped nano-structures having high refractive index. At this time, the nano-structure (meta-atoms) may have a rectangular or oval cross-section. The metamaterial layer of FIGS. 18 and 19 may be a transmissive birefringent meta surface layer.

Although many matters are specifically described in the above description, they should be interpreted as examples of specific embodiments rather than limiting the scope of the invention. For example, those of ordinary skill in the art, various configurations of metamaterial-based reflectors, optical cavity structures, vertical resonant surface emitting lasers (VCSELs), and optical elements described with reference to FIGS. 1A to 15C are various. You will see that it can change. As a specific example, the array configuration of the first and second metamaterial layers may be variously changed, three or more metamaterial layers may be combined, and the configuration of the vertical resonant surface emitting laser (VCSEL) may also be varied. You will see that you can. Therefore, the scope of the invention should not be determined by the described embodiments, but should be determined by the technical spirit described in the claims.

M10 to M13: first metamaterial layer M20 to M23: second metamaterial layer
m10 to m13: first material layer m20 to m23: second material layer
n10 to n13: first nanostructure n20 to n23: second nanostructure
L10 to L13: incident light L20 to L23: reflected light
L30 to L33: transmitted light R12, R13: distributed Bragg reflector
100A to 100D: metamaterial-based reflector 150, 170: metamaterial-based reflector
50: dispersion Bragg reflector 70: active layer
200: substrate 210: first electrode
250: distributed Bragg reflector 270: gain layer
280: contact layer 290: second electrode

Claims (24)

A first metamaterial layer including an array of a plurality of first nanostructures; And
It is disposed on the first meta-material layer, a second meta-material layer including an array of a plurality of second nano-structures; having, the plurality of second nano-structures are different from the plurality of first nano-structures Arranged,
Metamaterial-based reflector. The method of claim 1,
The arrangement direction and arrangement method of the plurality of second nanostructures are metamaterial-based reflectors different from the arrangement direction and arrangement method of the plurality of first nanostructures. According to claim 2,
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged in a direction different from the first direction or the arrangement direction of the plurality of second nanostructures is a metamaterial-based reflector that changes depending on the region. The method of claim 1,
The first meta-material layer is a transmissive wave plate,
The second metamaterial layer is a metamaterial-based reflector which is a reflective wave plate. The method of claim 4, wherein
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged side by side with each other along a second direction rotated by θ relative to the first direction, wherein θ is less than 90 ° metamaterial-based reflector. The method of claim 4, wherein
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged to be rotated with respect to the first direction, and the rotation angle of the second nanostructures is metamaterial-based reflector that changes depending on the region. The method of claim 4, wherein
The metamaterial-based reflector is a metamaterial-based reflector configured to circularly polarize light passing therethrough. The method of claim 4, wherein
A metamaterial-based reflector in which the arrangement rules of the plurality of second nanostructures are designed so that the metamaterial-based reflector functions as a converging mirror or a diverging mirror. The method of claim 1,
The first meta-material layer is a first transmissive wave plate,
The second meta-material layer is a second transmission type wave plate,
A metamaterial-based reflector further comprising a distributed Bragg reflector (DBR) disposed on the second metamaterial layer. The method of claim 9,
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged side by side with each other along a second direction rotated by θ relative to the first direction, wherein θ is less than 90 ° metamaterial-based reflector. The method of claim 9,
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged to be rotated with respect to the first direction, and the rotation angle of the second nanostructures is metamaterial-based reflector that changes depending on the region. The method of claim 9,
The metamaterial-based reflector is a metamaterial-based reflector configured to linearly polarize light passing therethrough. The method of claim 9,
A metamaterial-based reflector in which the arrangement rules of the plurality of second nanostructures are designed so that the metamaterial-based reflector functions as a converging mirror or a diverging mirror. An optical device comprising at least one metamaterial-based reflector according to any one of claims 1 to 13. A gain layer for generating light;
A distributed Bragg reflector disposed on the first surface of the gain layer; And
Includes a metamaterial-based reflector disposed on the second surface of the gain layer;
The metamaterial-based reflector includes a first metamaterial layer including an array of a plurality of first nanostructures; And a second metamaterial layer including an array of a plurality of second nanostructures on the first metamaterial layer, wherein the plurality of second nanostructures are arranged differently from the plurality of first nanostructures,
Optical cavity structure. The method of claim 15,
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged in a direction different from the first direction, or an optical cavity structure in which the arrangement directions of the plurality of second nanostructures vary depending on regions. The method of claim 15,
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged side by side with each other along a second direction rotated by θ with respect to the first direction, wherein θ is less than 90 °. The method of claim 15,
The plurality of first nanostructures are arranged alongside each other along the first direction,
The plurality of second nanostructures are arranged to be rotated with respect to the first direction, and the rotational angle of the second nanostructures varies according to an area. The method of claim 15,
The first meta-material layer is a transmissive wave plate,
The second meta-material layer is an optical cavity structure that is a reflective wave plate. The method of claim 15,
The first meta-material layer is a first transmissive wave plate,
The second meta-material layer is a second transmission type wave plate,
The metamaterial-based reflector further includes a separate dispersion Bragg reflector (DBR) disposed on the second metamaterial layer. The method of claim 15,
The metamaterial-based reflector is an optical cavity structure configured to circularly polarize light passing therethrough. The method of claim 15,
The metamaterial-based reflector is an optical cavity structure configured to linearly polarize light passing therethrough. The method of claim 15,
An optical cavity structure in which the arrangement rules of the plurality of second nanostructures are designed such that the metamaterial-based reflector acts as a converging mirror or a diverging mirror. A vertical cavity surface emitting laser comprising the optical cavity structure according to any one of claims 15 to 23.

Images