JP2007240641A - Surface light emitting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enhance the luminance of a light emitting surface by achieving a two-dimensional spread of emitted light. <P>SOLUTION: Waveguide mode light travelling along a rectangular waveguide core 10 is taken out as radiation mode light 200 in a direction approximately perpendicular to a side face of the rectangular waveguide core 10 by a second-order diffraction grating 11 formed on the side face of the rectangular waveguide core 10 and us taken out two-dimensionally by a plane guide sheet 20 which spreads in a direction of the side face of the rectangular core 10 and contains a fluorescent material or a diffusing material. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a technology of a planar light emitting device that emits light in a planar shape.

  Currently, light-emitting elements using waveguides are used in various technical fields. This waveguide is characterized in that light can be input and output only from the end face, and light does not leak outside the waveguide direction.

  On the other hand, there is a method of extracting light input to the waveguide (hereinafter referred to as “guided mode light”) on a line along the waveguide. Specifically, by forming a diffraction grating having a Bragg scattering order of second or higher in the direction along the waveguide, the waveguide mode light coupled to the diffraction grating can be extracted to the outside as radiation mode light.

  The light emitting device shown in FIG. 12 includes a planar waveguide core 10 having a diffraction grating 11 of the second-order Bragg scattering order formed on the upper surface, and a transparent planar waveguide sheet 20 surrounding the entire planar waveguide core 10. It is the composition which has. Further, in order to input light to the planar waveguide core 10, a light emitter 30 on the printed circuit board 32 is provided on one end face of the planar waveguide core 10.

The output from the light emitter 30 is input from one end face of the planar waveguide core 10. The input light travels along the planar waveguide core 10 as guided mode light 100. When the diffraction grating formed on the upper surface of the planar waveguide core 10 is second order, the radiation mode light 200 can be extracted from the upper and lower surfaces of the planar waveguide core 10 in a substantially vertical direction. Note that Patent Document 1 is known as a technique related to the present application.
JP 2000-151141 A

  However, by using the above-described waveguide and the diffraction grating formed in the waveguide, it is possible to change from a point light source to a linear light source, but as a wide planar light source, There was a problem that it was not visible.

  Further, since the radiation mode light is a loss for the waveguide mode light, there is a problem that the intensity of the waveguide mode light gradually attenuates as the waveguide mode light progresses.

  The present invention has been made in view of the above, and an object of the present invention is to first realize planar spread of light emission. Secondly, the luminance of the light emitting surface is improved.

  A planar light emitting device according to a first aspect of the present invention includes a rectangular waveguide core having a holographic optical structure for extracting guided mode light to the outside on all or a part of side surfaces along the longitudinal direction, and the rectangular waveguide. And a planar waveguide sheet extending in the side surface direction of the waveguide core.

  In the present invention, by having a holographic optical structure for extracting guided mode light to the outside on the side surface along the longitudinal direction, it is possible to emit more planar light than in the case of having the optical structure on the upper surface. Expansion can be realized.

  The planar light emitting device may further include a light emitter that emits light to be optically coupled to the rectangular waveguide core at one or both ends of the rectangular waveguide core.

  In the present invention, since the light emitting body optically coupled to the rectangular waveguide core is provided at both ends of the rectangular waveguide core, it is possible to compensate for a decrease in the intensity of the waveguide mode light at the far end, and a plane that is a light emitting surface. The luminance of the entire waveguide sheet can be improved and the luminance distribution can be easily controlled.

  The planar light emitting device has a plurality of the rectangular waveguide cores, each of the rectangular waveguide cores has a light emitter disposed at one or both ends, and the wavelength of the waveguide mode light that is optically coupled from the light emitters. However, it is different from the other rectangular waveguide cores.

  In the present invention, a plurality of rectangular waveguide cores are provided, and light emitters are arranged at one or both ends of each rectangular waveguide core, and the wavelength of the waveguide mode light that is optically coupled from each of the light emitters. Since it is different from the other rectangular waveguide cores, a mixed color of a plurality of shades can be obtained.

  In the planar light emitting device, the planar waveguide sheet includes at least one fluorescent material or wavelength conversion material that emits light when excited by the wavelength of the light emitter.

  In the present invention, the planar waveguide sheet includes a fluorescent material or a wavelength conversion material that emits light when excited by the wavelength of the light emitter, so that the radiation mode light extracted from the rectangular waveguide core is a light emitting surface. The planar waveguide sheet can be efficiently taken out in a planar shape.

  In the planar light emitting device, a light emitting body that emits light in which guided mode light having the same wavelength as that of blue or ultraviolet light is guided by optical coupling is disposed at one or both ends of the rectangular waveguide core, and the red, green The blue fluorescent material or the wavelength converting material is included in the planar waveguide sheet.

  In the present invention, each of the rectangular waveguide cores has a light emitting body that emits light in which guided mode light having the same wavelength as that of blue or ultraviolet light is guided by optical coupling, and red, green, and blue fluorescent light is disposed. By including the material or the wavelength conversion material in the planar waveguide sheet, white light emission can be obtained from the entire planar waveguide sheet as the light emitting surface.

  In the planar light emitting device, the planar waveguide sheet includes a material having an optical diffusion effect.

  In the present invention, since the planar waveguide sheet contains a material having an optical diffusion effect, the radiation mode light extracted from the rectangular waveguide core is diffused, and the planar waveguide sheet as a light emitting surface is planarized from the entire plane waveguide sheet. Can be taken out.

  In the planar light emitting device, the optical structure has a second or higher order Bragg diffraction grating with respect to the guided mode light.

  According to the present invention, it is possible to realize a broader spread of light emission and improve the luminance of the light emitting surface.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is a perspective view showing the first embodiment. The basic structure of the planar light emitting device in the present embodiment includes a rectangular waveguide core 10 having a secondary diffraction grating 11 on all side surfaces in the longitudinal direction, and a planar waveguide sheet 20 extending in the side surface direction of the rectangular waveguide core 10. This is a configuration provided. The planar waveguide sheet 20 includes diffusing particles 40 that are materials having an optical diffusion effect capable of diffusing and scattering light, and has a refractive index different from that of the planar waveguide sheet 20. It is formed of a transparent material. The second-order diffraction grating 11 is a diffraction grating having a periodic structure that generates radiation mode light by second-order Bragg scattering.

  In addition to this basic structure, a light emitting body 30 disposed at one end of the rectangular waveguide core 10 is provided. A condensing lens 31 is provided on the side surface of the light emitter 30 in order to increase the coupling efficiency to the rectangular waveguide core 10. The light emitter 30 uses, for example, an LED (Light Emitting Diode) chip. Since the LED chip is difficult to handle as it is, it can be packaged by providing an envelope. Hereinafter, for the light emitter 30, an LED is used.

  Next, the operation of the planar light emitting device in this embodiment will be described. The light output by the light emission of the LED 30 is coupled to one end face of the rectangular waveguide core 10 via the condenser lens 31. The combined light travels as guided mode light 100 along the rectangular waveguide core 10. The waveguide mode light 100 is extracted as radiation mode light 200 in a direction substantially perpendicular to the side surface of the rectangular waveguide core 10 by the secondary diffraction grating 11 formed on the side surface of the rectangular waveguide core 10. As the guided mode light 100 travels, the radiation mode light 200 is gradually emitted to the side surface of the rectangular waveguide core 10 and spreads two-dimensionally over the entire planar waveguide sheet 20. Thereafter, it is diffused (arrow A) by the diffusing particles 40 and taken out from the entire planar waveguide sheet 20 in a planar manner.

  According to the present embodiment, the waveguide mode light 100 traveling along the rectangular waveguide core 10 is converted into the side surface of the rectangular waveguide core 10 by the secondary diffraction grating 11 formed on the side surface of the rectangular waveguide core 10. Since the radiation mode light 200 can be extracted in a direction substantially perpendicular to the plane, it is possible to realize planar spread of light emission. Furthermore, since the extracted radiation mode light 200 can be diffused by the diffusing particles 40, planar light can be extracted more reliably.

  As shown in FIG. 2, the secondary diffraction grating 11 is formed on the upper surface of the rectangular waveguide core 10, and the output of the radiation mode light 200 is output from the upper and lower surfaces of the rectangular waveguide core 10 in a substantially vertical direction. It is also possible to take it out. When the extracted radiation mode light 200 is diffused (arrow B) by the diffusion plate 500, it can be visually recognized as a light emitting surface having a certain width. However, the light emission limited to the upper surface or the lower surface of the rectangular waveguide core 10 is mainly linear light emission along the rectangular waveguide core 10, and a plurality of light sources arranged in parallel to obtain planar light emission. It is necessary to close the rectangular waveguides. Therefore, as shown in the present embodiment, by outputting the radiation mode light 200 from the side surface of the rectangular waveguide core 10, more planar light can be obtained.

  FIG. 3 is a perspective view showing a first modification of the first embodiment shown in FIG. In addition to the basic configuration in the first embodiment, the basic configuration of the planar light emitting device in the present modification example is an LED 30b that is functionally the same as the LED 30a and the condensing lens 31a configured as the first embodiment, and The condensing lens 31 b is arranged at the other end of the rectangular waveguide core 10. Other configurations and basic operations are the same as those in the first embodiment, and thus description thereof is omitted here.

  According to this modification, the luminance of the entire planar waveguide sheet 20 can be improved by arranging the LEDs at both ends of the rectangular waveguide core 10. When light is incident only from one end face by the LED 30a, the waveguide mode light 100a traveling through the rectangular waveguide core 10 emits light energy as the radiation mode light 200 to the outside of the rectangular waveguide core 10, and thus the traveling direction The strength gradually decreases along the line. Further, if the depth and shape of the diffraction grating 11 are constant, the intensity of the guided mode light 100a is smaller at the far end, and therefore the intensity of the radiation mode light 200 radiated along the traveling direction at a constant rate is also proportional thereto. Then drop. Therefore, by using the guided mode light 100b by making the light incident from the far end by the LED 30b, it is possible to compensate for the decrease in intensity at the far end. Therefore, the luminance distribution on the light emitting surface can be easily controlled.

  FIG. 4 is a perspective view showing a second modification of the first embodiment shown in FIG. The basic configuration of the planar light emitting device in this modification is the same as the basic configuration in the first embodiment, but the region where the secondary diffraction grating is formed is different. That is, it is not formed on the entire side surface of the rectangular waveguide core 10, but is formed by being divided into secondary diffraction gratings 11a to 11c which are a plurality of regions. Other configurations and basic operations are the same as those in the first embodiment, and thus description thereof is omitted here.

  According to the present modification, the radiation mode light 200 is output from the region where the secondary diffraction gratings 11a to 11c are formed. Therefore, the regions other than 11a to 11c where the secondary diffraction grating is not formed are output. As stated in the background art, no light is emitted. Accordingly, the radiation mode light 200 can be output only to a necessary portion.

  Further, by changing the depth of the diffraction grating 11, the luminance distribution of the entire planar waveguide sheet 20 can be easily controlled. That is, if the depth of the diffraction grating is deeper, the ratio of conversion from the waveguide mode light 100 to the radiation mode light 200 becomes higher, so that the intensity of the radiation mode light 200 can be increased. On the other hand, light energy is dissipated from the rectangular waveguide core 10 as the radiation mode light 200 as the waveguide mode light 100 travels. That is, the intensity of the guided mode light 100 is large at the near end and small at the far end. Further, when the depth of the diffraction grating is constant, the intensity of the radiation mode light 200 is proportional to the intensity of the guided mode light 100. Therefore, the intensity of the radiation mode light 200 is similarly large at the near end and at the far end. Get smaller. Therefore, the radiation mode light 200 uniform in the direction of the rectangular waveguide core 10 can be obtained by making the depth of the diffraction grating shallow at the near end and processing deeper at the far end. Therefore, it is not necessary to fix the structure of the secondary diffraction grating, and various modifications can be made according to the purpose.

  FIG. 5 is a perspective view showing a third modification of the first embodiment shown in FIG. The basic configuration of the planar light emitting device in the present modification is basically the same as the basic configuration in the first embodiment, but instead of the diffusing particles 40 included in the planar waveguide sheet 20, a planar surface is provided. A light guide plate structure 21 is formed on the bottom surface of the waveguide sheet 20.

  The radiation mode light 200 extracted almost perpendicularly from the side surface of the rectangular waveguide core 10 is diffused (arrow C) by the light guide plate structure 21 and is extracted in a planar manner from the entire planar waveguide sheet 20. Other configurations and basic operations are the same as those in the first embodiment, and thus description thereof is omitted here.

  According to this modification, by having the light guide plate structure 21 on the bottom surface of the planar waveguide sheet 20, the radiation mode light 200 extracted from the rectangular waveguide core 10 is diffused, and the planar waveguide sheet 20 that is the light emitting surface is diffused. The entire surface can be taken out in a planar shape.

[Second Embodiment]
FIG. 6 is a perspective view showing the second embodiment. The basic structure of the planar light emitting device in this embodiment is basically the same as the basic configuration in the first embodiment, but has a plurality of rectangular waveguide cores 10a to 10c in parallel. In addition, a plurality of LEDs 30a to 30c and condenser lenses 31a to 31c corresponding to the rectangular waveguide cores 10a to 10c are provided.

  Here, the LEDs 30a to 30c output red (R), green (G), and blue (B) light, respectively. Further, the periods of the secondary diffraction gratings 11a to 11c formed on the side surfaces of the rectangular waveguide cores 10a to 10c are adjusted to the same wavelength period as that of RGB. Other configurations and basic operations are the same as those in the first embodiment, and thus description thereof is omitted here.

  According to the present embodiment, since the wavelengths of the radiation mode light emitted from the side surfaces of the rectangular waveguide cores 10a to 10c are different from each other, the light is mixed when diffused and scattered by the diffusion material 40, Mixtures of various shades can be obtained. In particular, in the case of RGB, planar white light emission can be obtained.

[Third Embodiment]
FIG. 7 is a perspective view showing the third embodiment. The basic structure of the planar light emitting device in the present embodiment is basically the same as the basic configuration in the first embodiment. However, instead of the diffusing particles 40 included in the planar waveguide sheet 20, fluorescence is used. A yellow phosphor (YAG or TAG) 41 that is a material or a wavelength conversion material is included in the planar waveguide sheet 20. The phosphor 41 is excited by the wavelength of the radiation mode light 200 extracted by the secondary diffraction grating as the light output by the light emission of the LED 30 travels as the waveguide mode light along the rectangular waveguide core 10. Flashes. The LED 30 outputs blue light (dominant wavelength is around 470 nm). Other configurations and basic operations are the same as those in the first embodiment, and thus description thereof is omitted here.

  According to the present embodiment, since the emission color output from the LED 30 is blue and the phosphor 41 is yellow, the yellow phosphor 41 is excited efficiently. That is, the phosphor 41 diffuses and scatters the blue radiation mode light 200 emitted from the secondary diffraction grating 11 formed on the side surface of the rectangular waveguide core 10 and simultaneously emits light in yellow. As a result, planar pseudo-white light emission in which blue and yellow which is a complementary color thereof are mixed can be obtained from the planar waveguide sheet 20. In addition, about the structure of 1st Embodiment (a 1st modification and a 2nd modification are included) and the structure of 2nd Embodiment, by changing the diffused particle 40 to the fluorescent substance 41, another structure is changed. The same effect as the third embodiment can be obtained. Moreover, about the structure of the 3rd modification of 1st Embodiment, by including the fluorescent substance 41 in the inside of the planar waveguide sheet 20, it is the same as that of this 3rd Embodiment, without changing another structure. An effect can be obtained.

[Fourth Embodiment]
FIG. 8 is a perspective view showing the fourth embodiment. The basic structure of the planar light emitting device in the present embodiment is basically the same as the basic configuration in the second embodiment, but instead of the diffusing particles 40 contained in the planar waveguide sheet 20, fluorescence Phosphors 41 a to 41 c that are materials or wavelength conversion materials are included in the planar waveguide sheet 20. The phosphors 41a to 41c are excited by the wavelength of the radiation mode light extracted by the secondary diffraction grating as the light output by the light emission of the LED travels as the waveguide mode light along the rectangular waveguide core. Flashes.

  Here, the LEDs 30a to 30c output blue or ultraviolet light. The phosphors 41a to 41c are red (R), green (G), and blue (B) phosphors, respectively. Other configurations and basic operations are the same as those in the first embodiment, and thus description thereof is omitted here.

  According to the present embodiment, since the emission color output from the LEDs 30a to 30c is blue or ultraviolet, the RGB phosphors 41a to 41c are excited efficiently. That is, light emission from the phosphors 41a to 41c can obtain planar white light emission as the three primary colors of visible light.

  The most efficient excitation wavelengths in the RGB phosphors 41a to 41c are slightly different. In order to excite all the phosphors 41a to 41c more efficiently, a light source that excites at a wavelength suitable for each excitation wavelength band is required. That is, the LEDs 30a to 30c need to be selected so that the phosphors 41a to 41c of the three primary colors of RGB emit light at a wavelength that is most efficiently excited. Further, the period of the diffraction grating is used so that the spectrum of the radiation mode light or the peak wavelength of this spectrum approximately matches the excitation wavelength band of the phosphors 41a to 41c or the peak wavelength of this excitation wavelength band. In particular, it is possible to further improve efficiency by distributing a large number of phosphors 41a to 41c around the rectangular waveguide core 10 to which efficient wavelengths are respectively coupled.

[Fifth Embodiment]
The waveguides (rectangular waveguide cores) described in the first to fourth embodiments are passive elements and are separated from the active elements that emit light. In the present embodiment, a case where the waveguide has a light emitting function of emitting light along its own longitudinal direction will be described. Specifically, the present embodiment can be applied on a semiconductor chip.

  As a light emitting element using a waveguide, for example, a semiconductor laser (LD) or an edge-emitting LED can be given. Unlike a surface-emitting LED that is widely used, a waveguide-type light-emitting element energizes a narrow stripe (waveguide / light-emitting region), and the stripe-shaped waveguide emits light. In the case of the LD, the light wave guided along the stripe repeatedly reflects on both cleavage end faces, thereby obtaining a gain and laser oscillation.

Next, the configuration of the present embodiment will be described. FIG. 9 is a perspective view showing the fifth embodiment. The planar light emitting device in this embodiment is applied to an AlInGaP / GaAs-based waveguide light emitting element. On an n-type GaAs substrate 1, an n-type (Al _x Ga _1-x ) _0.5 In _0.5 P cladding layer 2 (0 <x <1) and an undoped (Al _y Ga _{1- y} ) Continuous crystal growth of _0.5 In _0.5 P active layer 3 (0 <y <1, y <x), p-type (Al _x Ga _1-x ) _0.5 In _0.5 P cladding layer 4 To do. Next, a waveguide structure (hereinafter referred to as “mesa stripe”) 5 is formed on the uppermost portion (p side). A secondary diffraction grating 11 is formed on the side surface of the mesa stripe 5, and a ¼ wavelength phase shift 11 ′ is provided at the center of the side surface. An oxide film (SiO ₂ thin film) 17 is deposited on the portion where the gold wire 14 is bonded for insulation. A p-side electrode 8 is formed on the oxide film 17 and the mesa stripe 5. On the other hand, the n-side full surface electrode 9 is formed on the bottom surface of the n-type GaAs substrate 1. A transparent oxide film (SiO ₂ ) 20 ′ is deposited so as to spread in the lateral direction of the mesa stripe 5. This oxide film clad 20 ′ corresponds to the planar waveguide sheet 20 described in the first embodiment. In the transparent oxide film cladding 20 ′, diffusing particles 40 are mixed as a material for diffusing and scattering the radiation mode light 200. The diffusion particles 40 can also form a diffusion scattering mechanism by repeatedly forming a recess in the oxide film clad 20 'by patterning and etching and depositing a thin film of zirconium oxide or the like having a different refractive index thereon. It is.

  Next, the operation of the planar light emitting device in this embodiment will be described. The current flows through the active layer 3 included in the mesa stripe 5, and the light wave emitted from the active layer 3 is guided along the mesa stripe 5 as a waveguide, and is emitted from the side diffraction grating 11 into the radiation mode. Light 200 is emitted to the oxide film cladding 20 ′. The emitted radiation mode light 200 is diffused and scattered by the diffusing particles 40 and is planarly extracted from the entire oxide film cladding 20 ′. As a result, the entire chip surface emits light.

  According to the present embodiment, since the waveguide has a light emitting function of emitting light along the longitudinal direction of the waveguide, planar light emission can be obtained from the oxide film clad 20 ′ using light emitted from the waveguide itself.

  Further, by providing a quarter-wave phase shift 11 ′ near the center of the secondary diffraction grating 11 formed on the side surface of the mesa stripe 5, the extraction efficiency of the radiation mode light 200 can be increased. That is, it is possible to form a phase condition in which constructive interference occurs with the radiation mode light 200 generated from the waveguide traveling back and forth within the mesa stripe 5. If there is no phase shift 11 ′, the phase condition of destructive interference occurs, the distribution of the radiation mode light 200 falls at the center of the mesa stripe 5, and the extraction efficiency is greatly reduced.

  Further, since the radiation mode light 200 is emitted perpendicularly from the waveguide direction of the mesa stripe 5, it is not affected by total reflection due to a wide angle greater than the critical angle. That is, the refractive index of the active layer 3 included in the mesa stripe 5 is generally 3.2 or more, which is largely different from the refractive index of 1.5 near the oxide film cladding 20 '. When light is incident on the oxide film side from the crystal side having a large refractive index at the interface between the flat crystal having no structure such as a diffraction grating and the oxide film (oxide film clad 20 ′), the light exceeds the critical angle with respect to this interface. Wide-angle incident light is totally reflected and returns to the inside of the crystal. Furthermore, since surface emission from the active layer 3 is used, a wide-angle light emission component increases. Therefore, in the case of the conventional surface emitting LED, the light extraction efficiency is low. However, in the case of the present embodiment, by extracting the radiation mode light 200 vertically from the mesa stripe 5, there is no wide-angle emission component, and it is possible to obtain extremely high light extraction efficiency from the chip. Furthermore, by providing a plurality of the mesa stripes 5 in the same chip, the area of the diffraction grating 11 can be substantially increased, and the efficiency can be more reliably increased.

[Sixth Embodiment]
FIG. 10 is a perspective view showing the sixth embodiment. The basic structure of the planar light emitting device in the present embodiment is basically the same as the basic structure in the fifth embodiment, but instead of the diffusing particles 40 contained in the oxide film cladding 20 ′, fluorescence A yellow phosphor (YAG or TAG) 41, which is a material or a wavelength conversion material, is included in the oxide film cladding 20 ′. In this phosphor 41, light emitted from the active layer portion is guided along the mesa stripe 5, and is excited by the wavelength of the radiation mode light 200 extracted by the secondary diffraction grating 11 on the side surface to emit light. The wavelength of the radiation mode light 200 emitted from the second-order diffraction grating 11 formed on the side surface of the mesa stripe 5 is the same as that of blue (dominant wavelength is around 470 nm). Other configurations and basic operations are the same as those in the fifth embodiment, and thus description thereof is omitted here.

  According to the present embodiment, the light emitted from the active layer portion is guided along the mesa stripe 5 and is emitted by being excited by the wavelength of the radiation mode light 200 extracted by the secondary diffraction grating 11 on the side surface. By including the phosphor 41 in the oxide film cladding 20 ′, the radiation mode light 200 extracted from the mesa stripe 5 can be efficiently extracted in a planar shape from the entire planar waveguide sheet as the light emitting surface. Moreover, since the wavelength of the radiation mode light 200 is the same wavelength as blue, and the phosphor 41 is yellow, the yellow phosphor 41 is efficiently excited. That is, the phosphor 41 diffuses and scatters the blue radiation mode light 200 emitted from the secondary diffraction grating 11 formed on the side surface of the mesa stripe 5 and simultaneously emits yellow light. As a result, planar pseudo-white light emission in which blue and its complementary color yellow are mixed can be obtained from the mesa stripe 5. In addition, since the configuration is the same as that of the fifth embodiment, it is possible to obtain extremely high light extraction efficiency from the chip as in the effect of the fifth embodiment, and to obtain white light emission from the entire chip. it can.

[Seventh Embodiment]
FIG. 11 is a perspective view showing the seventh embodiment. The basic structure of the planar light emitting device in the present embodiment is basically the same as the basic structure in the fifth embodiment, but instead of the diffusing particles 40 contained in the oxide film cladding 20 ′, fluorescence Phosphors 41a to 41c, which are materials or wavelength conversion materials, are included in the oxide film clad 20 ′. The phosphors 41a to 41c emit light that is emitted by the light emitted from the active layer portion along the mesa stripe 5 and is excited by the wavelength of the radiation mode light 200 extracted by the secondary diffraction grating 11 on the side surface. To do.

  Here, the wavelength of the radiation mode light 200 emitted from the second-order diffraction grating 11 formed on the side surface of the mesa stripe 5 is the same as that of the blue or ultraviolet light. The phosphors 41a to 41c are red (R), green (G), and blue (B) phosphors, respectively. Other configurations and basic operations are the same as those in the fifth embodiment, and thus description thereof is omitted here.

  According to the present embodiment, the light emitted from the active layer portion is guided along the mesa stripe 5 and is emitted by being excited by the wavelength of the radiation mode light 200 extracted by the secondary diffraction grating 11 on the side surface. By including the phosphors 41a to 41c in the oxide film clad 20 ′, the radiation mode light 200 extracted from the mesa stripe 5 can be efficiently extracted in a planar shape from the entire planar waveguide sheet as the light emitting surface. Further, since the wavelength of the radiation mode light 200 is the same as that of blue or ultraviolet, the RGB phosphors 41a to 41c are excited efficiently. That is, light emission from the phosphors 41a to 41c can obtain planar white light emission as the three primary colors of visible light. In addition, since the configuration is the same as that of the fifth embodiment, it is possible to obtain extremely high light extraction efficiency from the chip as in the effect of the fifth embodiment, and to obtain white light emission from the entire chip. it can.

The perspective view which shows 1st Embodiment The perspective view which shows embodiment at the time of forming a diffraction grating in the upper surface of a rectangular waveguide core in 1st Embodiment The perspective view which shows the 1st modification of 1st Embodiment. The perspective view which shows the 2nd modification of 1st Embodiment. The perspective view which shows the 3rd modification of 1st Embodiment. The perspective view which shows 2nd Embodiment The perspective view which shows 3rd Embodiment The perspective view which shows 4th Embodiment The perspective view which shows 5th Embodiment The perspective view which shows 6th Embodiment The perspective view which shows 7th Embodiment The perspective view which shows the light emitting device at the time of utilizing the conventional waveguide

Explanation of symbols

A through C ... arrow 1 ... n-type GaAs substrate 2 ... n-type _{(Al x Ga 1-x)} 0.5 In 0.5 P cladding layer 3 ... undoped _{(Al y Ga 1-y)} 0.5 In 0. ₅ P active layer 4 ... p-type _{(Al x Ga 1-x)} 0.5 In 0.5 P cladding layer 5 ... mesa stripe 8 ... p-side electrode 9 ... n-side electrode 10 ... rectangular waveguide core, the planar waveguide Core 11, 11a to 11c ... Diffraction grating 11 '... Phase shift 14 ... Gold wire 17 ... Oxide film 20 ... Planar waveguide sheet 20' ... Oxide film cladding 21 ... Light guide plate structure 30, 30a-30c ... Light emitter (LED)
31, 31a-31c ... Condensing lens 32 ... Printed circuit board 40 ... Diffusion material and diffusion particles 41, 41a-41c ... Phosphor 100, 100a, 100b ... Waveguide mode light 200 ... Radiation mode light 500 ... Diffuser plate

Claims (7)

A rectangular waveguide core having a holographic optical structure for extracting guided mode light to the outside on all or part of the side surface along the longitudinal direction;
A planar waveguide sheet extending in the lateral direction of the rectangular waveguide core;
A planar light-emitting device comprising:   2. The planar light emitting device according to claim 1, further comprising a light emitter that optically couples emitted light to the rectangular waveguide core at one or both ends of the rectangular waveguide core.   A plurality of the rectangular waveguide cores are provided, and a light emitter is disposed at one or both ends of each rectangular waveguide core, and the wavelength of the waveguide mode light optically coupled from each light emitter is different from the other rectangular waveguides. The planar light-emitting device according to claim 1, wherein the planar light-emitting device is different from a waveguide core.   The said planar waveguide sheet contains at least 1 or more types of fluorescent material or wavelength conversion material which is excited by the wavelength of the said light-emitting body, and light-emits. Planar light emitting device.   A light emitter that emits light in which guided mode light having the same wavelength as that of blue or ultraviolet light is guided by optical coupling is disposed at one or both ends of the rectangular waveguide core, and the fluorescent material of red, green, or blue, or The planar light-emitting device according to claim 4, wherein the wavelength conversion material is contained in the planar waveguide sheet.   The planar light-emitting device according to claim 1, wherein the planar waveguide sheet includes a material having an optical diffusion effect. The planar light-emitting device according to claim 1, wherein the optical structure has a second-order or higher-order Bragg diffraction grating with respect to the waveguide mode light.

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