Patent Publication Number: US-2023152511-A1

Title: Planar light source

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims priority to Japanese Patent Application No. 2021-177477, filed on Oct. 29, 2021, the disclosure of which is hereby incorporated by reference in its entirety. 
     An embodiment according to the present disclosure relates to a planar light source. 
     A light-emitting module acquired by combining a light-emitting element such as a light-emitting diode with a light guide plate is widely used in a planar light source such as a backlight for a liquid crystal display, for example (See, for example, Japanese Patent Publication No. 2020-13714). 
     SUMMARY 
     An object of an exemplary embodiment according to the present disclosure is to provide a planar light source in which luminance unevenness is reduced. 
     According to an exemplary aspect of the present disclosure, a planar light source includes a light guide member, one or more light sources. The light guide member includes a plurality of light-emitting units separated by a groove. The one or more light sources are disposed in one or more of the plurality of light-emitting units. The plurality of light-emitting units include a plurality of outer portions and at least one inner portion located in a region surrounded by the plurality of outer portions in a plan view. In the plan view, at least one of the plurality of outer portions is adjacent to a smaller number of light-emitting units than a number of light-emitting units to which one of the at least one inner portion is adjacent. In a state in which a same power is supplied and one of the plurality of outer portion and one of the at least one inner portion are allowed to individually emit light, brightness of the one of the plurality of outer portion is higher than brightness of the one of the at least one inner portion. 
     A planar light source according to an exemplary embodiment of the present disclosure can achieve an planar light source in which luminance unevenness is reduced. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG.  1    is a schematic top view of an exemplary planar light source of exemplary embodiments. 
         FIG.  2    is a schematic top view of a portion A in  FIG.  1   . 
         FIG.  3    is a schematic cross-sectional view taken along line in  FIG.  2   . 
         FIG.  4 A  is a schematic bottom view of a light source of the exemplary embodiments. 
         FIG.  4 B  is a schematic cross-sectional view taken along line IVB-IVB in  FIG.  4 A . 
         FIG.  4 C  is a schematic cross-sectional view illustrating a modified example of a light source of the exemplary embodiments. 
         FIG.  4 D  is a schematic cross-sectional view illustrating a modified example of a light source of the exemplary embodiments. 
         FIG.  5    is a schematic top view of a portion B in  FIG.  1   . 
         FIG.  6    is a schematic cross-sectional view taken along line VI-VI in  FIG.  5   . 
         FIG.  7 A  is a schematic top view of an exemplary first light-reflective member  40  of the exemplary embodiments. 
         FIG.  7 B  is a schematic top view of another exemplary first light-reflective member  40  of the exemplary embodiments. 
         FIG.  7 C  is a schematic top view of another exemplary first light-reflective member  40  of the exemplary embodiments. 
         FIG.  8    is a schematic cross-sectional view of an outer portion of a third embodiment. 
         FIG.  9    is a schematic top view of an outer portion of a sixth embodiment. 
         FIG.  10    is a schematic cross-sectional view taken along line X-X in  FIG.  9   . 
         FIG.  11    is a schematic cross-sectional view of the outer portion of the sixth embodiment. 
         FIG.  12    is a schematic top view of a part of an exemplary planar light source of a seventh embodiment. 
         FIG.  13    is a schematic top view of a part of the exemplary planar light source of the seventh embodiment. 
         FIG.  14    is a schematic top view of a part of an exemplary planar light source of an eighth embodiment. 
         FIG.  15    is a schematic top view of a part of an exemplary planar light source of a ninth embodiment. 
         FIG.  16    is a schematic top view of a part of an exemplary planar light source of a tenth embodiment. 
         FIG.  17    is a schematic top view of a part of an exemplary planar light source of an eleventh embodiment. 
         FIG.  18    is a schematic cross-sectional view of a part of an exemplary planar light source of a twelfth embodiment. 
         FIG.  19    is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
         FIG.  20    is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
         FIG.  21    is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
         FIG.  22 A  is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
         FIG.  22 B  is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
         FIG.  23 A  is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
         FIG.  23 B  is a schematic top view illustrating an arrangement example of second hole portions in the twelfth embodiment. 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     Embodiments will be described below with reference to the drawings. Note that the drawings are diagrams that schematically illustrate embodiments, and thus scales, intervals, positional relationships, or the like of members are exaggerated, or illustration of some of the members may not be omitted. As a cross-sectional view, an end surface illustrating only a cut surface may be illustrated. 
     In the following description, components having substantially the same function may be denoted by the same reference signs and a description thereof may be omitted. Further, terms indicating a specific direction or position (“upper”, “lower”, and other terms including related to those terms) may be used. However, these terms are used merely to make it easy to understand relative directions or positions in the referenced drawing. As long as the relative direction or position is the same as that described in the referenced drawing using the term such as “upper” or “lower”, in drawings other than the drawings of the present disclosure, actual products, and the like, components need not necessarily be arranged in the same manner as in the referenced drawing. In the present specification, “parallel” includes not only a case in which two straight lines, sides, surfaces, or the like do not intersect even if extended, but also a case in which angles formed by two straight lines, sides, surfaces, or the like intersect in a range of 10° or less. In the present specification, a positional relationship that expresses “on” includes a case in which an object is in contact and also a case in which an object is not in contact but located above. 
       FIG.  1    is a schematic top view of a planar light source of an embodiment. 
     A planar light source of an embodiment includes a light guide member  10 . The light guide member  10  includes a first surface  11  and a second surface  12  on a side opposite to the first surface  11  as shown in  FIG.  3    and the like to be described below. In the present specification, two directions that are parallel to the first surface  11  of the light guide member  10  and are orthogonal to each other are referred to as a first direction X and a second direction Y. Further, a direction extending from the second surface  12  to the first surface  11  and orthogonal to the first direction X and the second direction Y is referred to as a third direction Z. The shape of the light guide member  10  in a plan view is, for example, a quadrangle having two sides extending in the first direction X and two sides extending in the second direction Y. 
     The light guide member  10  includes a plurality of light-emitting units  1  separated from each other in the first direction X and the second direction Y by grooves  14 . Each of the light-emitting units  1  can serve as, for example, a driving unit for local dimming. The plurality of light-emitting units  1  include a plurality of outer portions  1   b , a plurality of outer portions  1   c , and at least one inner portion  1   a . In the example illustrated in  FIG.  1   , a plurality of inner portions  1   a  are disposed in a region surrounded by the plurality of outer portions  1   b  and the plurality of outer portions  1   c  in the plan view. For example, the number of inner portions  1   a  is greater than the number of outer portions  1   b  and the number of outer portions  1   c.    
     In the plan view, each of the plurality of outer portions  1   b  and each of the plurality of outer portions  1   c  are adjacent to a smaller number of light-emitting units  1  than the number of light-emitting units  1  to which one inner portion  1   a  is adjacent. The plurality of outer portions  1   b  and the plurality of outer portions  1   c  are light-emitting units  1  located on the outermost periphery of the region where the plurality of light-emitting units  1  are disposed in the plan view. The plurality of outer portions  1   b  and the plurality of outer portions  1   c  are arranged along the sides of the light guide member  10  in the plan view. The outer portions  1   c  are located at corners of the light guide member  10  in the plan view. The light-emitting unit  1  includes four outer portions  1   c.    
     In the plan view, one outer portion  1   c  located at the corner is adjacent to one outer portion  1   b  in the first direction X, is adjacent to one outer portion  1   b  in the second direction Y, and is adjacent to one inner portion  1   a  in a diagonal direction of the light guide member  10 . That is, in the plan view, one outer portion  1   c  located at the corner is adjacent to three light-emitting units  1 . 
     In the plan view, one outer portion  1   b  of the plurality of outer portions  1   b  arranged in the second direction Y is adjacent to one inner portion  1   a  in the first direction X, is adjacent to two outer portions  1   b  (or one outer portion  1   b  and one outer portion  1   c ) in the second direction Y, and is adjacent to two inner portions  1   a  (or one inner portion  1   a  and one outer portion  1   b ) in an oblique direction inclined with respect to the first direction X and the second direction Y. In the plan view, one outer portion  1   b  of the plurality of outer portions  1   b  arranged in the first direction X is adjacent to one inner portion  1   a  in the second direction Y, is adjacent to two outer portions  1   b  (or one outer portion  1   b  and one outer portion  1   c ) in the first direction X, and is adjacent to two inner portions  1   a  (or one inner portion  1   a  and one outer portion  1   b ) in the oblique direction inclined with respect to the first direction X and the second direction Y. That is, in the plan view, one outer portion  1   b  is adjacent to five light-emitting units  1 . 
     In the plan view, one inner portion  1   a  is adjacent to two inner portions  1   a  (or one inner portion  1   a  and one outer portion  1   b ) in the first direction X, is adjacent to two inner portions  1   a  (or one inner portion  1   a  and one outer portion  1   b ) in the second direction Y, and is adjacent to four inner portions  1   a  (or two inner portions  1   a  and two outer portions  1   b , or one inner portion  1   a , two outer portions  1   b , and one outer portion  1   c ) in the oblique direction inclined with respect to the first direction X and the second direction Y. That is, in the plan view, one inner portion  1   a  is adjacent to eight light-emitting units  1 . 
       FIG.  2    is a schematic top view of a portion A in which the inner portion  1   a  is disposed in  FIG.  1   . 
       FIG.  3    is a schematic cross-sectional view taken along line in  FIG.  2   . 
     The planar light source of the embodiment includes a plurality of light sources  20 A in addition to the light guide member  10 . Moreover, the planar light source of the embodiment can include a support member  50 , a first light-transmissive member  30 , and a first light-reflective member  40 . 
     Hereinafter, elements constituting the planar light source of the embodiment will be described in detail. 
     Light Guide Member 
     The light guide member  10  is light-transmissive to light emitted from the light source  20 A. A transmittance of the light guide member  10  with respect to a peak wavelength of the light source  20 A is preferably equal to or greater than 50% and more preferably equal to or greater than 70%, for example. 
     As a material of the light guide member  10 , a thermoplastic resin such as acrylic, polycarbonate, cyclic polyolefin, polyethylene terephthalate, or polyester, a thermosetting resin such as epoxy or silicone, or glass can be used, for example. 
     A thickness of the light guide member  10  is preferably in a range from 150 μm to 800 μm, for example. In the present specification, a thickness of each member represents a maximum value of a distance between an upper surface and a lower surface of each member in the third direction Z. The light guide member  10  may be formed of a single layer or may be formed of a layered body of a plurality of layers in the third direction Z. When the light guide member  10  is formed of a layered body, a light-transmissive adhesive layer may be disposed between layers. The layers of the layered body may use different kinds of chief materials. As a material of the adhesive layer, a thermoplastic resin such as acrylic, polycarbonate, cyclic polyolefin, polyethylene terephthalate, or polyester, or a thermosetting resin such as epoxy or silicone can be used, for example. 
     The light guide member  10  includes a first hole portion h 1  penetrating from the first surface  11  to the second surface  12 . As illustrated in  FIG.  2   , in the plan view, the first hole portion h 1  can be, for example, circular. Further, in the plan view, the shape of the first hole portion h 1  can be, for example, an ellipse, or a polygon such as a triangle, a quadrangle, a hexagon, or an octagon. In the present specification, the plan view means viewing from the third direction Z. 
     As described above, the light guide member  10  is formed with the grooves  14  that separate the light-emitting units  1  from each other. By forming the groove  14 , for example, the warpage of the planar light source due to heat generation of the light source  20 A can be suppressed. As illustrated in  FIG.  3   , the groove  14  includes a first groove portion  14   a  that is open to the first surface  11  side, and a second groove portion  14   b  that is open to the second surface  12  side. The first groove portion  14   a  and the second groove portion  14   b  communicate with each other in the third direction Z. A width of the first groove portion  14   a  is greater than a width of the second groove portion  14   b . The width of the first groove portion  14   a  and the width of the second groove portion  14   b  are a width in a direction orthogonal to a direction in which the groove  14  extends. 
     A partition member  15  can be disposed in the first groove portion  14   a . The partition member  15  has light reflectivity to the light emitted from the light source  20 A. The partition member  15  is, for example, a resin member including light scattering particles. As the light scattering particles of the partition member  15 , particles of titania, silica, alumina, zinc oxide, magnesium oxide, zirconia, yttria, calcium fluoride, magnesium fluoride, niobium pentoxide, barium titanate, tantalum pentoxide, barium sulfate, glass, or the like can be used, for example. As a resin material of the partition member  15 , a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. The partition member  15  may be a metal member such as aluminum and silver. For example, the partition member  15  is disposed in a film shape along an inside surface of the first groove portion  14   a . The partition member  15  may fill the first groove portion  14   a.    
     The partition member  15  suppresses light guide between adjacent light-emitting units  1 . For example, light guide from the light-emitting unit  1  in a light-emitting state to the light-emitting unit  1  in a non-light-emitting state is suppressed by the partition member  15 . Thus, when performing local dimming with each of the light-emitting units  1  as a driving unit, it is possible to easily control luminance for each of the light-emitting units  1 . 
     In  FIG.  3   , the groove  14  penetrates from the first surface  11  to the second surface  12  of the light guide member  10 . The groove  14  may be a bottomed groove having an opening portion on the first surface  11  side, and having a bottom that does not reach the second surface  12 . The groove  14  may be a bottomed groove having an opening portion on the second surface  12  side, and having a bottom that does not reach the first surface  11 . The groove  14  may be a hollow groove disposed inside the light guide member  10 . 
     Light Source 
     The light source  20 A is disposed in the first hole portion h 1  of the light guide member  10 . The first hole portion h 1  is disposed in each of the plurality of light-emitting units  1 . Consequently, the light source  20 A is disposed in each of the plurality of light-emitting units  1 . 
     The light source  20 A includes a light-emitting element  21 . The light-emitting element  21  includes a semiconductor layered body. The semiconductor layered body includes, for example, a substrate such as sapphire or gallium nitride, an n-type semiconductor layer and a p-type semiconductor layer disposed on the substrate, and a light-emitting layer interposed between the n-type semiconductor layer and the p-type semiconductor layer. Further, the light-emitting element  21  includes an n-side electrode electrically connected to the n-type semiconductor layer, and a p-side electrode electrically connected to the p-type semiconductor layer. Moreover, the light source  20 A includes a pair of positive and negative electrodes  25  disposed on a lower surface side. One of the pair of electrodes  25  is electrically connected to the p-side electrode, and the other is electrically connected to the n-side electrode. 
     The semiconductor layered body from which the substrate is eliminated may be used. Further, a structure of the light-emitting layer may be a structure including a single active layer such as a double heterostructure and a single quantum well (SQW) structure, or a structure including an active layer group such as a multiple quantum well (MQW) structure. The light-emitting layer can emit visible light or ultraviolet light. The light-emitting layer can emit light that is visible from blue to red. As the semiconductor layered body including such a light-emitting layer, for example, In x Al y Ga 1-x-y N (0≤x, 0≤y, x+y≤1) can be included. The semiconductor layered body can include at least one light-emitting layer that can achieve the light emission described above. For example, the semiconductor layered body may have a structure including one or more light-emitting layers between the n-type semiconductor layer and the p-type semiconductor layer, or may have a structure in which a structure including the n-type semiconductor layer, the light-emitting layer, and the p-type semiconductor layer in order is repeated multiple times. When the semiconductor layered body includes the plurality of light-emitting layers, the semiconductor layered body may include the light-emitting layers having different light emission peak wavelengths, or may include the light-emitting layers having the same light emission peak wavelength. Note that the same light emission peak wavelength may have a variation of approximately several nm, for example. A combination of such light-emitting layers can be selected as appropriate, and, for example, when the semiconductor layered body includes two light-emitting layers, the light-emitting layers can be selected from combinations of blue light and blue light, green light and green light, red light and red light, ultraviolet light and ultraviolet light, blue light and green light, blue light and red light, green light and red light, and the like. The light-emitting layer may include a plurality of active layers having different light emission peak wavelengths, or may include a plurality of active layers having the same light emission peak wavelength. 
     As illustrated in  FIGS.  3  to  4 B , the light source  20 A can further include a second light-transmissive member  22 . The second light-transmissive member  22  covers an upper surface and a lateral surface of the light-emitting element  21 . The second light-transmissive member  22  protects the light-emitting element  21 , and also has functions such as wavelength conversion and light diffusion according to particles added to the second light-transmissive member  22 . 
     For example, the second light-transmissive member  22  includes a light-transmissive resin, and may further include a phosphor. For example, a silicone resin, an epoxy resin, or the like can be used as the light-transmissive resin. The phosphor can use an oxynitride based phosphor such as an yttrium aluminum garnet based phosphor (for example, Y 3 (Al,Ga) 5 O 12 :Ce), a lutetium aluminum garnet based phosphor (for example, Lu 3 (Al,Ga) 5 O 12 :Ce), a terbium aluminum garnet based phosphor (for example, Tb 3 (Al,Ga) 5 O 12 :Ce), a CCA based phosphor (for example, Ca 10 (PO 4 ) 6 Cl 2 :Eu), an SAE based phosphor (for example, Sr 4 A 14 O 25 :Eu), a chlorosilicate based phosphor (for example, Ca 8 MgSi 4 O 16 Cl 2 :Eu), a β-sialon based phosphor (for example, (Si,Al) 3 (O,N) 4 :Eu), or an α-sialon based phosphor (for example, Ca(Si,Al) 12 (O,N) 16 :Eu), a nitride based phosphor such as an SLA based phosphor (for example, SrLiAl 3 N 4 :Eu), a CASN based phosphor (for example, CaAlSiN 3 :Eu), or an SCASN based phosphor (for example, (Sr,Ca)AlSiN 3 :Eu), a fluoride based phosphor such as a KSF based phosphor (for example, K 2 SiF 6 :Mn), a KSAF based phosphor (for example, K 2 Si 0.99 Al 0.01 F 5.99 :Mn), or an MGF based phosphor (for example, 3.5MgO.0.5MgF 2 . GeO 2 :Mn), a phosphor having a perovskite structure (for example, CsPb(F,Cl,Br,I) 3 ), a quantum dot phosphor (for example, CdSe, InP, AgInS 2 , or AgInSe 2 ), or the like. As the phosphor added to the second light-transmissive member  22 , one kind of a phosphor may be used, or a plurality of kinds of phosphors may be used. 
     The KSAF based phosphor may have a composition represented by Formula (I) below. 
       M 2 [Si p Al q Mn r F s ]  (I)
 
     In Formula (I), M represents an alkali metal and may include at least K. Mn may be a tetravalent Mn ion. p, q, r, and s may satisfy 0.9≤p+q+r≤1.1, 0&lt;q≤0.1, 0&lt;r≤0.2, 5.9≤s≤6.1. Preferably 0.95≤p+q+r≤1.05 or 0.97≤p+q+r≤1.03, 0&lt;q≤0.03, 0.002≤q≤0.02 or 0.003≤q≤0.015, 0.005≤r≤0.15, 0.01≤r≤0.12 or 0.015≤r≤0.1, 5.92≤s≤6.05 or 5.95≤s≤6.025. Examples thereof include compositions represented by K 2  [Si 0.946 Al 0.005 Mn 0.049 F 5.995 ], K 2  [Si 0.942 Al 0.008 Mn 0.050 F 5.992 ], K 2  [Si 0.939 Al 0.014 Mn 0.047 F 5.986 ]. According to such a KSAF based phosphor, it is possible to obtain red light emission having a high luminance and a narrow half-value width of the light emission peak wavelength. 
     Further, a wavelength conversion sheet containing the phosphor described above may be disposed on the planar light source. The wavelength conversion sheet can be used as a planar light source that absorbs a part of the blue light from the light source  20 A, emits yellow light, green light, and/or red light, and emits white light. For example, white light can be acquired by combining the light source  20 A that can emit blue light and the wavelength conversion sheet containing the phosphor that can emit yellow light. In addition, the light source  20 A that can emit blue light and the wavelength conversion sheet containing a red phosphor and a green phosphor may be combined. Further, the light source  20 A that can emit blue light and a plurality of wavelength conversion sheets may be combined. As the plurality of wavelength conversion sheets, for example, the wavelength conversion sheet containing the phosphor that can emit red light and the wavelength conversion sheet containing the phosphor that can emit green light can be selected. Further, the light source  20 A including the light-emitting element  21  that can emit blue light and the second light-transmissive member  22  containing the phosphor that can emit red light may be combined with the wavelength conversion sheet containing the phosphor that can emit green light. 
     As a yellow phosphor used in the wavelength conversion sheet, the yttrium aluminum garnet based phosphor is preferably used, for example. Further, as a green phosphor used in the wavelength conversion sheet, for example, the phosphor having the perovskite structure or the quantum dot phosphor described above with a narrow half-value width of a light emission peak wavelength is preferably used. Further, as a red phosphor used in the wavelength conversion sheet, for example, the KSF based phosphor, the KSAF based phosphor, or the quantum dot phosphor described above with a narrow half-value width of a light emission peak wavelength is preferably used similarly to the green phosphor. Particularly, because the quantum dot phosphor has a short afterglow time, it can be suitably used as a planar light source that performs local dimming. 
     The light source  20 A can further include a covering member  24 . The covering member  24  is disposed on a lower surface of the light-emitting element  21 . The covering member  24  is disposed such that a lower surface of the electrodes  25  of the light source  20 A is exposed from the covering member  24 . The covering member  24  is also disposed on a lower surface of the second light-transmissive member  22  covering the lateral surface of the light-emitting element  21 . 
     The covering member  24  has light reflectivity to the light emitted from the light source  20 A. The covering member  24  is, for example, a resin member containing light scattering particles. As the light scattering particles of the covering member  24 , particles of titania, silica, alumina, zinc oxide, magnesium oxide, zirconia, yttria, calcium fluoride, magnesium fluoride, niobium pentoxide, barium titanate, tantalum pentoxide, barium sulfate, glass, or the like can be used, for example. As a resin material of the covering member  24 , a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. 
     The light source  20 A can further include a second light-reflective member  23 . The second light-reflective member  23  is disposed on an upper surface of the light source  20 A. The second light-reflective member  23  covers the upper surface of the light-emitting element  21 . The second light-reflective member  23  is disposed on an upper surface of the second light-transmissive member  22 , and controls the amount and emission direction of light emitted from the upper surface of the second light-transmissive member  22 . The second light-reflective member  23  has light reflectivity and is light-transmissive to light emitted from the light-emitting element  21 . A part of the light emitted from the upper surface of the second light-transmissive member  22  is reflected by the second light-reflective member  23 , and another part thereof is transmitted through the second light-reflective member  23 . A transmittance of the second light-reflective member  23  with respect to the light emitted from the light-emitting element  21  is preferably in a range from 1% to 50% and more preferably in a range from 3% to 30%, for example. Thus, luminance directly above the light source  20 A is reduced, and luminance unevenness of the planar light source is reduced. 
     The second light-reflective member  23  can be formed of a light-transmissive resin and light scattering particles contained in the light-transmissive resin. As the light-transmissive resin, a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. As the light scattering particles, particles of titania, silica, alumina, zinc oxide, magnesium oxide, zirconia, yttria, calcium fluoride, magnesium fluoride, niobium pentoxide, barium titanate, tantalum pentoxide, barium sulfate, glass, or the like can be used, for example. The second light-reflective member  23  may be, for example, a metal member such as Al or Ag, or a dielectric multilayer film. 
     The light source may not include the covering member  24 . For example, a light source  20 B illustrated in  FIG.  4 C  includes a lower surface formed of the lower surface of the light-emitting element  21  and the lower surface of the second light-transmissive member  22 . 
     Further, a light source  20 C may be the light-emitting element  21  alone. As illustrated in  FIG.  4 D , the second light-reflective member  23  may be disposed on the upper surface of the light-emitting element  21 . Further, in  FIG.  4 D , in the light source  20 C, the covering member  24  is not disposed on the lower surface of the light-emitting element  21 ; however, the covering member  24  may be disposed on the lower surface of the light-emitting element  21 . 
     First Light-Transmissive Member 
     The first light-transmissive member  30  is disposed between a lateral surface of the light source  20 A and the light guide member  10 , and is disposed on the light source  20 A, while being in the first hole portion h 1  of the light guide member  10 . The first light-transmissive member  30  covers the upper surface and the lateral surface of the light source  20 A. The first light-transmissive member  30  is preferably in contact with the light guide member  10  and the light source  20 A. In this way, the light from the light source  20 A is easily guided to the light guide member  10 . 
     The first light-transmissive member  30  is light-transmissive to the light emitted from the light source  20 A. A transmittance of the first light-transmissive member  30  with respect to the peak wavelength of the light source  20 A is preferably 50% or more and more preferably 70% or more, for example. For example, a resin can be used as a material of the first light-transmissive member  30 . For example, as the material of the first light-transmissive member  30 , the same resin as the material of the light guide member  10  or a resin having a small difference in refractive index from the material of the light guide member  10  can be used. 
     The first light-transmissive member  30  may be formed of a single layer or may be formed of a layered body of a plurality of layers in the third direction Z. The first light-transmissive member  30  may include a phosphor or a light diffusing material. When the first light-transmissive member  30  is a layered body, each layer may or may not include a phosphor and/or light diffusing material. For example, the first light-transmissive member  30  may be formed of a layer containing a phosphor and a layer that does not contain a phosphor. 
     First Light-Reflective Member 
     The first light-reflective member  40  is disposed on the first light-transmissive member  30 . As illustrated in  FIG.  2   , the first light-reflective member  40  is disposed above the light source  20 A via the first light-transmissive member  30 . The first light-reflective member  40  may be in contact with the first light-transmissive member  30  and the light source  20 A. The first light-reflective member  40  may be disposed above the first light-transmissive member  30  and the light source  20 A via an adhesive resin. As the adhesive resin, a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. As illustrated in  FIG.  2   , the first light-reflective member  40  is disposed in a position overlapping the first hole portion h 1  in which the light source  20 A and the first light-transmissive member  30  are disposed in the plan view. 
     The first light-reflective member  40  has light reflectivity and is light-transmissive to the light emitted from the light source  20 A. A transmittance of the first light-reflective member  40  with respect to the peak wavelength of the light source  20 A is preferably in a range from 1% to 50% and more preferably in a range from 3% to 30%, for example. 
     The first light-reflective member  40  can be formed of a light-transmissive resin and light scattering particles contained in the light-transmissive resin. As the light-transmissive resin, a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. As the light scattering particles, particles of titania, silica, alumina, zinc oxide, magnesium oxide, zirconia, yttria, calcium fluoride, magnesium fluoride, niobium pentoxide, barium titanate, tantalum pentoxide, barium sulfate, glass, or the like can be used, for example. Further, in the first light-reflective member  40 , the light-transmissive resin as described above may contain a plurality of air bubbles without containing light scattering particles. Further, the first light-reflective member  40  may be, for example, a metal member such as aluminum or silver, or a dielectric multilayer film. 
     An upper surface of the first light-reflective member  40  serves as a light-emitting surface (light exit surface) of the planar light source together with the first surface  11  of the light guide member  10 . The first light-reflective member  40  reflects a part of the light traveling upward from the first hole portion h 1  in which the light source  20 A is disposed, and transmits the other part of the light. Thus, in the light-emitting surface of the planar light source, a difference between luminance of a region directly above and around the light source  20 A and luminance of another region can be reduced. Thus, luminance unevenness on the light-emitting surface of the planar light source can be reduced. 
     The first light-transmissive member  30  is disposed between the first light-reflective member  40  and the second light-reflective member  23  of the light source  20 A. The first light-transmissive member  30  has a higher transmittance with respect to the light emitted from the light source  20 A than the transmittance of the first light-reflective member  40  and the second light-reflective member  23 . The transmittance of the first light-transmissive member  30  with respect to the light emitted from the light source  20 A can be set in a range from 2 times to 100 times the transmittance of the second light-reflective member  23  and the transmittance of the first light-reflective member  40  in a range of 100% or less. The light emitted from the lateral surface of the light source  20 A, light reflected by a third light-reflective member  53  to be described below, and the like go around and are guided into the first light-transmissive member  30  between the first light-reflective member  40  and the second light-reflective member  23 . Thus, a region directly above the light source  20 A is not too bright and not too dark, and as a result, luminance unevenness on the light-emitting surface of the planar light source can be reduced. 
     Because the second light-reflective member  23  suppresses transmission of a part of the light emitted in a directly upward direction from the light source  20 A, the transmittance of the first light-reflective member  40  is preferably higher than the transmittance of the second light-reflective member  23  with respect to the light emitted from the light source  20 A in order to suppress the region directly above the light source  20 A from becoming too dark. 
     Support Member 
     The support member  50  supports the light guide member  10  and the light source  20 A. The light guide member  10  is disposed on the support member  50  with the second surface  12  facing an upper surface of the support member  50 . The light source  20 A is disposed on the support member  50  in the first hole portion h 1 . 
     The support member  50  includes a wiring substrate  60 . The wiring substrate  60  includes an insulating base material  61 , and a wiring layer  62  of at least one layer disposed on at least one surface of the insulating base material  61 . The insulating base material  61  may be a rigid substrate, or may be a flexible substrate. The insulating base material  61  is preferably a flexible substrate in order to reduce a thickness of the planar light source. The insulating base material  61  may be formed of a single layer or may be formed of a layered body of a plurality of layers in the third direction Z. For example, the insulating base material  61  may be formed of a single-layer flexible substrate, or may be formed of a layered body of a plurality of rigid substrates. For example, a resin such as a polyimide can be used as a material of the insulating base material  61 . The wiring layer  62  is a metal film, for example, a copper film. 
     The support member  50  further includes a first adhesive layer  51  disposed on the wiring substrate  60 , the third light-reflective member  53  disposed on the first adhesive layer  51 , and a second adhesive layer  52  disposed on the third light-reflective member  53 . 
     The first adhesive layer  51  is disposed on a surface of the insulating base material  61  on a side opposite to the surface on which the wiring layer  62  is disposed. The first adhesive layer  51  is disposed between the insulating base material  61  and the third light-reflective member  53 , and adheres the insulating base material  61  and the third light-reflective member  53 . The first adhesive layer  51  is, for example, a resin layer containing light scattering particles. As the light scattering particles, particles of titania, silica, alumina, zinc oxide, magnesium oxide, zirconia, yttria, calcium fluoride, magnesium fluoride, niobium pentoxide, barium titanate, tantalum pentoxide, barium sulfate, glass, or the like can be used, for example. As the resin of the first adhesive layer  51 , a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. 
     The third light-reflective member  53  is disposed below the second surface  12  of the light guide member  10 , below the light source  20 A, below the first light-transmissive member  30 , and below the groove  14 . The third light-reflective member  53  has light reflectivity to the light emitted from the light source  20 A. As the third light-reflective member  53 , a resin member including a large number of air bubbles or a resin member including light scattering particles can be used, for example. The resin of the third light-reflective member  53  can be selected from, for example, the resins listed as the resins that can be used for the first adhesive layer  51  described above. The light scattering particles can be selected from, for example, the light scattering particles listed as the light scattering particles that can be used for the first adhesive layer  51  described above. 
     In a region between the third light-reflective member  53  and the first surface  11  of the light guide member  10 , the light from the light source  20 A is repeatedly reflected by the third light-reflective member  53  and the first surface  11  and is guided in the light guide member  10  toward the groove  14 . A part of the light toward the first surface  11  is extracted from the first surface  11  to the outside of the light guide member  10 . A part of the light toward the second surface  12  is reflected to the first surface  11  side by the third light-reflective member  53 , and thus luminance of the light extracted from the first surface  11  can be improved. The third light-reflective member  53  preferably uses a resin member containing a large number of air bubbles. The amount of light reflected by the third light-reflective member  53  is improved, and the light from the light source  20 A is easily guided into the light guide member  10  toward the groove  14 . Moreover, when light reflectivity is provided to the first adhesive layer  51  disposed on the lower surface of the third light-reflective member  53 , luminance of the light extracted from the first surface  11  can be further improved. 
     The second adhesive layer  52  is disposed between the third light-reflective member  53  and the second surface  12  of the light guide member  10 , and adheres the third light-reflective member  53  and the light guide member  10 . The light source  20 A is disposed on the second adhesive layer  52  in the first hole portion h 1  of the light guide member  10 . The second adhesive layer  52  is light-transmissive to the light emitted from the light source  20 A. The material of the second adhesive layer  52  can be selected from, for example, the resins listed in the resins that can be used for the first adhesive layer  51  described above. Further, the second adhesive layer  52  may include light scattering particles, and the light scattering particles can be selected from, for example, the light scattering particles listed as the light scattering particles that can be used for the first adhesive layer  51  described above. 
     The support member  50  further includes a conductive member  70 . The conductive member  70  includes, for example, a resin and metal particles included in the resin. As the resin of the conductive member  70 , an epoxy resin or a phenol resin can be used, for example. For example, particles of copper or silver can be used as the metal particles. 
     The conductive member  70  includes a connection portion  71  and a wiring portion  72 . The connection portion  71  penetrates the second adhesive layer  52 , the third light-reflective member  53 , the first adhesive layer  51 , and the insulating base material  61  in the third direction Z. The wiring portion  72  is disposed on a surface of the wiring substrate  60  where the wiring layer  62  is disposed, and is connected to the connection portion  71 . The connection portion  71  and the wiring portion  72  can be integrally formed of the same material, for example. A portion  72   a  of the wiring portion  72  is connected to the wiring layer  62 . 
     A pair of the conductive members  70  are separated from each other corresponding to the pair of positive and negative electrodes  25  of the light source  20 A. The connection portion  71  of one of the conductive members  70  is connected to the positive electrode  25  below the light source  20 A, and the connection portion  71  of the other conductive member  70  is connected to the negative electrode  25  below the light source  20 A. The electrode  25  of the light source  20 A is electrically connected to the conductive member  70  and the wiring layer  62 . 
     The support member  50  further includes an insulating layer  54 . The insulating layer  54  covers and protects the surface of the wiring substrate  60  where the wiring layer  62  is disposed, the wiring layer  62 , and the conductive member  70 . 
       FIG.  5    is a schematic top view of a portion B in  FIG.  1   . The portion B is a portion including one outer portion  1   c  disposed at the corner of the light guide member  10 , one outer portion  1   b  adjacent to the outer portion  1   c  in the first direction X, one outer portion  1   b  adjacent to the outer portion  1   c  in the second direction Y, and one inner portion  1   a  adjacent to the outer portion  1   c  in the oblique direction inclined with respect to the first direction X and the second direction Y among the light-emitting units  1 .  FIG.  6    is a schematic cross-sectional view taken along line VI-VI in  FIG.  5   , and is a schematic cross-sectional view of the planar light source in the outer portion  1   c . Note that the outer portion  1   b  can have the same configuration as the outer portion  1   c.    
     The outer portion  1   b  and the outer portion  1   c  can include the same member as the inner portion  1   a  described above with reference to  FIG.  3   . Note that lateral surfaces (lateral surface on the right side in  FIG.  6   ) of the outer portion  1   b  and the outer portion  1   c  on the sides where other light-emitting units  1  are not adjacent to each other each have a configuration in which the groove  14  is cut at a half position in the width direction of the groove  14 . 
     Moreover, as a difference between the outer portion  1   b  and the inner portion  1   a  and a difference between the outer portion  1   c  and the inner portion  1   a , there is a difference in brightness in an individual light-emitting state. The brightness of one outer portion  1   b  is higher than the brightness of one inner portion  1   a . The brightness of one outer portion  1   c  is higher than the brightness of one inner portion  1   a . The brightness represents the brightness in a state in which the same power is supplied to the light sources  20 A disposed on the outer portion  1   b , the outer portion  1   c , and the inner portion  1   a , respectively, and one outer portion  1   b , one outer portion  1   c , and one inner portion  1   a  are individually allowed to emit light. 
     For example, the brightness of the light-emitting unit  1  can be measured by a spectral luminance meter. When the spectral luminance meter is installed above one light-emitting unit  1 , power is supplied to the light source  20 A to measure the luminance. 
     In the plan view, the number of light-emitting units  1  adjacent to one outer portion  1   b  and the number of light-emitting units  1  adjacent to one outer portion  1   c  are less than the number of light-emitting units  1  adjacent to one inner portion  1   a . Accordingly, the amount of light entering the one outer portion  1   b  from the adjacent light-emitting units  1  and the amount of light entering the one outer portion  1   c  from the adjacent light-emitting units  1  are less than the amount of light entering the one inner portion  1   a  from the adjacent light-emitting units  1 . Therefore, in an entire light-emitting state in which all the light-emitting units  1  are allowed to emit light, the outer peripheral side of the light guide member  10  in which the outer portion  1   b  and the outer portion  1   c  are disposed tends to be darker than the region where the inner portion  1   a  is disposed. 
     As will be described in detail below, according to the embodiment, in a state in which one outer portion  1   b , one outer portion  1   c , and one inner portion  1   a  are individually allowed to emit light with the same power, the brightness of one outer portion  1   b  and the brightness of one outer portion  1   c  are made higher than the brightness of one inner portion  1   a  by varying, for example, the covering ratio of the first light-reflective member  40  covering the light-emitting unit  1 , the thickness of the first light-reflective member  40 , the concentration of the light scattering particles in the first light-reflective member  40 , and the like. Thus, it is possible to compensate for a decrease in the brightness on the outer peripheral side in the entire light-emitting state, and it is possible to reduce luminance unevenness on the light-emitting surface of the planar light source. 
     For example, the brightness of one inner portion  1   a  can be the brightness of at least the inner portion  1   a  closest to the center of the light guide member  10  in the plan view illustrated in  FIG.  1   . The center of the light guide member  10  is located at an intersection of two diagonal lines of the light guide member  10  in the plan view. In the plan view, when the inner portion  1   a  overlaps the center of the light guide member  10 , this inner portion  1   a  is the inner portion  1   a  closest to the center of the light guide member  10 . In the plan view, when the center of the light guide member  10  does not overlap the inner portion  1   a , the inner portion  1   a  having an outer edge (lateral surface adjacent to the groove  14 ) closest to the center of the light guide member  10  is the inner portion  1   a  closest to the center of the light guide member  10 . In this case, there may be a plurality of inner portions  1   a  closest to the center of the light guide member  10 , but any of the plurality of inner portions  1   a  may be the inner portions  1   a  closest to the center of the light guide member  10 . 
     One outer portion  1   b  brighter than one inner portion  1   a  is one outer portion  1   b  selected from the plurality of outer portions  1   b . One outer portion  1   c  brighter than one inner portion  1   a  is one outer portion  1   c  selected from the plurality of outer portions  1   c . The number of outer portions  1   b  brighter than one inner portion  1   a  and the number of outer portions  1   c  brighter than one inner portion  1   a  may also be multiple. The brightness of all the outer portions  1   b  and the brightness of all the outer portions  1   c  may also be higher than the brightness of one inner portion  1   a . In this case, it is possible to further reduce luminance unevenness on the light-emitting surface of the planar light source in the entire light-emitting state. 
     In order to further reduce luminance unevenness on the light-emitting surface of the planar light source, for example, the brightness of one outer portion  1   b  and the brightness of one outer portion  1   c  are preferably set in a range from 1.3 times to 3 times the brightness of one inner portion. 
     Further, among the outer portions  1   b  and the outer portions  1   c , the number of light-emitting units  1 , to which one outer portion  1   c  located at the corner of the light guide member  10  is adjacent, is smaller than the number of light-emitting units  1  to which one outer portion  1   b  located at a position other than the corner is adjacent. Therefore, in the entire light-emitting state, among the outer peripheral portions of the light guide member  10 , the brightness of the corner tends to be dark. Therefore, in a state in which one outer portion  1   b  and one outer portion  1   c  are individually allowed to emit light with the same power, it is preferable that the brightness of one outer portion  1   c  located at the corner is higher than the brightness of one outer portion  1   b  located at a position other than the corner. 
     Note that among the plurality of inner portions  1   a , the brightness in the individual light-emitting state may be different in accordance with the distance from the outer portion  1   b . For example, the brightness of the inner portion  1   a  adjacent to the outer portion  1   b  in the individual light-emitting state can be made higher than the brightness of the inner portion  1   a  closest to the center of the light guide member  10  in the individual light-emitting state. Thus, in the entire light-emitting state, light from the inner portion  1   a  adjacent to the outer portion  1   b  can compensate for a decrease in the brightness of the outer portion  1   b  and reduce luminance unevenness on the light-emitting surface of the planar light source. 
     Further, among the plurality of inner portions  1   a , the brightness in the individual light-emitting state may be different in accordance with the distance from the outer portion  1   c . For example, the brightness of the inner portion  1   a  adjacent to the outer portion  1   c  in the individual light-emitting state can be made higher than the brightness of the inner portion  1   a  closest to the center of the light guide member  10  in the individual light-emitting state. Thus, in the entire light-emitting state, light from the inner portion  1   a  adjacent to the outer portion  1   c  can compensate for a decrease in the brightness of the outer portion  1   c  and reduce luminance unevenness on the light-emitting surface of the planar light source. 
     As illustrated in  FIGS.  2  and  5   , in one light-emitting unit  1 , the first light-reflective member  40  can overlap and continuously cover all of the light source  20 A and the first hole portion h 1  in the plan view. 
     As illustrated in  FIG.  7 A , the first light-reflective member  40  may has opening portions  40   a . Further, as illustrated in  FIG.  7 B , the first light-reflective member  40  may be disposed in a plurality of dot shapes, and a gap  40   b  in which no first light-reflective member  40  is disposed in a region surrounded by the plurality of dot-shaped first light-reflective members  40  may be formed. Further, as illustrated in  FIG.  7 C , a plurality of first light-reflective members  40  may be disposed with gaps  40   c  so that a plurality of dots do not overlap. The first light-reflective member  40  can be formed, for example, by applying. The first light-reflective member  40  may be formed for each dot or may be formed by printing a plurality of dots at a time. When the first light-reflective member  40  is formed by printing a plurality of dots at a time, for example, the first light-reflective member  40  illustrated in  FIG.  7 B  is less likely to have a thickness variation even in a region where the plurality of dots overlap. 
     In the first light-reflective member  40 , the first light-reflective member  40  disposed on the inner portion  1   a  is referred to as an inner light-reflective member  40 A (illustrated in  FIG.  3   ). In the first light-reflective member  40 , the first light-reflective member  40  disposed on the outer portion  1   b  and/or the outer portion  1   c  is referred to as an outer light-reflective member  40 B (illustrated in  FIG.  6   ). In  FIGS.  7 A to  7 C , the inner light-reflective member  40 A and the outer light-reflective member  40 B may be indicated as the first light-reflective member  40  without distinction. 
     The following describes embodiments for making the brightness of one outer portion  1   b  and the brightness of one outer portion  1   c  higher than the brightness of one inner portion  1   a  in a state in which the one outer portion  1   b , the one outer portion  1   c , and the one inner portion  1   a  are individually allowed to emit light with the same power. According to the embodiments, as will be described below, the brightness of one outer portion  1   b , and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a , so that luminance unevenness on the light-emitting surface of the planar light source in the entire light-emitting state can be reduced. Note that the embodiments can be implemented independently, or two or more of the embodiments can be combined and implemented. 
     First Embodiment 
     According to the first embodiment, in a plan view, the covering ratio of the outer light-reflective member  40 B covering the outer portion  1   b  (or an area of the outer light-reflective member  40 B per unit area in the outer portion  1   b ) is smaller than the covering ratio of the inner light-reflective member  40 A covering the inner portion  1   a  (or an area of the inner light-reflective member  40 A per unit area in the inner portion  1   a ). Thus, the amount of light extracted above the outer portion  1   b  can be greater than the amount of light extracted above the inner portion  1   a , and the brightness of one outer portion  1   b  can be higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     Further, in the plan view, the covering ratio of the outer light-reflective member  40 B covering the outer portion  1   c  (or an area of the outer light-reflective member  40 B per unit area in the outer portion  1   c ) is smaller than the covering ratio of the inner light-reflective member  40 A covering the inner portion  1   a  (or an area of the inner light-reflective member  40 A per unit area in the inner portion  1   a ). Thus, the amount of light extracted above the outer portion  1   c  can be greater than the amount of light extracted above the inner portion  1   a , and the brightness of one outer portion  1   c  can be higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     For example, the inner light-reflective member  40 A may not be formed with the opening portion  40   a  illustrated in  FIG.  7 A , the gap  40   b  illustrated in  FIG.  7 B , and the gap  40   c  illustrated in  FIG.  7 C , and the outer light-reflective member  40 B can be formed with the opening portion  40   a , the gap  40   b , and the gap  40   c . Further, the number of opening portions  40   a , gaps  40   b , and gaps  40   c  formed in the outer light-reflective member  40 B can be made greater than the number of opening portions  40   a , gaps  40   b , and gaps  40   c  formed in the inner light-reflective member  40 A. Further, the size of each of the opening portion  40   a , the gap  40   b , and the gap  40   c  formed in the outer light-reflective member  40 B can be made greater than the size of each of the opening portion  40   a , the gap  40   b , and the gap  40   c  formed in the inner light-reflective member  40 A. Further, the number of opening portions  40   a , gaps  40   b , and gaps  40   c  formed in the outer light-reflective member  40 B can be made greater than the number of opening portions  40   a , gaps  40   b , and gaps  40   c  formed in the inner light-reflective member  40 A, and the size of each of the opening portion  40   a , the gap  40   b , and the gap  40   c  formed in the outer light-reflective member  40 B can be made greater than the size of each of the opening portion  40   a , the gap  40   b , and the gap  40   c  formed in the inner light-reflective member  40 A. 
     Second Embodiment 
     According to the second embodiment, by making the light transmittance of the outer light-reflective member  40 B higher than the light transmittance of the inner light-reflective member  40 A, the brightness of one outer portion  1   b  can be higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     For example, by making the thickness of the outer light-reflective member  40 B illustrated in  FIG.  6    thinner than the thickness of the inner light-reflective member  40 A illustrated in  FIG.  3   , the light transmittance of the outer light-reflective member  40 B can be made higher than the light transmittance of the inner light-reflective member  40 A. Further, by making the concentration of the light scattering particles contained in the outer light-reflective member  40 B lower than the concentration of the light scattering particles contained in the inner light-reflective member  40 A, the light transmittance of the outer light-reflective member  40 B can be made higher than the light transmittance of the inner light-reflective member  40 A. When the concentration of the light scattering particles contained in the outer light-reflective member  40 B is lower than the concentration of the light scattering particles contained in the inner light-reflective member  40 A, the outer light-reflective member  40 B may include no light scattering particles. The concentration of the light scattering particles contained in the inner light-reflective member  40 A and the concentration of the light scattering particles contained in the outer light-reflective member  40 B can be set in a range from 20% by weight to 30% by weight, for example. The difference between the concentration of the light scattering particles contained in the outer light-reflective member  40 B and the concentration of the light scattering particles contained in the inner light-reflective member  40 A can be set within, for example, 5% by weight. Further, by making the thickness of the outer light-reflective member  40 B thinner than the thickness of the inner light-reflective member  40 A and making the concentration of the light scattering particles contained in the outer light-reflective member  40 B lower than the concentration of the light scattering particles contained in the inner light-reflective member  40 A, the light transmittance of the outer light-reflective member  40 B can be made higher than the light transmittance of the inner light-reflective member  40 A. 
     Third Embodiment 
     According to the third embodiment, as illustrated in  FIG.  2   , in the plan view, the inner light-reflective member  40 A covers an outer edge h 1   a  of the first hole portion h 1  that defines the first hole portion h 1 . On the other hand, in the plan view, the outer edge h 1   a  of the first hole portion h 1  that defines the first hole portion h 1  around the outer light-reflective member  40 B is exposed. As illustrated in  FIG.  8   , in a cross-sectional view, the outer edge h 1   a  of the first hole portion h 1  that defines the first hole portion h 1  around the outer light-reflective member  40 B is exposed. An end portion of the outer light-reflective member  40 B may be covered by the first light-transmissive member  30 . 
     At a boundary between the first light-transmissive member  30  and the light guide member  10 , reflection and refraction of light may occur and light heading upward may increase depending on a difference in refractive index between the first light-transmissive member  30  and the light guide member  10 . That is, luminance in the vicinity of the outer edge h 1   a  of the first hole portion h 1  located at an upper end of the boundary between the first light-transmissive member  30  and the light guide member  10  may increase. Consequently, because the inner light-reflective member  40 A covers the outer edge h 1   a  of the first hole portion h 1  and the outer edge h 1   a  of the first hole portion h 1  in the outer light-reflective member  40 B is exposed, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     Further, in the outer portion  1   b  or the outer portion  1   c  illustrated in  FIG.  8   , the upper surface of the first light-transmissive member  30  has a region not covered by the outer light-reflective member  40 B. In the region, light from the first light-transmissive member  30  is extracted upward without transmitting the outer light-reflective member  40 B. Thus, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     Fourth Embodiment 
     According to the fourth embodiment, the concentration of the light diffusing material in the first light-transmissive member  30  at the outer portion  1   b  and/or the outer portion  1   c  is made higher than the concentration of the light diffusing material in the first light-transmissive member  30  at the inner portion  1   a . In this case, the concentration of the light diffusing material in the first light-transmissive member  30  at the inner portion  1   a  may be 0, that is, the first light-transmissive member  30  at the inner portion  1   a  may not contain the light diffusing material. The concentration of the light diffusing material in the first light-transmissive member  30  at the outer portion  1   b  and/or the outer portion  1   c  is in a range from 0.1% by weight to 2% by weight, for example. The concentration of the light diffusing material in the first light-transmissive member  30  at the inner portion  1   a  is in a range from 0% by weight to 0.1% by weight, for example. According to the fourth embodiment, light traveling in various directions can be incident on the outer light-reflective member  40 B by diffuse reflection in the first light-transmissive member  30  at the outer portion  1   b  and/or the outer portion  1   c . Thus, at the outer portion  1   b  and/or the outer portion  1   c , the amount of light extracted above the outer portion  1   b  and/or the outer portion  1   c  without being reflected at an interface between the first light-transmissive member  30  and the outer light-reflective member  40 B can be greater than the amount of light at the inner portion  1   a . As a result, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     Fifth Embodiment 
     According to the fifth embodiment, the brightness of the light source  20 A itself at the outer portion  1   b  and/or the outer portion  1   c  is made higher than the brightness of the light source  20 A itself at the inner portion  1   a , so that the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. For example, in a state in which the same power is supplied, the light source  20 A with high output is disposed at the outer portion  1   b  and/or the outer portion  1   c , and the light source  20 A with lower output than the light source  20 A disposed at the outer portion  1   b  and/or the outer portion  1   c  is disposed at the inner portion  1   a , so that the brightness of the light source  20 A at the outer portion  1   b  and/or the outer portion  1   c  can be made higher than the brightness of the light source  20 A at the inner portion  1   a . Further, for example, the size of the light source  20 A at the outer portion  1   b  and/or the outer portion  1   c  is made greater than the size of the light source  20 A at the inner portion  1   a , so that the brightness of the light source  20 A at the outer portion  1   b  and/or the outer portion  1   c  can be made higher than the brightness of the light source  20 A at the inner portion  1   a.    
     Sixth Embodiment 
       FIG.  9    is a schematic top view of the portion B of  FIG.  1    in a planar light source of the sixth embodiment. 
       FIG.  10    is a schematic cross-sectional view taken along line X-X in  FIG.  9   . 
     According to the sixth embodiment, a third light-transmissive member  16  is disposed on the upper surface of the outer portion  1   b  and/or the outer portion  1   c  (the first surface  11  of the light guide member  10 ). The third light-transmissive member  16  is disposed between the light source  20 A at one outer portion  1   b  and/or one outer portion  1   c  and an outer surface of another outer portion  1   b  and/or another outer portion  1   c  in the plan view. The outer surface of the outer portion  1   b  and/or the outer portion  1   c  is a lateral surface on the side where there are no adjacent light-emitting units  1 , and extends along the first direction X and the second direction Y to form an outer edge of the planar light source. The third light-transmissive member  16  is continuously disposed along the first direction X and the second direction Y except for the position of the groove  14 . Alternatively, the third light-transmissive member  16  may be intermittently disposed along the first direction X and the second direction Y to cover the groove  14 . 
     The third light-transmissive member  16  is a resin member light-transmissive to light emitted from the light source  20 A. As a resin material of the third light-transmissive member  16 , a thermoplastic resin such as an acrylic resin, a polycarbonate resin, a cyclic polyolefin resin, a polyethylene terephthalate resin, or a polyester resin, or a thermosetting resin such as an epoxy resin or a silicone resin can be used, for example. The refractive index of the resin member of the third light-transmissive member  16  is smaller than the refractive index of the light guide member  10  and is greater than the refractive index of the air. That is, the third light-transmissive member  16  having a refractive index between the refractive index of the light guide member  10  and the refractive index of the air is disposed between the first surface  11  of the light guide member  10  and the air at the outer portion  1   b  and/or the outer portion  1   c . Thus, compared with a case in which the first surface  11  of the light guide member  10  is directly in contact with the air, the total reflection on an optical path between the first surface  11  of the light guide member  10  and the air can be reduced and the amount of light extracted upward from the upper surface of the outer portion  1   b  and/or the outer portion  1   c  can be increased. As a result, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     The third light-transmissive member  16  can further conain light scattering particles. Light can be diffused by the light scattering particles to further increase the amount of light extracted above the third light-transmissive member  16 . For example, a member having the same configuration as the partition member  15  disposed in the groove  14  can be used as the third light-transmissive member  16 . For example, the thickness of the third light-transmissive member  16  can be set in a range from 5 μm to 30 μm, and as light scattering particles in the third light-transmissive member  16 , the concentration of titanium oxide can be set in a range from 40% by weight to 70% by weight, for example. 
     As illustrated in  FIG.  11   , the third light-transmissive member  16  can be disposed so as to cover the partition member  15  disposed on an outer surface  14   c  of the outer portion  1   b  and/or the outer portion  1   c . Thus, the amount of light returned by reflection from the outer surface  14   c  side into the light guide member  10  can be increased, and the light returned from the outer surface  14   c  side can be further reflected on the second surface  12  side and directed upward. This can further increase the amount of light extracted above the outer portion  1   b  and/or the outer portion  1   c.    
     The outer surface  14   c  is one lateral surface, of a pair of lateral surfaces that define the groove  14 , that is left by the cutting of the groove  14 . Therefore, the partition member  15  is already disposed on the outer surface  14   c , and the third light-transmissive member  16  is further disposed to cover the partition member  15 . The same material can be used for the partition member  15  and the third light-transmissive member  16 , and the thickness of the light-transmissive member (the partition member  15  and the third light-transmissive member  16 ) disposed on the outer surface  14   c  of the outer portion  1   b  and/or the outer portion  1   c  is thicker than the thickness of the third light-transmissive member  16  disposed on the upper surface of the outer portion  1   b  and/or the outer portion  1   c . By thickening the light-transmissive member of the outer surface  14   c  of the outer portion  1   b  and/or the outer portion  1   c , light returned from the outer surface  14   c  into the light guide member  10  can be further increased, so that the amount of light extracted above the outer portion  1   b  and/or the outer portion  1   c  can be further increased. 
     The third light-transmissive member  16  may be disposed on the lower surface of the outer portion  1   b  and/or the outer portion  1   c  (the second surface  12  of the light guide member  10 ). Similar to the third light-transmissive member  16  disposed on the upper surface of the outer portion  1   b  and/or the outer portion  1   c , the third light-transmissive member  16  disposed on the lower surface of the outer portion  1   b  and/or the outer portion  1   c  can also be disposed between the light source  20 A on the outer portion  1   b  and/or the outer portion  1   c  and the outer surface of the outer portion  1   b  and/or the outer portion  1   c  in the plan view. The third light-transmissive member  16  disposed on the lower surface of the outer portion  1   b  and/or the outer portion  1   c  preferably contains light scattering particles. Thus, the amount of light extracted above the outer portion  1   b  and/or the outer portion  1   c  can be increased by diffuse reflection in the third light-transmissive member  16  disposed on the lower surface of the outer portion  1   b  and/or the outer portion  1   c.    
     Seventh Embodiment 
       FIG.  12    is a schematic top view of a part of a planar light source according to the seventh embodiment (portion including the upper right corner of the planar light source illustrated in  FIG.  1   ). 
     According to the seventh embodiment, a groove  14 A is further disposed in the outer portion  1   b  and/or the outer portion  1   c  in addition to the groove  14  that separates the light guide member  10  into the plurality of light-emitting units  1 . The groove  14 A is disposed between the light source  20 A on the outer portion  1   b  and/or the outer portion  1   c  and the outer surface  14   c  of the outer portion  1   b  and/or the outer portion  1   c  in the plan view, and extends in the first direction X and the second direction Y. The shape, size, depth, and the like of the groove  14 A can be the same as the groove  14 . Further, the partition member  15  may also be disposed in the groove  14 A. 
     Light traveling from the light source  20 A toward the groove  14 A in the light guide member  10  tends to change its direction upward due to refraction or reflection at an interface between the light guide member  10  and the groove  14 A. Therefore, light is easily extracted upward from the groove  14 A disposed on the outer portion  1   b  and/or the outer portion  1   c , and the groove  14 A becomes a bright line. The bright line is disposed in a region of the outer portion  1   b  and/or the outer portion  1   c  on the outer surface  14   c  side, so that it is possible to compensate for a decrease in luminance on the outer surface  14   c  side where there are no adjacent light-emitting units  1 . As a result, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     Because light directed from the light source  20 A toward the outer surface  14   c  is easily extracted upward from the groove  14 A, the light does not easily reach a region between the groove  14 A and the outer surface  14   c . Therefore, the substantial light-emitting area of the outer portion  1   b  and the substantial light-emitting area of the outer portion  1   c  can be made smaller than the light-emitting area of the inner portion  1   a , and the light emission intensity per unit area of the outer portion  1   b  and the light emission intensity per unit area of the outer portion  1   c  can be made higher than the light emission intensity per unit area of the inner portion  1   a . Thus, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     As illustrated in  FIG.  13   , in the plan view, a fourth light-reflective member  17  (represented by hatching in  FIG.  13   ) can be disposed on an upper surface (the first surface  11  of the light guide member  10 ) between the groove  14 A disposed in the outer portion  1   b  and/or the outer portion  1   c  and the outer surface  14   c.    
     The planar light source can be used as a backlight of a liquid crystal display device, for example. In this case, a light-emitting surface of the planar light source (first surface of the light guide member  10 ) is disposed to face the liquid crystal panel, and an optical sheet such as a light diffusion sheet or a prism sheet may be disposed between the light-emitting surface of the planar light source and the liquid crystal panel. The fourth light-reflective member  17  reflects return light from the optical sheet to the planar light source side toward the optical sheet side. As described above, the region between the groove  14 A and the outer surface  14   c  in the light guide member  10  is less likely to serve as a substantially light-emitting region. Consequently, disposing the fourth light-reflective member  17  on the region between the groove  14 A and the outer surface  14   c  can suppress return light from the optical sheet from being incident on the region between the groove  14 A and the outer surface  14   c  in the light guide member  10  and becoming loss light. 
     The fourth light-reflective member  17  is, for example, a resin member containing light scattering particles. As the fourth light-reflective member  17 , for example, a member made of the same material as the first light-reflective member  40  can be used. For example, the thickness of the fourth light-reflective member  17  can be set in a range from 50 μm to 100 μm, and the concentration of, for example, titanium oxide as the light scattering particles in the fourth light-reflective member  17  can be set in a range from 20% by weight to 30% by weight. 
     Eighth Embodiment 
       FIG.  14    is a schematic top view of a part of a planar light source according to the eighth embodiment (portion including the upper right corner of the planar light source illustrated in  FIG.  1   ). 
     According to the eighth embodiment, the position of the light source  20 A disposed on the outer portion  1   b  is shifted from the center of the outer portion  1   b  to the outer surface  14   c  side in the plan view, and the position of the light source  20 A disposed on the outer portion  1   c  is shifted from the center of the outer portion  1   c  to the outer surface  14   c  side in the plan view. In the present embodiment, the center of the light source  20 A disposed on the outer portion  1   b  in the plan view is shifted from the center of the outer portion  1   b  to the outer surface  14   c  side by 10 μm or more in the plan view, and the center of the light source  20 A disposed on the outer portion  1   c  in the plan view is shifted from the center of the outer portion  1   c  to the outer surface  14   c  side by 10 μm or more in the plan view. The center of the light source  20 A disposed on the outer portion  1   b  in the plan view is preferably shifted from the center of the outer portion  1   b  to the outer surface  14   c  side by 20 μm or more in the plan view, and the center of the light source  20 A disposed on the outer portion  1   c  in the plan view is preferably shifted from the center of the outer portion  1   c  to the outer surface  14   c  side by 20 μm or more in the plan view. In the plan view, the shapes of the outer portion  1   b  and the outer portion  1   c  are quadrangles, and the center of the outer portion  1   b  and the center of the outer portion  1   c  are each located at an intersection of two diagonal lines of each of the quadrangles. In the plan view, the shape of the light source  20 A is a quadrangle, and the center of the light source  20 A is located at an intersection of two diagonal lines of the quadrangle. In  FIG.  14   , a center line Cx that virtually divides the outer portion  1   b  and the outer portion  1   c  into two equal parts in the first direction X and a center line Cy that virtually divides the outer portion  1   b  and the outer portion  1   c  into two equal parts in the second direction Y are represented by one-dot chain lines, respectively. 
     In the plan view, the centers of the respective light sources  20 A disposed on the plurality of outer portions  1   b  arranged in the first direction X are located closer to the outer surface  14   c  side than the center line Cy in the second direction Y. The distance in the second direction Y between the center of the light sources  20 A on the outer portion  1   b  and the center of the light sources  20 A on the inner portion  1   a  adjacent in the second direction Y is longer than the distance in the second direction Y between the centers of the light sources  20 A on the inner portions  1   a  adjacent in the second direction Y. 
     In the plan view, the centers of the respective light sources  20 A disposed on the plurality of outer portions  1   b  arranged in the second direction Y are located closer to the outer surface  14   c  side than the center line Cx in the first direction X. The distance in the first direction X between the center of the light sources  20 A on the outer portion  1   b  and the center of the light sources  20 A on the inner portion  1   a  adjacent in first direction X is longer than the distance in the first direction X between the centers of the light sources  20 A on the inner portions  1   a  adjacent in the first direction X. 
     In the plan view, the center of the light source  20 A disposed on the outer portion  1   c  at a corner is located closer to the outer surface  14   c  side than the center line Cy in the second direction Y, and is located closer to the outer surface  14   c  side than the center line Cx in the first direction X. That is, the center of the light source  20 A disposed on the outer portion  1   c  at the corner is shifted from the center of the outer portion  1   c  to become closer to the corner of the light guide member  10 . 
     According to the eighth embodiment, the position of the light source  20 A on each of the outer portion  1   b  and the outer portion  1   c  is shifted to the outer surface  14   c  side, so that it is possible to compensate for a decrease in luminance on the outer surface  14   c  side where adjacent light-emitting units  1  are not disposed. Moreover, while compensating for a decrease in luminance on the outer surface  14   c  side by combining the eighth embodiment with at least one of the other embodiments, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     The number of adjacent light-emitting units  1  on the outer portion  1   c  at the corner is smaller than the outer portion  1   b  not located at the corner. Therefore, only the light source  20 A disposed on the outer portion  1   c  at the corner is shifted to the outer surface  14   c  side from the center line Cy in the second direction Y and is shifted to the outer surface  14   c  side from the center line Cx in the first direction X, so that it also contribute to reduce luminance unevenness on the light-emitting surface of the planar light source in the entire light-emitting state. 
     In the plan view, the center of the outer light-reflective member  40 B is located in the center of the light source  20 A on the outer portion  1   c . In the plan view, the center of the first hole portion h 1  on the outer portion  1   c  is located in the center of the light source  20 A on the outer portion  1   c . Alternatively, in the plan view, the center of the first hole portion h 1  may be located in the center of the outer portion  1   c , and the center of the light source  20 A may be shifted from the center of the first hole portion h 1  to the outer surface  14   c  side. 
     Ninth Embodiment 
       FIG.  15    is a schematic top view of a part of a planar light source according to the ninth embodiment (portion including the upper right corner of the planar light source illustrated in  FIG.  1   ). 
     According to the ninth embodiment, the position of the outer light-reflective member  40 B disposed on each of the outer portion  1   b  and the outer portion  1   c  is shifted from the center of each of the outer portion  1   b  and the outer portion  1   c  to the inner portion  1   a  side in the plan view. 
     In the plan view, the center of each of the outer light-reflective member  40 B disposed on the plurality of outer portions  1   b  arranged in the first direction X is located closer to the inner portion  1   a  side than the center line Cy in the second direction Y. The distance in the second direction Y between the center of the outer light-reflective member  40 B on the outer portions  1   b  and the center of the inner light-reflective member  40 A on the inner portion  1   a  adjacent in the second direction Y is shorter than the distance in the second direction Y between the centers of the inner light-reflective members  40 A on the inner portions  1   a  adjacent in the second direction Y. When the shape of the first light-reflective member  40  in the plan view is a quadrangle, the center of the first light-reflective member  40  including the inner light-reflective member  40 A and the outer light-reflective member  40 B is located on an intersection of diagonal lines of the quadrangle, and when the shape of the first light-reflective member  40  in the plan view is a circle, the center of the first light-reflective member  40  is located in the center of the circle. Further, when the shape of the first light-reflective member  40  in the plan view is a quadrangle with rounded corners, an intersection of the diagonal lines of the quadrangles defined by an intersection of extension lines of each side is referred to as the center of the first light-reflective member  40 . 
     In the plan view, the center of the outer light-reflective member  40 B disposed on each of the plurality of outer portions  1   b  arranged in the second direction Y is located closer to the inner portion  1   a  side than the center line Cx in the first direction X. The distance in the first direction X between the center of the outer light-reflective member  40 B on the outer portions  1   b  and the center of the inner light-reflective member  40 A on the inner portion  1   a  adjacent in the first direction X is shorter than the distance in the first direction X between the centers of the inner light-reflective members  40 A on the inner portions  1   a  adjacent in the first direction X. 
     In the plan view, the center of the outer light-reflective member  40 B disposed on the outer portion  1   c  at the corner is located closer to the inner portion  1   a  side than the center line Cy in the second direction Y, and is located closer to the inner portion  1   a  side than the center line Cx in the first direction X. 
     According to the ninth embodiment, the position of the outer light-reflective member  40 B on the outer portion  1   b  and the outer portion  1   c  is shifted to the inner portion  1   a  side, so that the amount of light extracted from the light source  20 A above the region on the outer surface  14   c  side can be increased. Thus, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state while compensating for a decrease in luminance on the outer surface  14   c  side where adjacent light-emitting units  1  are not disposed. 
     In the ninth embodiment, in the plan view, the center of the light source  20 A on the outer portion  1   b  and the outer portion  1   c  is located in the center of the outer portion  1   b  and the outer portion  1   c . Alternatively, by combining the ninth embodiment with the eighth embodiment, the position of the outer light-reflective member  40 B on the outer portion  1   b  and the outer portion  1   c  may be shifted to the inner portion  1   a  side, and the position of the light source  20 A on the outer portion  1   b  and the outer portion  1   c  may be shifted to the outer surface  14   c  side. Further, in the ninth embodiment, only the outer light-reflective member  40 B disposed on the outer portion  1   c  at the corner may be shifted to the inner portion  1   a  side from the center line Cy in the second direction Y, and may be shifted to the inner portion  1   a  side from the center line Cx in the first direction X. 
     Tenth Embodiment 
       FIG.  16    is a schematic top view of a part of a planar light source according to the tenth embodiment (portion including the upper right corner of the planar light source illustrated in  FIG.  1   ). 
     According to the tenth embodiment, the size of an area of the outer portion  1   b  and the size of an area of the outer portion  1   c  in the plan view are made smaller than the size of an area of the inner portion  1   a . For example, as illustrated in  FIG.  16   , the groove  14  that separates the outer portion  1   b  and the inner portion  1   a  adjacent to this outer portion  1   b , and the groove  14  that separates the outer portion  1   c  and the inner portion  1   a  adjacent to this outer portion  1   c , are shifted to the light source  20 A side disposed on this outer portion  1   b  and the light source  20 A side disposed on this outer portion  1   c  with respect to the light source  20 A disposed on the inner portion  1   a  adjacent to this outer portion  1   b  and the light source  20 A disposed on the inner portion  1   a  adjacent to this outer portion  1   c  in the plan view, so that the size of the area of the outer portion  1   b  and the size of the area of the outer portion  1   c  in the plan view can be made smaller than the size of the area of the inner portion  1   a.    
     In the plan view, the length in the second direction Y of the plurality of outer portions  1   b  arranged in the first direction X is shorter than the length in the second direction Y of the inner portion  1   a . In the plan view, the length in the first direction X of the plurality of outer portions  1   b  arranged in the second direction Y is shorter than the length in the first direction X of the inner portion  1   a . The length in the first direction X of the outer portion  1   c  at the corner is shorter than the length in the first direction X of the inner portion  1   a , and the length in the second direction Y of the outer portion  1   c  at the corner is shorter than the length in the second direction Y of the inner portion  1   a.    
     According to the tenth embodiment, the light-emitting area of the outer portion  1   b  and the light-emitting area of the outer portion  1   c  defined by the groove  14  and the outer surface  14   c  can be made smaller than the light-emitting area of the inner portion  1   a  defined by the groove  14 , and the light emission intensity per unit area of the outer portion  1   b  and the light emission intensity per unit area of the outer portion  1   c  can be made higher than the light emission intensity per unit area of the inner portion  1   a . Thus, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. Note that in  FIG.  16   , the inner portion  1   a  adjacent to the outer portion  1   b  in the first direction X and the inner portion  1   a  adjacent to the outer portion  1   b  in the second direction Y have a larger light-emitting area than the inner portion  1   a  not adjacent to either the outer portion  1   b  or the outer portion  1   c , but all the inner portions  1   a  may have the same light-emitting area. For example, by shifting the region of the outer surface  14   c  to the light source  20  side disposed on the outer portion  1   b  and the light source  20 A side disposed on the outer portion  1   c , the light-emitting area of the outer portion  1   b  and the light-emitting area of the outer portion  1   c  can be made smaller than the light-emitting areas of all the inner portions  1   a  while allowing all the inner portions  1   a  to have the same light-emitting area. 
     By combining the tenth embodiment with the eighth embodiment, the position of the light source  20 A on the outer portion  1   b  and the position of the light source  20 A on the outer portion  1   c  may be shifted to the outer surface  14   c  side while reducing the light-emitting area of the outer portion  1   b  and the light-emitting area of the outer portion  1   c . Further, by combining the tenth embodiment with the ninth embodiment, the position of the outer light-reflective member  40 B on the outer portion  1   b  and the position of the outer light-reflective member  40 B on the outer portion  1   c  may be shifted to the inner portion  1   a  side while reducing the light-emitting area of the outer portion  1   b  and the light-emitting area of the outer portion  1   c . Moreover, the tenth embodiment may be combined with both the eighth embodiment and the ninth embodiment. Further, in the tenth embodiment, the distance between the light sources  20 A respectively disposed in the light-emitting units  1  may be made constant while reducing the light-emitting area of the outer portion  1   b  and the light-emitting area of the outer portion  1   c.    
     Eleventh Embodiment 
       FIG.  17    is a schematic top view of a part of a planar light source according to the eleventh embodiment (portion including the upper right corner of the planar light source illustrated in  FIG.  1   ). 
     According to the eleventh embodiment, the number of light sources  20 A disposed on one outer portion  1   b  and the number of light sources  20 A disposed on one outer portion  1   c  are greater than the number of light sources  20 A disposed on one inner portion  1   a . For example, two light sources  20 A can be disposed on one outer portion  1   b , two light sources  20 A can be disposed on one outer portion  1   c , and one light source  20 A can be disposed on one inner portion  1   a . Thus, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     The outer light-reflective member  40 B on one outer portion  1   b  overlaps a plurality of light sources  20 A on one outer portion  1   b  in the plan view, and the outer light-reflective member  40 B on one outer portion  1   c  overlaps a plurality of light sources  20 A on one outer portion  1   c  in the plan view. 
     Twelfth Embodiment 
       FIG.  18    is a schematic cross-sectional view of a part of a planar light source according to the twelfth embodiment. 
     The light guide member  10  further includes a second hole portion h 2 . The second hole portion h 2  is located between the light source  20 A and the groove  14 . The second hole portion h 2  opens to the first surface  11  side. The bottom surface of the light guide member  10  defining the second hole portion h 2  includes, for example, the light guide member  10 , and is preferably located below the upper surface of the light source  20 A in the cross-sectional view. Further the depth of the second hole portion h 2  can be preferably 100 μm or more, more preferably 200 μm or less. The second hole portion h 2  may penetrate between the first surface  11  and the second surface  12 . The second hole portion h 2  may open to the second surface  12  side. The second hole portion h 2  may be hollow and not have an opening portion in either of the first surface  11  side or the second surface  12  side. 
     Light traveling from the light source  20 A toward the groove  14  in the light guide member  10  tends to change its direction above the second hole portion h 2  due to refraction or reflection of light at an interface between the light guide member  10  and the second hole portion h 2 . Therefore, light can be easily extracted above the second hole portion h 2 , so that an upper part in a region directly above the second hole portion h 2  and a region around the second hole portion h 2  can be lightened. 
     According to the twelfth embodiment, the number of second hole portions h 2  disposed in one outer portion  1   b  is greater than the number of second hole portions h 2  disposed in one inner portion  1   a . The number of second hole portions h 2  disposed in one outer portion  1   c  is greater than the number of second hole portions h 2  disposed in one inner portion  1   a . The second hole portion h 2  may not be disposed in the inner portion  1   a . Alternatively, in the plan view, an area of the second hole portion h 2  disposed in the one outer portion  1   b  may be greater than an area of the second hole portion h 2  disposed in the one inner portion  1   a . An area of the second hole portion h 2  disposed in one outer portion  1   c  may be greater than the area of the second hole portion h 2  disposed in one inner portion  1   a . When a plurality of second hole portions h 2  are disposed in each of one outer portion  1   b , one outer portion  1   c , and one inner portion  1   a , the area of the second hole portion h 2  indicates the total value of the areas of the plurality of second hole portions h 2 . Thus, according to the twelfth embodiment, the brightness of one outer portion  1   b  can be made higher than the brightness of one inner portion  1   a  and the brightness of one outer portion  1   c  can be made higher than the brightness of one inner portion  1   a  in the individual light-emitting state. 
     Hereinafter, arrangement examples of the second hole portion h 2  are described with reference to schematic top views of  FIGS.  19  to  23 B . In  FIGS.  19  to  23 B , the outer portion  1   b , the outer portion  1   c , and the inner portion  1   a  are not distinguished and are referred to as the light-emitting unit  1 . The second hole portion h 2  illustrated in  FIGS.  19  to  23 B  can be applied to any of the outer portion  1   b , the outer portion  1   c , and the inner portion  1   a.    
     As illustrated in  FIGS.  19  to  21   , in the plan view, the second hole portion h 2  can be, for example, circular. Further, the shape of the second hole portion h 2  can be, for example, an ellipse, or a polygon such as a triangle, a quadrangle, a hexagon, or an octagon in the plan view. Further, the shape of the second hole portion h 2  can be, for example, a linear shape in the plan view. When the second hole portion h 2  is linear shape in the plan view, the second hole portion h 2  can be a groove extending along the groove  14  and the outer surface  14   c.    
     In the plan view, the second hole portion h 2  disposed in one light-emitting unit  1 , of adjacent light-emitting units  1  having the groove  14  interposed therebetween, is referred to as one second hole portion h 2 , and the second hole portion h 2  disposed in the other light-emitting unit  1 , of the adjacent light-emitting units  1  having the groove  14  interposed therebetween, is referred to as the other second hole portion h 2 . 
     As described above, light can be easily extracted upward in the second hole portion h 2 . Therefore, in a position where the second hole portion h 2  is in the intermediate portion of an optical path from the light source  20 A toward the groove  14 , the light is less likely to reach a region ahead of the second hole portion h 2 . That is, in the groove  14  and a region in the vicinity of the groove  14 , a region facing the second hole portion h 2  tends to be dark in the plan view. 
     According to the examples illustrated in  FIGS.  19  to  21   , positions in the second direction Y of the one second hole portion h 2  and the other second hole portion h 2  that are adjacent to each other with the groove  14  interposed therebetween without interposing the light source  20 A therebetween in the first direction X are shifted from each other. In other words, in two adjacent light-emitting units  1  having the groove  14  interposed therebetween in the first direction X, positions in the second direction Y of the second hole portion  2   h  closest to the groove  14  of the one light-emitting unit  1  and the second hole portion  2   h  closest to the groove  14  of the other light-emitting unit  1  are shifted from each other. In the plan view, the other second hole portion h 2  is not located on a straight line passing through the center of the one second hole portion h 2  and parallel to the first direction X. In the plan view, the one second hole portion h 2  is not located on a straight line passing through the center of the other second hole portion h 2  and parallel to the first direction X. 
     Further, positions in the first direction X of the one second hole portion h 2  and the other second hole portion h 2  that are adjacent to each other with the groove  14  interposed therebetween without interposing the light source  20 A therebetween in the second direction Y are shifted from each other. In other words, in two adjacent light-emitting units  1  having the groove  14  interposed therebetween in the second direction Y, positions in the first direction X of the second hole portion  2   h  closest to the groove  14  of the one light-emitting unit  1  and the second hole portion  2   h  closest to the groove  14  of the other light-emitting unit  1  are shifted from each other. In the plan view, the other second hole portion h 2  is not located on a straight line passing through the center of the one second hole portion h 2  and parallel to the second direction Y. In the plan view, the one second hole portion h 2  is not located on a straight line passing through the center of the other second hole portion h 2  and parallel to the second direction Y. 
     Thus, it is possible to suppress a region ahead of the second hole portion h 2  on the optical path from the light source  20 A toward the groove  14  from becoming dark. As a result, luminance unevenness on the light-emitting surface of the planar light source can be reduced. 
     In the example illustrated in  FIG.  19   , two second hole portions h 2  are disposed in the region between the light source  20 A and the groove  14  in each of the light-emitting units  1  in the direction along the groove  14 . Note that three or more second hole portions h 2  may be disposed in the region between the light source  20 A and the groove  14  in each of the light-emitting units  1  in the direction along the groove  14 . Further, as illustrated in  FIG.  20   , one second hole portion h 2  may be disposed in the region between the light source  20 A and the groove  14  in each of the light-emitting units  1 . Further, a plurality of second hole portions h 2  may be disposed in the region between the light source  20 A and the groove  14  in each of the light-emitting units  1  along a direction orthogonal to or oblique with respect to the direction in which the groove  14  extends. 
     Further, as illustrated in  FIG.  21   , in the plan view, in one light-emitting unit  1 , the second hole portion h 2  can be disposed in the vicinity of each of four corners, and in the other light-emitting unit  1  adjacent to the one light-emitting unit  1 , the second hole portion h 2  can be disposed at a position where the light-emitting unit  1  is equally divided into two in the first direction X and a position where the light-emitting unit  1  is equally divided into two in the second direction Y. 
     Next, second hole portions h 2  illustrated in  FIGS.  22 A to  23 B  are described. In  FIGS.  22 A to  23 B , for convenience of description, a virtual first straight line L 1  and a second straight line L 2  are set in the light-emitting unit  1 . The first straight line L 1  is a straight line connecting the center of the light source  20 A and a position farthest from the center of the light source  20 A in the groove  14  in a plan view of the light-emitting unit  1 . The second straight line L 2  is a straight line connecting the center of the light source  20 A and a position closest to the center of the light source  20 A in the groove  14  in the plan view of the light-emitting unit  1 . The shape of the light-emitting unit  1  in the plan view is a quadrangle, and the center of the light source  20 A matches the center of the light-emitting unit  1 . In this case, the position farthest from the center of the light source  20 A in the groove  14  is the corner of the light-emitting unit  1 . The position closest to the center of the light source  20 A in the groove  14  is a position whether the groove  14  is equally divided into two in each of the first direction X and the second direction Y. There are four first straight lines L 1  and four second straight lines L 2 . 
     In the example illustrated in  FIG.  22 A , the second hole portions h 2  are disposed at positions intersecting the second straight line L 2 , and are not disposed on the first straight line L 1 . The second hole portion h 2  in the plan view has a V shape. The second hole portion h 2  is disposed so that the V-shaped vertex (bent portion) h 2   a  faces one side of the light source  20 A. With such a second hole portion h 2 , light emitted from one side of the light source  20 A is reflected and refracted by two lateral surfaces forming the V shape of the second hole portion h 2  and tends to travel toward the corner of the light-emitting unit  1 . Thus, it is possible to compensate for a decrease in luminance at a corner located at the farthest position from the center of the light source  20 A and to reduce uneven luminance on the light-emitting surface of the planar light source. 
     Further, the position of the center (V-shaped vertex h 2   a ) in the second direction Y of each of two second hole portions h 2  with the light source  20 A interposed therebetween in the first direction X is not located on the same straight line in the first direction X. The position of the center (V-shaped vertex h 2   a ) in the first direction X of each of two second hole portions h 2  with the light source  20 A interposed therebetween in the second direction Y is not located on the same straight line in the second direction Y. Therefore, in a planar light source in which a plurality of the light-emitting units  1  illustrated in  FIG.  22 A  are disposed in the first direction X and the second direction Y, it is possible to suppress a region ahead of the second hole portion h 2  on the optical path from the light source  20 A toward the groove  14  from becoming dark. As a result, luminance unevenness on the light-emitting surface of the planar light source can be reduced. 
       FIG.  22 B  illustrates an arrangement example in which four second hole portions h 2  disposed in one light-emitting unit  1  illustrated in  FIG.  22 A  are rotationally shifted around the center of the light-emitting unit  1 . Also in the example illustrated in  FIG.  22 B , light emitted from one side of the light source  20 A is reflected and refracted by two lateral surfaces forming the V shape of the second hole portion h 2  and tends to travel toward the corner of the light-emitting unit  1 . Moreover, the position of the center (V-shaped vertex h 2   a ) in the second direction Y of each of two second hole portions h 2  with the light source  20 A interposed therebetween in the first direction X is not located on the same straight line in the first direction X. The position of the center (V-shaped vertex h 2   a ) in the first direction X of each of two second hole portions h 2  with the light source  20 A interposed therebetween in the second direction Y is not located on the same straight line in the second direction Y. Thus, in a planar light source in which a plurality of the light-emitting units  1  illustrated in  FIG.  22 B  are disposed in the first direction X and the second direction Y, it is possible to suppress a region ahead of the second hole portion h 2  on the optical path from the light source  20 A toward the groove  14  from becoming dark, and to reduce luminance unevenness on the light-emitting surface of the planar light source. 
     In the example of  FIG.  22 B , as compared with the example of  FIG.  22 A , it is possible to reduce a portion where two second hole portions h 2  with the groove  14  interposed therebetween in the first direction X overlap in the second direction Y and a portion where two second hole portions h 2  with the groove  14  interposed therebetween in the second direction Y overlap in the first direction X. Thus, in the example illustrated in  FIG.  22 B , it is possible to further suppress a region ahead of the second hole portion h 2  on the optical path from the light source  20 A toward the groove  14  from becoming dark. 
     In the example illustrated in  FIG.  23 A , in the plan view, second hole portions h 2  each having a triangular shape are disposed in a region between the light source  20 A and the groove  14 . In the example illustrated in  FIG.  23 A  in which the second hole portion h 2  is not disposed on the first straight line L 1 , in a region between each of four grooves  14  surrounding one light-emitting unit  1  and the light source  20 A, two second hole portions h 2  are disposed close to each other so as to interpose the second straight line L 2  in the first direction X or the second direction Y. 
     In the two second hole portions h 2  close to each other with the second straight line L 2  interposed therebetween, a lateral surface (inner surface) on the side of the second hole portion h 2  facing the light source  20 A is parallel to one side of the light source  20 A. In these two second hole portions h 2 , a lateral surface (outer surface) on the side of the second hole portion h 2  facing the groove  14  is inclined with respect to the direction in which the groove  14  extends. Light from the light source  20 A passes through the inner surface of the second hole portion h 2 , enters into the second hole portion h 2 , is refracted by the outer surface of the second hole portion h 2 , and then tends to travel toward the corner direction. Thus, it is possible to compensate for a decrease in luminance at the corners and reduce uneven luminance on the light-emitting surface of the planar light source. 
     Also in the example illustrated in  FIG.  23 A , as in the example illustrated in  FIG.  19    described above, positions in the first direction X and the second direction Y of one second hole portion h 2  and the other second hole portion h 2  that are adjacent to each other with the groove  14  interposed therebetween can be shifted from each other. 
     In the example illustrated in  FIG.  23 B , second hole portions h 2  are disposed at positions intersecting the first straight line L 1 , and are not disposed on the second straight line L 2 . The shape of the second hole portion h 2  in the plan view is a plano-concave lens shape. The recessed surface of the second hole portion h 2  faces the light source  20 A, and the flat surface faces the corner of the light-emitting unit  1 . Light from the light source  20 A is focused toward the corner by the second hole portion h 2  having a concave lens shape. Thus, it is possible to compensate for a decrease in luminance at the corners and reduce uneven luminance on the light-emitting surface of the planar light source. 
     Also in the example illustrated in  FIG.  23 B , as in the example illustrated in  FIG.  20    described above, positions in the first direction X and the second direction Y of one second hole portion h 2  and the other second hole portion h 2  that are adjacent to each other with the groove  14  interposed therebetween can be shifted from each other. 
     Thirteenth Embodiment 
     The arrangement examples of second hole portions h 2  illustrated in  FIGS.  19  to  23 B  can be applied without distinction among the inner portion  1   a , the outer portion  1   b , and the outer portion  1   c . That is, the number of second hole portions h 2  disposed on one outer portion  1   b  and the number of second hole portions h 2  disposed on one outer portion  1   c  are not limited to being greater than the number of second hole portions h 2  disposed on one inner portion  1   a . Further, in the plan view, the area of the second hole portion h 2  disposed on the one outer portion  1   b  and the area of the second hole portion h 2  disposed on the one outer portion  1   c  are not limited to being greater than the area of the second hole portion h 2  disposed on the one inner portion  1   a . The number of second hole portions h 2  disposed on one outer portion  1   b  may be the same as or less than the number of second hole portions h 2  disposed on one inner portion  1   a . The number of second hole portions h 2  disposed on one outer portion  1   c  may be the same as or less than the number of second hole portions h 2  disposed on one inner portion  1   a . In the plan view, the area of the second hole portion h 2  disposed on the one outer portion  1   b  may be the same as or smaller than the area of the second hole portion h 2  disposed on the one inner portion  1   a . In the plan view, the area of the second hole portion h 2  disposed on one outer portion  1   c  may be the same as or smaller than the area of the second hole portion h 2  disposed on one inner portion  1   a.    
     Also in the thirteenth embodiment, similarly to the twelfth embodiment, positions in the first direction X and the second direction Y of one second hole portion h 2  and the other second hole portion h 2  that are adjacent to each other with the groove  14  interposed therebetween are shifted from each other, so that it is possible to suppress a region ahead of the second hole portion h 2  on the optical path from the light source  20 A toward the groove  14  from becoming dark, and to reduce luminance unevenness on the light-emitting surface of the planar light source. 
     The embodiments of the present invention have been described above with reference to specific examples. However, the present invention is not limited to these specific examples. All aspects that can be practiced by a person skilled in the art modifying the design as appropriate based on the above-described embodiments of the present invention are also included in the scope of the present invention, as long as they encompass the spirit of the present invention. In addition, in the spirit of the present invention, a person skilled in the art can conceive of various alteration examples and modification examples, and those alteration examples and modification examples will also fall within the scope of the present invention.