Patent Description:
Semiconductor light emitting diodes and laser diodes (collectively referred to herein as "LEDs") are among the most efficient light sources currently available. The emission spectrum of an LED typically exhibits a single narrow peak at a wavelength determined by the structure of the device and by the composition of the semiconductor materials from which it is constructed. By suitable choice of device structure and material system, LEDs may be designed to operate at ultraviolet, visible, or infrared wavelengths.

LEDs may be combined with one or more wavelength converting materials (generally referred to herein as "phosphors") that absorb light emitted by the LED and in response emit light of a longer wavelength. For such phosphor-converted LEDs ("pcLEDs"), the fraction of the light emitted by the LED that is absorbed by the phosphors depends on the amount of phosphor material in the optical path of the light emitted by the LED, for example on the concentration of phosphor material in a phosphor layer disposed on or around the LED and the thickness of the layer.

Phosphor-converted LEDs may be designed so that all of the light emitted by the LED is absorbed by one or more phosphors, in which case the emission from the pcLED is entirely from the phosphors. In such cases the phosphor may be selected, for example, to emit light in a narrow spectral region that is not efficiently generated directly by an LED.

Alternatively, pcLEDs may be designed so that only a portion of the light emitted by the LED is absorbed by the phosphors, in which case the emission from the pcLED is a mixture of light emitted by the LED and light emitted by the phosphors. By suitable choice of LED, phosphors, and phosphor composition, such a pcLED may be designed to emit, for example, white light having a desired color temperature and desired color-rendering properties.

Multiple LEDs can be formed together on a single substrate to form an array. Such arrays can be employed to form active illuminated displays, such as those employed in smartphones and smart watches, computer or video displays, or signage. An array having one or several or many individual devices per millimeter (e.g., device pitch of about a millimeter, a few hundred microns, or less than <NUM> microns, and spacing between adjacent devices less than <NUM> microns or only a few tens of microns or less) typically is referred to as a miniLED array or a microLED array (alternatively, a µLED array). Such miniLED arrays or microLED arrays can in many instances also include phosphor converters as described above; such arrays can be referred to as pc-miniLED arrays or pc-microLED arrays.

<CIT> discloses a light emitting device comprising a light emitting diode arranged on a submount, said device having a lateral circumference surface and a top surface, and an optically active coating layer. Said coating layer covering along at least a part of said circumference surface, extending from the submount to said top surface, and essentially not covering the top surface.

A light emitting device comprises a substrate, first and second phosphor converted LEDs, and a side reflector. Each of the first and second phosphor converted LEDs comprising a corresponding semiconductor LED, a corresponding wavelength converting structure, a light emitting external surface, and side walls. Each semiconductor LED is disposed on the substrate; each wavelength converting structure is disposed on a surface of the corresponding semiconductor LED opposite from the substrate. Each light emitting external surface is located opposite from the substrate, and the side walls extend from the substrate to the light emitting surface of each phosphor converted LED. The phosphor converted LEDs are spaced apart from each other by a street defined by the substrate and their corresponding side walls. The street is less than about <NUM> millimeters wide. The side reflector is disposed in the street on a side wall of the first phosphor converted LED and includes one or more pigments that absorb light in at least a portion of the spectrum of light emitted by the first phosphor converted LED. The street can be less than about <NUM> millimeters wide. The phosphor converted LEDs can be monolithically integrated together on the substrate, and can have transverse dimensions less than about <NUM> millimeters or less than about <NUM> millimeters.

Objects and advantages pertaining to LEDs, pcLEDs, miniLED arrays, pc-miniLED arrays, microLED arrays, and pc-microLED arrays may become apparent upon referring to the examples illustrated in the drawings and disclosed in the following written description or appended claims.

The examples depicted are shown only schematically; all features may not be shown in full detail or in proper proportion; for clarity certain features or structures may be exaggerated or diminished relative to others or omitted entirely; the drawings should not be regarded as being to scale unless explicitly indicated as being to scale. For example, individual LEDs may be exaggerated in their vertical dimensions or layer thicknesses relative to their lateral extent or relative to substrate or phosphor thicknesses. The examples shown should not be construed as limiting the scope of the present disclosure or appended claims.

The following detailed description should be read with reference to the drawings, in which identical reference numbers refer to like elements throughout the different figures. The drawings, which are not necessarily to scale, depict selective examples and are not intended to limit the scope of the invention. The detailed description illustrates inventive principles by way of example, not by way of limitation.

<FIG> shows an example of an individual pcLED <NUM> comprising a semiconductor diode structure <NUM> disposed on a substrate <NUM>, together considered herein an "LED" or "semiconductor LED", and a wavelength converting structure <NUM> (e.g., phosphor layer) disposed on the semiconductor LED. Semiconductor diode structure <NUM> typically comprises an active region disposed between n-type and p-type layers. Application of a suitable forward bias across the diode structure <NUM> results in emission of light from the active region. The wavelength of the emitted light is determined by the composition and structure of the active region.

The LED may be, for example, a III-Nitride LED that emits blue, violet, or ultraviolet light. LEDs formed from any other suitable material system and that emit any other suitable wavelength of light may also be used. Suitable material systems may include, for example, various III-Nitride materials, various III-Phosphide materials, various III-Arsenide materials, and various II-VI materials.

Any suitable phosphor materials may be used for or incorporated into the wavelength converting structure <NUM>, depending on the desired optical output from the pcLED.

<FIG> show, respectively, cross-sectional and top views of an array <NUM> of pcLEDs <NUM>, each including a phosphor pixel <NUM>, disposed on a substrate <NUM>. Such an array may include any suitable number of pcLEDs arranged in any suitable manner. In the illustrated examples the array is depicted as formed monolithically on a shared substrate, but alternatively an array of pcLEDs may be formed from separate individual pcLEDs. Substrate <NUM> may optionally include electrical traces or interconnects, or CMOS or other circuitry for driving the LED, and may be formed from any suitable materials.

Individual pcLEDs <NUM> may optionally incorporate or be arranged in combination with a lens or other optical element located adjacent to or disposed on the phosphor layer. Such an optical element, not shown in the figures, may be referred to as a "primary optical element". In addition, as shown in <FIG>, a pcLED array <NUM> (for example, mounted on an electronics board) may be arranged in combination with secondary optical elements such as waveguides, lenses, or both for use in an intended application. In <FIG>, light emitted by each pcLED <NUM> of the array <NUM> is collected by a corresponding waveguide <NUM> and directed to a projection lens <NUM>. Projection lens <NUM> may be a Fresnel lens, for example. This arrangement may be suitable for use, for example, in automobile headlights. In <FIG>, light emitted by pcLEDs of the array <NUM> is collected directly by projection lens <NUM> without use of intervening waveguides. This arrangement may particularly be suitable when pcLEDs can be spaced sufficiently close to each other, and may also be used in automobile headlights as well as in camera flash applications. A miniLED or microLED display application may use similar optical arrangements to those depicted in <FIG>, for example. Generally, any suitable arrangement of optical elements may be used in combination with the pcLEDs described herein, depending on the desired application.

Although <FIG> show a 3x3 array of nine pcLEDs, such arrays may include for example on the order of <NUM><NUM>, <NUM><NUM>, <NUM><NUM>, or more LEDs, e.g., as illustrated schematically in <FIG>. Individual LEDs <NUM> (i.e., pixels) may have widths w<NUM> (e.g., side lengths) in the plane of the array <NUM>, for example, less than about <NUM> millimeters, less than about <NUM> millimeters, less than about <NUM> millimeters, or less than about <NUM> millimeters. LEDs <NUM> in the array <NUM> may be spaced apart from each other by streets, lanes, or trenches <NUM> having a width w<NUM> in the plane of the array <NUM> of, for example, , less than about <NUM> millimeters, less than about <NUM> millimeters, less than about <NUM> millimeters, less than about <NUM> millimeters, or less than about <NUM> millimeters. The pixel pitch D<NUM> is the sum of w<NUM> and w<NUM>. Although the illustrated examples show rectangular pixels arranged in a symmetric matrix, the pixels and the array may have any suitable shape or arrangement, whether symmetric or asymmetric. Multiple separate arrays of LEDs can be combined in any suitable arrangement in any applicable format to form a larger combined array or display.

LEDs having dimensions w<NUM> in the plane of the array (e.g., side lengths) of less than or equal to about <NUM> millimeters microns are typically referred to as microLEDs, and an array of such microLEDs may be referred to as a microLED array. LEDs having dimensions w<NUM> in the plane of the array (e.g., side lengths) of between about <NUM> millimeters and about <NUM> millimeters are typically referred to as miniLEDs, and an array of such miniLEDs may be referred to as a miniLED array.

An array of LEDs, miniLEDs, or microLEDs, or portions of such an array, may be formed as a segmented monolithic structure in which individual LED pixels are electrically isolated from each other by trenches, grooves, or streets, or by suitably arranged insulating material (e.g., filling the trenches). <FIG> shows a perspective view of an example of such a segmented monolithic LED array <NUM>. Pixels in this array (i.e., individual semiconductor LED devices <NUM>) are separated by trenches <NUM> which are filled to form n-contacts <NUM>. The monolithic structure is grown or disposed on the substrate <NUM>. Each pixel includes a p-contact <NUM>, a p-GaN semiconductor layer 102b, an active region 102a, and an n-GaN semiconductor layer 102c; the layers 102a/102b/102c collectively form the semiconductor LED <NUM>. A wavelength converter material <NUM> may be deposited on the semiconductor layer 102c (or other applicable intervening layer). Passivation layers <NUM> may be formed within the trenches <NUM> to separate at least a portion of the n-contacts <NUM> from one or more layers of the semiconductor. The n-contacts <NUM>, other material within the trenches <NUM>, or material different from material within the trenches <NUM> may extend into the converter material <NUM> to form complete or partial optical isolation barriers <NUM> between the pixels.

<FIG> is a schematic cross-sectional view of a close packed array <NUM> of multi-colored, phosphor converted LEDs <NUM> on a monolithic die and substrate <NUM>. The side view shows GaN LEDs <NUM> attached to the substrate <NUM> through metal interconnects <NUM> (e.g., gold-gold interconnects or solder attached to copper micropillars) and metal interconnects <NUM>. Phosphor pixels <NUM> are positioned on or over corresponding GaN LED pixels <NUM>. The semiconductor LED pixels <NUM> or phosphor pixels <NUM> (often both) can be coated on their sides with a reflective mirror or diffusive scattering layer to form an optical isolation barrier <NUM>. In this example each phosphor pixel <NUM> is one of three different colors, e.g., red phosphor pixels 106R, green phosphor pixels <NUM>, and blue phosphor pixels 106B (still referred to generally or collectively as phosphor pixels <NUM>). Such an arrangement can enable use of the LED array <NUM> as a color display.

The individual LEDs (pixels) in an LED array may be individually addressable, may be addressable as part of a group or subset of the pixels in the array, or may not be addressable. Thus, light emitting pixel arrays are useful for any application requiring or benefiting from fine-grained intensity, spatial, and temporal control of light distribution. These applications may include, but are not limited to, precise special patterning of emitted light from pixel blocks or individual pixels, in some instances including the formation of images as a display device. Depending on the application, emitted light may be spectrally distinct, adaptive over time, and/or environmentally responsive. The light emitting pixel arrays may provide preprogrammed light distribution in various intensity, spatial, or temporal patterns. The emitted light may be based at least in part on received sensor data and may be used for optical wireless communications. Associated electronics and optics may be distinct at a pixel, pixel block, or device level.

<FIG> are examples of LED arrays <NUM> employed in display applications, wherein an LED display includes a multitude of display pixels. In some examples (e.g., as in <FIG>), each display pixel comprises a single semiconductor LED pixel <NUM> (not visible in <FIG>) and a corresponding phosphor pixel 106R, <NUM>, or 106B of a single color (red, green, or blue). Each display pixel only provides one of the three colors. In some examples (e.g., as in <FIG>), each display pixel includes multiple semiconductor LED pixels <NUM> (not visible in <FIG>) and multiple corresponding phosphor pixels <NUM> of multiple colors. In the example shown each display pixel includes a 3X3 array of semiconductor pixels <NUM>; three of those LED pixels have red phosphor pixels 106R, three have green phosphor pixels <NUM>, and three have blue phosphor pixels 106B. Each display pixel can therefore produce any desired color combination. In the example shown the spatial arrangement of the different colored phosphor pixels <NUM> differs among the display pixels; in some examples (not shown) each display pixel can have the same arrangement of the different colored phosphor pixels <NUM>.

As shown in <FIG>, a pcLED array <NUM> may be mounted on an electronics board <NUM> comprising a power and control module <NUM>, a sensor module <NUM>, and an LED attach region <NUM>. Power and control module <NUM> may receive power and control signals from external sources and signals from sensor module <NUM>, based on which power and control module <NUM> controls operation of the LEDs. Sensor module <NUM> may receive signals from any suitable sensors, for example from temperature or light sensors. Alternatively, pcLED array <NUM> may be mounted on a separate board (not shown) from the power and control module and the sensor module.

A highly reflective side coating is often used in top emitter LED applications to redirect the light coming out through the side walls of the LED to a wavelength converting structure positioned on the top surface of the die. If the areas of the side walls of the LED die are of significant size, for example around <NUM>% of photons generated by the die will go unconverted if there is no reflector coating located over the side wall areas. Such side coatings can be included in any of the examples shown, e.g., within trenches <NUM> or incorporated into barriers <NUM>.

One method for forming side wall reflectors is to apply a layer of light scattering particles mixed with a binder (e.g., silicone) onto the side walls, for example by dispensing or molding. Because reflection of light incident on such a reflector occurs through a series of reflection (scattering) or refraction events (often both), a long path length and correspondingly large thickness of the reflective layer perpendicular to the die often may be needed to provide sufficient reflection and extinction of excess light.

Conventional side coat materials include TiO<NUM> powder particles in liquid silicone, and SiO<NUM>/Al<NUM>O<NUM> fiber or Glass fiber/TiO<NUM>/silicone molding compounds. In some examples transmission of these materials is such that if the reflector layer surrounding the die/converter has a thickness < <NUM> microns, blue photons from the LED and converted light from the wavelength converter can penetrate though the reflector. Photons that penetrate through the reflector can then be scattered by or absorbed in neighboring pcLEDs, a process referred to as cross-talk. Photons leaking through the reflector can also cause color shift of the pcLED or over-converted red output, or can adversely affect contrast.

Some pcLED applications may require a thin side coat on the sides of the LED emitter (e.g., due to space constraints) and at the same time may be very sensitive to photons penetrating the thin side coat and causing color shift of and cross-talk between the pcLEDs of the array. This can be important for applications (automotive, flash, projection, display, etc.) where optical contrast is an important optical parameter. For example, if pcLEDs are arranged in an array with a narrow spacing (e.g., <<NUM> microns) between pcLEDs (e.g., as in a pc-miniLED array or a pc-microLED array), blue photons from the LEDs can in some instances penetrate through a thin TiO<NUM>/silicone layer between adjacent pcLEDs, causing cross-talk and color change in adjacent pixels of the pcLED array.

Inventive arrangements according to the present disclosure or claims are discussed with respect to the device shown in <FIG>, but are applicable to any pcLED array, pc-miniLED array, or pc-microLED array, including the other examples shown in the drawings. <FIG> shows a simplified schematic cross-sectional view of several adjacent individual pcLED pixels <NUM> on a shared substrate <NUM> in a pcLED array <NUM>. The pcLED array <NUM> may comprise many more such pcLED pixels arranged on a shared substrate <NUM>, but only a few are shown here for simplicity of presentation. Each pcLED pixel <NUM> comprises a semiconductor LED pixel <NUM> disposed on the substrate <NUM>, and a wavelength converting structure <NUM> (i.e., a phosphor pixel <NUM>) disposed on the LED pixel <NUM>. The pcLEDs <NUM> are spaced apart from each other by a street (i.e., a trench or gap; labelled trench <NUM> in <FIG> and <FIG>; filled with barrier material <NUM> but not separately labelled in <FIG>) having a width w<NUM> (e.g., as in <FIG>). The streets may have widths w<NUM> of <NUM> to <NUM> microns, for example, or any other suitable width, including those disclosed above. An optional off state white layer, not shown, may be disposed on the top light output surface of each wavelength converting structure <NUM>. Off-state white layers typically strongly scatter ambient light and consequently appear white when the pcLED is not operating, but become less scattering at the elevated temperatures resulting from pcLED operation.

Although in <FIG> the streets are shown as being defined by straight parallel pcLED side walls oriented perpendicularly to the substrate <NUM>, in other variations the LED side walls, the wavelength converter sidewalls, or both the LED side walls and the wavelength converter side walls may be angled with respect to the substrate <NUM>. The streets may therefore by narrower toward the top light emitting surface of the pcLEDs <NUM> than near the substrate <NUM>, or alternatively wider near the top light emitting surface of the pcLEDs <NUM> than near the substrate <NUM>.

The array of pcLED pixels <NUM> may be formed using any suitable methods. The streets between pixels may be formed for example by photoresist patterning, mechanical sawing, or laser patterning. The wavelength converting structures <NUM> may be formed directly on the LEDs <NUM>, or an array of wavelength converters <NUM> may be separately formed and then attached to an array of LEDs <NUM> to form the array <NUM> of pcLED pixels <NUM>.

Each LED <NUM> comprises an active region disposed between n-type and p-type layers (e.g., layers 102a/102b/102c of <FIG>). Application of a suitable forward bias across the diode structure results in emission of light from the active region. The LEDs may be, for example III-Nitride LEDs that emit blue, violet, or ultraviolet light. LEDs formed from any other suitable material system and that emit any other suitable wavelength of light may also be used. Other suitable material systems may include, e.g. III-Phosphide materials, III-Arsenide materials, and II-VI materials, as noted above.

Wavelength converting structures <NUM> may comprise, for example, phosphor particles dispersed in a binder. Suitable binders may include silicones and solgels, for example. Alternatively, wavelength converting structures <NUM> may comprise ceramic phosphor structures, formed for example by sintering phosphor particles. Each wavelength converting structure <NUM> may comprise phosphors of only a single composition, or phosphors of two or more different compositions. Each pcLED <NUM> of the array <NUM> can have the same one or more phosphor materials are the other pcLEDs <NUM> of the array <NUM>, or the one or more phosphor materials can differ among the pcLEDs <NUM> of the array <NUM>. Phosphors in wavelength converting structure <NUM> may, for example, convert blue light to red, yellow, green, or cyan light. Any suitable phosphor materials may be used, depending on the desired optical output from the pcLEDs <NUM> of the array <NUM>.

Reflective side coats <NUM> are disposed on the sides of the pcLEDs, in the streets between adjacent pcLEDs <NUM>. Reflective side coats <NUM> may fill the streets as shown in <FIG>. Alternatively adjacent pcLEDs <NUM> may each have a side coat <NUM> in the street between the pixels, without completely filling the street (not shown). Such side coatings serve to at least partly isolate adjacent pcLEDs from one another, i.e., to reduce or prevent leakage of light emitted from a first pcLED into a second, adjacent pcLED, there to be scattered as part of the second pcLED's output or to be absorbed and cause unwanted emission that then forms part of the second pcLED's output. Such leakage or crosstalk is undesirable in applications wherein high contrast between adjacent pcLEDs is needed (e.g., for a pcLED array used as a display device). Such leakage or crosstalk can also alter the color profile or color point of pcLEDs of the array in uncontrolled or undesirable ways. Conventional side reflectors often include scattering particles, scattering voids, or reflective particles that redirect at least some of the light back toward the emitting pcLED and reduce or prevent propagation into an adjacent pcLED.

Side reflector coating materials disclosed herein for use in side reflectors for pcLEDs comprise pigments that are photochemically stable under illumination by light from the pcLED. The pigments absorb light emitted by the pcLED. By pigments is meant material that absorbs light and does not in response emit light of a longer wavelength. Pigments therefore differ from phosphors. In the invention, the pigments absorb blue and green light and reflect red light, or absorb red light and reflect green light, or reflect blue light and absorb green light, or red light, or both. The side coating materials may comprise light scattering voids or light scattering particles (e.g., TiO<NUM> particles) dispersed in a transparent binder material (e.g., a silicone or a solgel) in which the pigments are also dispersed. The side coating material may optionally also comprise phosphor particles. The pigments may be inorganic or organic pigments.

Small concentrations of pigments in such side coating materials can help to decrease light leakage through the side walls and also help to tailor the color point of the pcLED. For thin-film flip-chip LEDs lacking a sapphire substrate the advantages of these pigments may be more substantial.

Side coatings and side coating materials as disclosed herein may be employed, for example, with pcLED arrays used in automotive, flash, illumination, and display applications. Side coatings including pigments can be advantageously employed in pcLED arrays wherein spacing between adjacent pcLEDs of the array might not provide sufficient light propagation pathlength to result in sufficient isolation. Such situations can arise in, e.g., pc-miniLED arrays or pc-microLED arrays as described above, wherein spacing between adjacent pcLEDs typically is less than about <NUM> millimeters, less than about <NUM> millimeters, or even less. If reflective or scattering particles alone do not provide sufficient isolation between adjacent pcLEDs of the array, addition of one or more pigments as disclosed or claimed herein can in some examples increase isolation to acceptable levels.

As summarized above, reflective side coats <NUM> are formed from a material comprising pigments that are photochemically stable under illumination by light from the LED <NUM> and from the wavelength converting structure <NUM>. These pigments absorb light from the pcLED <NUM>, decreasing light leakage through the side walls. This allows effective isolation of adjacent pcLED pixels with much thinner reflective side walls than would be necessary without the pigments. Because the pigments can be chosen to selectively absorb only portions of the spectrum of light from the pcLED, they also may help tailor the color point of the pcLED.

Suitable inorganic green pigments (absorbing blue and red light) may include, for example, Co<NUM>TiO<NUM>, Zn<NUM>TiO<NUM>, Ni<NUM>TiO<NUM>, or (Co, Zn, Ni)<NUM>TiO<NUM>. Suitable inorganic red pigments (absorbing blue and green light) may include, for example, BiO<NUM>V (bismuth vanadate). Suitable inorganic blue pigments (absorbing green and red light) may include, for example, CoAl<NUM>O<NUM> or YlnMn-blue. Suitable organic blue and green pigments may include, for example, phtalocyanines. Suitable organic red pigments may include, for example, perylenes. Other suitable pigments can be employed.

Also as summarized above, the pigments may be dispersed with light scattering particles in a binder, and optionally with phosphor particles in the binder as well. An advantage of including phosphor particles is that when adjacent pcLED pixels are outputting light there would be less of a dark gap between the operating pixels, without use of external optics to blur the resolution. The phosphor particles in the reflective side coat may, for example, convert blue light from the LED to red, yellow, green, or cyan light.

The side coating material may be applied to the pcLED array <NUM> to fill the streets by, for example, a dispensing, spraying, or molding process. Excess side coat material, for example disposed on the light output top surface of a wavelength converting structure or on the light output top surface of an off-state white layer disposed on the wavelength converting structure, can be removed by mechanical abrasion, planarization, polishing or grinding, for example.

After deposition, the reflective side coat <NUM> may comprise, for example, TiO<NUM> light scattering particles, air voids, inorganic or organic pigments, and optionally phosphor particles, all dispersed homogeneously in a silicone or solgel binder matrix. The air voids may act as light scatterers, and may also reduce the refractive index of the binder matrix. In this variation the difference between the refractive index of the phosphor particles and the surrounding matrix is typically homogeneous throughout the reflector.

Alternatively, the reflective side coat may comprise two or more layers oriented parallel to the sides of the pcLEDs <NUM>. A first layer, disposed on the side of the pcLED, may comprise light scattering particles (and optionally air voids) dispersed in a transparent silicon or solgel matrix. A second layer, disposed on the first layer and spaced apart from the pcLED by the first layer, may comprise pigments dispersed in a transparent silicon or solgel matrix. The separate layers may comprise different binder matrices. Such a layered structure maximizes the light scattering/reflecting effect of the first (e.g., TiO<NUM>) layer while maintaining the absorption/light extinguishing effect of the pigment containing layer.

The layered structure can be made by sequential application of the first layer with a thickness less than the street width, followed by application of the second layer. The layering can also be performed by first filling the street with side coat material for the first layer, then sawing or etching a smaller street within the first layer, then filling the new street with the material for the second layer.

The resulting layered reflective side coat structure between two adjacent pcLED pixels may comprise, for example, a first light scattering particle layer disposed on the side wall of one of the pcLED pixels, a second light scattering particle layer disposed on the side wall of the other of the adjacent pcLED pixels, and one or more pigment layers disposed between the first and second light scattering layers. Reflective side coat <NUM> may comprise additional layers between the two adjacent pcLED pixels <NUM>, as suitable. In such a layered structure, phosphor particles may optionally be dispersed in the light scattering particle layer, in the pigment layer, or in both the light scattering layer and the pigment layer.

In a layered side coat reflective structure as just described, the difference between the refractive index of the phosphor particles and the surrounding matrix may vary with distance from the pcLED side wall (e.g., have a gradient) because the matrix is layered rather than homogeneous and the matrix index of refraction may be different in different layers. Depending on the layer structure, the refractive index may for example vary gradually, or more strongly as for example a step function.

<FIG> show, respectively, reflection and transmission spectra of side coat material samples comprising different concentrations (wgt% ranging from <NUM>% to <NUM>%) of approximately <NUM> to <NUM> micron diameter particles of blue absorbing pigment Fe<NUM>O<NUM> uniformly dispersed in a TiO<NUM>/ silicone mixture.

Claim 1:
A light emitting device comprising:
a substrate (<NUM>);
a first phosphor converted LED comprising a first semiconductor LED (<NUM>) disposed on the substrate (<NUM>), a first wavelength converting structure (<NUM>) disposed on a surface of the first semiconductor LED (<NUM>) opposite from the substrate (<NUM>), a light emitting external surface located opposite from the substrate (<NUM>), and side walls extending from the substrate (<NUM>) to the light emitting surface;
a second phosphor converted LED comprising a second semiconductor LED (<NUM>) disposed on the substrate (<NUM>), a second wavelength converting structure (<NUM>) disposed on a surface of the second semiconductor LED opposite from the substrate (<NUM>), a light emitting external surface opposite from the substrate (<NUM>), and side walls extending from the substrate (<NUM>) to the light emitting surface, the second phosphor converted LED being spaced apart from the first phosphor converted LED by a street (<NUM>) defined by the substrate (<NUM>), a side wall of the first phosphor converted LED, and an adjacent side wall of the second phosphor converted LED; wherein the first phosphor converted LED emits blue light, green light or red light;
characterized by
the street (<NUM>) being less than <NUM> millimeters wide;
a side reflector (<NUM>) disposed in the street (<NUM>) on a side wall of the first phosphor converted LED and including one or more pigments that absorb light in at least a portion of the spectrum of light emitted by the first phosphor converted LED; and
wherein one or more of the pigments (i) absorb green and blue light and reflect red light, (ii) absorb red light and reflect green light, or (iii) reflect blue light and absorb green light, red light, or both.