Patent Publication Number: US-2023154967-A1

Title: Monolithic rgb micro led display

Description:
FIELD OF THE INVENTION 
     The invention relates to an array of micro light emitting diodes (LEDs) and a method for forming an array of LEDs. In particular, but not exclusively, the invention relates to a multicolour monolithic array of light emitting diodes using down converting organic semiconductors and a method for forming a multicolour monolithic array of light emitting diodes using down converting organic semiconductors. 
     BACKGROUND OF THE INVENTION 
     It is known that light emitting diode (LED) devices provide efficient sources of light for a wide range of applications. Increases in LED light generation efficiency and extraction, along with the production of smaller LEDs (with smaller light emitting surface areas) and the integration of different wavelength LED emitters into arrays, has resulted in the provision of high quality colour arrays with multiple applications, in particular in display technologies. 
     In order to provide high resolution LED arrays, such as micro LED arrays, the light emitting surface area defining the pixel surface is reduced compared with the light emitting surface of conventional LEDs, as is the pixel pitch. However, as the pixel pitch in such arrays is reduced to very small pitches (e.g., less than 5 μm) in order to provide higher resolution arrays, a number of difficulties arise. For example, quantum dots (QDs) are typically used as colour conversion layers to achieve a full colour red green blue (RGB) display, where blue LEDs are typically used as the source of input light. Such QDs are typically used to convert blue input light to red light and green light using appropriate QDs. However, such QD layers are generally required to be of the order of 20 μm to 30 μm thick in order to achieve full colour saturation. Therefore, at these thicknesses, the minimum pixel that can be produced is restricted to a width of above 20 μm. 
     Further difficulties are known to arise in processing QDs for light wavelength colour conversion in micro LED arrays, such as degradation in efficiency and lifetime of the wavelength converting QDs when forming layers of material comprising QDs using photolithography and inkjet printing, for example. Accordingly, there are significant challenges in the pursuit of high resolution micro LED arrays, for which it would be beneficial to have a pixel pitch is less than 10 μm. 
     SUMMARY OF THE INVENTION 
     In order to mitigate for at least some of the above described problems, there is provided a light emitting diode array comprising a plurality of light emitting pixels and a method of forming a light emitting diode array comprising a plurality of light emitting pixels in accordance with the appended claims. 
     In an example, there is provided method of forming a light emitting diode array comprising a plurality of light emitting pixels, wherein at least one of the light emitting pixels comprises: a light emitting diode configured to emit light of a first primary peak wavelength; and organic semiconductors dispersed in a medium, wherein the organic semiconductors are configured to receive and convert input light of the first primary peak wavelength from the light emitting diode to provide output light of a second primary peak wavelength. 
     There is also provided a light emitting diode array comprising a plurality of light emitting pixels, wherein at least one of the light emitting pixels comprises: a light emitting diode configured to emit light of a first primary peak wavelength; and organic semiconductor dispersed in a medium, wherein the organic semiconductors are configured to receive and convert input light of the first primary peak wavelength from the light emitting diode to provide output light of a second primary peak wavelength. 
     Advantageously, the combination of a light emitting diode array with organic semiconductors dispersed in a medium means that a desired colour of light is provided that is different from the colour of light produced by the light emitting diode array. Beneficially, the use of organic semiconductors dispersed in a medium means that very thin films, typically of the order of 1 μm to 2 μm are used to convert the primary peak wavelength of light from a first wavelength to a second wavelength in an efficient manner. This means that very thin films of colour converting organic semiconductors dispersed in a medium are used for high efficiency colour conversion with reduced absorption compared to known methods. Further, the efficiency of absorption and subsequent emission of light from organic semiconductors means that there is no requirement for an additional blue light blocking filter, which may otherwise be required where highly efficient blue light emitting LEDs are used to provide an optical pump source for colour conversion layers and where the blue light is not fully absorbed. Accordingly, the combination of organic semiconductors with a light emitting diode array provides excellent colour saturation performance. 
     Preferably, at least one further light emitting pixel comprises: a further light emitting diode configured to emit light of the first primary peak wavelength; and further organic semiconductors dispersed in a further medium, wherein the further organic semiconductors are configured to receive and convert input light of the first primary peak wavelength from the further light emitting diode to output light of a third primary peak wavelength. 
     Advantageously, the ability to control the absorption and emission properties of organic semiconductors means that the light emitting pixels with different wavelengths of light emission are provided using a light emitting diode array that uses light emitting diodes that emit the same wavelength of light (such as blue LEDs pumping both green and red colour conversion layers and producing RGB emission when combined with blue emission from the LEDs in the light emitting diode array). 
     Preferably, the method comprises depositing the medium and/or the further medium on a light emitting diode array, preferably wherein depositing the medium and/or further medium comprises slit coating or spin coating the medium and/or further medium. 
     Advantageously, the organic semiconductors are tunable for full dissolution in different media. This means that they are deposited using techniques such as slit coating or spin coating and are therefore not subject to photolithographical methods or inkjet printing, which are known to result in degradation for quantum dots that are dispersed in photo definable material, for example. 
     Preferably, the method comprises selectively covering one or more light emitting diodes in the light emitting diode array with a material prior to depositing the medium and/or the further medium, thereby to enable selective deposition of the medium and/or further medium. 
     Advantageously, an efficient method for the self-alignment of organic semiconductor material is provided, which enables the formation of light emitting pixels that emit light of different wavelengths based on the same wavelength of input light provided by the array of light emitting diodes. 
     Preferably, the material is at least one of: a temporary material that is removable thereby to enable further deposition of the medium and/or the further medium on the selectively covered one or more light emitting diodes in a further distinct step after deposition of the medium and/or further medium on the light emitting diode array; and an optically transparent material that enables light emission from the selectively covered one or more light emitting diodes, wherein the one or more light emitting diodes are configured to emit light with the primary peak wavelength. 
     Advantageously, the use of temporary material enables sequential deposition steps for the deposition of different media comprising organic semiconductors and hence the formation of different colour light emitting pixels associated with an array of light emitting diodes. 
     Preferably, the medium and/or further medium comprises at least one of: a resin, an epoxy and a polymer. 
     Advantageously, the organic semiconductors are tunable for full dissolution in the different types of media, enabling a range of processing techniques to be employed in the formation of multicolour LED arrays. 
     Preferably, the method comprises patterning an insulating layer on a light emitting diode array, thereby to define a perimeter of a light emitting surface of at least one light emitting pixel. 
     Advantageously, the insulating layer separates regions associated with light emitting surfaces of light emitting diodes, in which light converting organic semiconductors are deposited. Beneficially, the insulating layer prevents the medium comprising organic semiconductors from spreading from one light emitting surface associated with one light emitting diode device to another light emitting surface associated with another light emitting diode device. Accordingly, a self-aligning method is provided, where the organic semiconductors dispersed in the medium is straightforwardly selectively deposited to associate with light emitting diode devices to form light emitting surfaces that emit light at a down converted wavelength with respect to the primary peak wavelength of light emitted by the light emitting diode devices in the array of light emitting diode devices. 
     Preferably, the method comprises depositing a layer of insulating material on the light emitting diode array and selectively etching the insulating material to provide the patterned insulating layer. 
     Advantageously, selective etching if a layer of insulating material provides a controllable and efficient mechanism to fence areas associated with light emitting surfaces of light emitting diode devices, such that colour conversion material is enabled selectively to self-align within the fenced areas, thereby forming light emitting surfaces of light emitting pixels that provide light emission at controllable wavelengths. 
     Preferably, the method comprises depositing a conformal reflective layer on the patterned insulating layer and etching the conformal reflective layer thereby to provide a light emitting surface associated with the light emitting diode of the at least one of the plurality of light emitting pixels. Preferably, the method comprises depositing the medium and/or the further medium on the light emitting diode array after etching the conformal reflective layer. 
     Advantageously, the reflective layer provides optical isolation for the colour conversion material provided by the organic semiconductors dispersed in the medium, as the reflective material is formed on the insulating layer that defines the perimeter of light emitting pixels. 
     Preferably, the method comprises curing the medium and/or the further medium and planarising a surface of the light emitting diode array. 
     Advantageously, planarization removes unwanted material, enabling access to layers that were previously covered, whilst providing a relatively flat and smooth surface for subsequent processing steps. 
     Preferably, the method comprises forming a passivation layer on the light emitting diode array, thereby to protect the medium and/or the further medium. 
     Advantageously, the passivation layer protects multiple light emitting pixels associated with the array of light emitting diode devices in a single protective step. 
     Preferably, the organic semiconductors and/or the further organic semiconductors comprise conjugated organic semiconductors having a plurality of conjugated structures, preferably wherein the organic semiconductors and/or further organic semiconductors are formed from organic semiconductor material, more preferably wherein the plurality of conjugated structures comprises a core and an arm, yet more preferably wherein at least two of the plurality of conjugated structures have a different functional property. 
     Advantageously, organic semiconductors, such as down converting organic semiconductors, have the ability to tune the molecular structure to achieve targeted physical properties. The organic semiconductors can achieve specific values for the ionization potential or electron affinity, absorption and emission characteristics, charge transport properties, phase behavior, solubility, and processability. Specific to the requirements of a monolithic RGB micro LED display the ability to make subtle structural changes to the organic semiconductor allows full control over the display performance. 
     Preferably, one functional property is absorption at the first primary peak wavelength and wherein one functional property is emission of absorbed light at the second primary peak wavelength. 
     Advantageously, organic semiconductors absorb input light with a first primary peak wavelength from light emitting diodes in the light emitting diode array and emit light at a determined second primary peak wavelength that is different to the first primary peak wavelength. Accordingly, RGB arrays (and other multicolour arrays) of light emitting pixels are enabled. 
     Preferably, the light emitting diode array is a high resolution monolithic micro LED array, preferably wherein the method comprises forming a reflective layer between at least two of the light emitting diodes in the high resolution monolithic micro LED array, more preferably wherein the high resolution monolithic LED has a pixel pitch less than 10 μm, preferably less than 4 μm. Preferably, the plurality of light emitting pixels each have a light emitting surface that is less than or equal to 100 μm 2 , preferably less than 16 μm 2 . 
     Advantageously, high resolution arrays are provided by the combination of organic semiconductors and monolithic LED arrays, where pixel size is reduced compared with known techniques. Reduced pixel size in combination with reduced pixel pitch is enabled without using photolithographical or inkjet printing techniques that may otherwise cause the colour conversion material to degrade. 
     Further aspects of the invention will be apparent from the description and the appended claims. 
    
    
     
       DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION 
       A detailed description of embodiments of the invention is described, by way of example only, with reference to the figures, in which: 
         FIG.  1 A  shows a cross-sectional view of a monolithic LED array; 
         FIG.  1 B  shows a cross-sectional view of a processed version of the monolithic LED array of  FIG.  1 A ; 
         FIG.  1 C  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  1 B ; 
         FIG.  1 D  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  1 C ; 
         FIG.  1 E  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  1 D ; 
         FIG.  1 F  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  1 E ; 
         FIG.  2 A  shows a cross-sectional view of multicolour LED array; 
         FIG.  2 B  shows a plan view of the multicolour LED array of  FIG.  2 A ; 
         FIG.  3    shows a cross-sectional view of a multicolour LED array; 
         FIG.  4 A  shows a cross-sectional view of a processed version of the monolithic LED array of  FIG.  1 D ; 
         FIG.  4 B  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 A ; 
         FIG.  4 C  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 B ; 
         FIG.  4 D  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 C ; 
         FIG.  4 E  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 D ; 
         FIG.  4 E  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 E ; 
         FIG.  4 F  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 F ; and 
         FIG.  4 G  shows a cross-sectional view of a further processed version of the monolithic LED array of  FIG.  4 G . 
     
    
    
     In order to address deficiencies in the prior art, an array of light emitting diodes comprising a plurality of light emitting pixels and a method of forming an array of light emitting diodes comprising a plurality of light emitting pixels is described with reference to  FIGS.  1  to  4   . It is described how down converting organic semiconductors are dispersed in a medium thereby to enable improved processing of colour converting materials in conjunction with monolithic LED arrays, thereby to facilitate the provision of high resolution monolithic LED arrays having light emitting pixels that have smaller light emitting surfaces and that are closer together than conventional techniques allow. Advantageously, the methods described enable such high resolution monolithic LED arrays having a plurality of light emitting pixels to be created without using lithographical or inkjet patterning processes to form colour conversion regions associated with light emitting diodes in the light emitting diode array, and are therefore not subject to the deleterious effects of such lithographical and inkjet patterning processing, as seen in conventional techniques for forming colour conversion regions using quantum dots. 
     A method for forming a monochrome monolithic LED array comprising a plurality of light emitting pixels is described with reference to  FIG.  1 A to  1 F , where the primary peak wavelength emitted by the light emitting pixels is different to the primary peak wavelength emitted by the LEDs in the array.  FIG.  1 A  shows a cross-sectional view  100 A of a section of a monolithic LED array. Whilst reference is made to cross-sectional views and layers as seen in cross-section, the skilled person understands that the layers extend laterally in a three-dimensional array to provide planar layers suitable for functional displays, for example. 
     There are shown three LED structures  104  that form part of a monolithic LED array. However, in further examples the array is not limited in the number of LED structures  104 . 
     The LED structures  104  are nitride-based epitaxially grown compound crystalline semiconductor LEDs. In further examples, other LEDs are used, such as other group III-V, or group II-VI based materials. Advantageously, the LED structures  104  are grown monolithically, thereby to provide high quality material with excellent uniformity and efficiency, without a requirement to transfer individual LED devices. Beneficially, the monolithic LED array is coupled to a backplane in order to enable control of individual LED structures  104  in the monolithic array. The LED structures  104  are grown as part of a monolithic array of LEDs using metal organic chemical vapour deposition (MOCVD). In further examples, alternative and/or additional techniques are used to form the LED structures  104  as part of a monolithic array, such as molecular beam epitaxy (MBE) and other suitable deposition/growth techniques. In further examples, other additional and/or alternative semiconductor fabrication and processing techniques are used to provide the monolithic array of LED structures  104 . 
     The LED structures  104  are formed on a region of gallium nitride (GaN)  102  and are shown to be embedded in the GaN  102  region. In further examples, additionally or alternatively, LED structures  104  are formed on a different material and are positioned to be proud of a top surface of a monolithic light emitting diode array such that the surface of the monolithic LED array has topological variations. In further examples, the region of GaN  102  is coupled to a complementary metal oxide semiconductor (CMOS) backplane such that the individual LED structures  104  of the monolithic array are independently addressable, thereby to control light emission from the array. The individual electrical connections to the LED structures  104  are not shown and the skilled person understands that such electrical connections are implementable in a variety of ways. 
     A metallic layer  106  is formed around the perimeter of the LED structures  104  in the monolithic array thereby to provide optical isolation and to prevent optical cross talk between LED structures  104 . In further examples, alternatively or additionally, the metallic layer  106  is not used. In further examples, alternative or additional layers are used between LED structures  104  in the monolithic array in order to provide isolation of LED structures  104 , including optical isolation of LED structures  104 . 
     Once an array of monolithic LED structures  104  has been provided, an insulating layer  108  is patterned on the surface of the array, as shown in the cross-sectional view  100 B of  FIG.  1 B . The insulating layer  108  is patterned such that the light emitting surface of each pixel, defined by the light emitting surfaces of the LED structures  104 , is exposed. The insulating layer  108  is patterned by forming a layer of insulating material on the monolithic array of LED structures  104  and performing anisotropic etching of the insulating material, thereby to expose a light emitting surface associated with each light emitting diode structure  104 , whilst leaving a patterned insulating layer  108  provided around the perimeter of each of the LEDs, enabling a light emitting surface for each of the LED structures  104  to be defined and allowing for subsequent deposition of material to be confined to individually selected LED structures  104 . The insulating layer  108  is a silicon dioxide patterned layer. If further examples, alternatively or additionally, different insulating materials are used to form the patterned insulating layer  108 . 
     Once the insulating layer  108  has been formed on the monolithic array of LED structures  104 , as described with reference to  FIG.  1 B , a conformal reflective layer is deposited onto the surface of the array. The reflective layer  110  is an aluminium layer. In further examples, alternatively or additionally, different reflective layers used, such as different metallic reflective layers or other reflective material layers. In further examples the reflective layer  110  is omitted. Once the conformal reflective layer  110  has been deposited as shown at  FIG.  1 C , the process moves to  FIG.  1 D . Whilst the conformal reflective layer  110  is shown in a cross-sectional view  100 C, the skilled person understands that the conformal layer extends laterally across the surface of the array of LED structures  104 , as required. 
     At  FIG.  1 D  there is shown a cross-sectional view  100 D of a monolithic array of LED structures  104  where an anisotropic etch has been performed thereby to leave metallic reflective layers  110  on the sidewalls of the insulating layer  108  that was patterned onto the surface of the array and not on the light emitting surface associated with individual LED structures  104 . The anisotropic etch selectively exposes light emitting surfaces associated with individual LED structures  104  in the array of LED structures  104 . Beneficially, the metallic reflective layers  110  on the sidewalls of the insulating layer  108  provides for optical definition of light emitting surfaces of light emitting pixels and thus better contrast between pixels. The process then moves on to provide the structure shown in  FIG.  1 E . 
     At  FIG.  1 E  there is shown a cross-sectional view  100 E of the array described with reference to  FIG.  1 D  with a organic semiconductor based layer deposited onto the array. It is known that down converting organic semiconductors can be tuned in order to achieve targeted physical properties. In particular, advantageously, organic semiconductors can achieve specific values for the ionisation potential or electronic affinity, absorption and emission characteristics, charged transport properties, phase behaviour, solubility, and processability. Typically, organic semiconductors are conjugated organic semiconductors comprising a plurality of conjugated structures. In an example, such conjugated structures include a core and arm. The functionality of these constituent parts of the macro molecule are tuned in order to provide particular characteristics. 
     Macromolecules are discussed in  Acc. Chem. Res  2019, 52, 1665 to 1674 and  J. Mater. Chem. C,  2016, 4, 11499, for example. Macromolecules that are tunable include conjugated organic semiconductor comprising a plurality of conjugated structures. These are typically organic semiconductors. The plurality of conjugated structures can be formed to have a different functional properties, for example, different absorption and/or emission characteristics associated with each of the different conjugated structures. 
     Advantageously, such organic semiconductor can efficiently absorb light at one wavelength and convert it to a different wavelength that is emitted, even using a thin layer of organic semiconductors. An elegant and advantageous technique for processing such organic semiconductors dispersed in a medium is demonstrated below with respect to  FIGS.  1  to  4   . Beneficially, the method does not rely on lithography or inkjet patterning processes that are known to otherwise degrade the colour conversion material in conventional colour converting materials, such as quantum dots. Advantageously, a self-aligning method is described that nevertheless enables the creation of small features suitable for micro LED arrays without a need to use lithographical or inkjet patterning processes to form colour converting regions. 
     The organic semiconductor material  112  comprises colour converting organic semiconductors dispersed in a medium. Advantageously, the ability to tune the organic semiconductor enables the colour gamut of the final display to be readily controlled. The organic semiconductor material  112  absorbs light from the LED structures  104  and emits light at a different, down converted wavelength. The primary peak wavelength of light from the LED structures  104  is longer that the primary peak wavelength of light emitted from the colour converting organic semiconductor material  112 . The light emitted from the LED structures  104  has a primary peak wavelength that is blue (approximately 450 nm). In further examples, the light emitted from the LED structures  104  has a different primary peak wavelength of light. The organic semiconductor material  112  is configured to absorb light and emit light with a primary peak wavelength that corresponds to green light (approximately 550 nm). Additionally, or alternatively, in further examples, the organic semiconductor material  112  is configured to emit light with a primary peak wavelength that corresponds to red light (approximately 650 nm). Additionally or alternatively, in further examples, the organic semiconductor material  112  comprises organic semiconductors that are configured to emit light at multiple wavelengths. Advantageously, the ability to tune the organic semiconductor allows the option for multiple colour multiple emission from a single pixel aiding the final display colour gamut. Additionally or alternatively, in further examples the organic semiconductor material  112  comprises different organic semiconductors that emit light at different wavelengths of light from each other, in response to absorbing light from the LED structures  104 . 
     The organic semiconductor material  112  is deposited on the monolithic array of LED structures  104  by slit coating deposition techniques. In further examples, alternative or additional techniques are used in order to deposit the organic semiconductor material  112  on the monolithic array of LED structures  104 . For example, spin coating is used in a further example. The medium in which the organic semiconductor is dispersed is a resin. In further examples, alternative or additional media are used such as epoxy material or polymer material. The organic semiconductors are dispersed in the medium to form the organic semiconductor material  112  prior to deposition on the surface of the array. The medium comprising the organic semiconductors is deposited on the LED structures  104  in between the insulating layer  108 . 
     Once the organic semiconductor material  112  has been deposited the surface of the array is planarised. Such planarisation is performed using an anisotropic etch back process. This is shown at  FIG.  1 F . At  FIG.  1 F  there is shown a cross-sectional view  100 F of the processed micro LED array shown at  FIG.  1 E . Advantageously, a planarised structure is provided, where the organic semiconductor material  112  defining pixels associated with each LED structure  104  are isolated laterally by an insulating layer  108  defining the perimeter of the pixels, as well as the reflective layer  110 , such that the pixels are optically isolated from one another. 
     The micro LED array has LED structures  104  that provide source input light to the colour conversion regions provided by the organic semiconductor material  112  that define different pixels in the array. Whilst planarisation is performed using an anisotropic etch back process, in further examples, additionally or alternatively, chemical mechanical polishing is used to planarise the structure. 
     Whilst the colour conversion layer provided by the organic semiconductor material  112  is shown to convert light from the LED structures  104  to a different wavelength of light. The skilled person understands that in further examples different pixels have different organic semiconductor materials  112  deposited in them thereby to provide different colour pixels. An example of this is described with respect to  FIG.  2   , which shows a view  200  multicolour monolithic LED array. 
       FIG.  2 A  shows a cross-sectional view  200  of a multicolour monolithic LED array showing three light emitting pixels  216   a,    216   b,    216   c.  There is shown a complementary metal oxide semiconductor (CMOS) backplane  202 , upon which there is provided an array of micro LEDs  204   a,    204   b,    204   c.  The CMOS backplane  202  is configured to work with the micro LEDs in order selectively to control light emission from the array of micro LEDs. There are three micro LEDs  204   a,    204   b,    204   c  shown in  FIG.  2 A . The micro LEDs  204   a,    204   b,    204   c  are nitride based epitaxial crystalline semiconductor LEDs configured to emit light with a primary peak wavelength that is blue (approximately 450 nm). In order to provide a red-green-blue (RGB) display, the blue light emitted by the micro LED structures  204   a,    204   b,    204   c  is converted using colour conversion layers that are formed on the micro LEDs  204   a,    204   b,    204   c.    
     The view  200  of  FIG.  2 A  shows a first micro LED  204   a  that is configured to emit light with a primary peak wavelength that is blue (approximately 450 nm), upon which there is deposited a clear resin  212 . Upon the clear resin  212  there is deposited a passivation, protective layer  214 . The protective layer  214  is transparent to visible light and forms at least part of a light emitting surface associated with the micro LED  204   a.  The micro LED  204   a,  the clear resin  212  and the protective layer  214  form a first light emitting pixel  216   a.    
     There is also shown a second micro LED  204   b  that is configured to emit light with a primary peak wavelength that is blue (approximately 450 nm), upon which there is formed a colour conversion layer  208  that is configured to convert light from the micro LED structure  204   b  such that input light with a primary peak wavelength that is blue is converted to a primary wavelength that is red. Upon the colour conversion layer  208  there is a passivation, protective layer  214 . The protective layer  214  is transparent to visible light and forms at least part of a light emitting surface associated with the micro LED  204   b.  The micro LED  204   b,  the colour conversion layer  208  and the protective layer  214  form a second light emitting pixel  216   b.    
     There is also shown a third micro LED  204   c  that is configured to emit light with a primary peak wavelength that is blue (approximately 450 nm). Upon the third blue micro LED  204   c , there is provided a colour conversion layer  210  that is different to the colour conversion layer  208  associated with the second micro LED  204   b.  The colour conversion layer  210  is configured to receive input light from the third micro LED  204   c  and convert it from light that has a primary peak wavelength that is blue light to light that has a primary peak wavelength that is green. Upon the colour conversion layer  210  there is a passivation, protective layer  214 . The protective layer  214  is transparent to visible light and forms at least part of a light emitting surface associated with the micro LED  204   b.  The micro LED  204   a,  the colour conversion layer  210  and the protective layer  214  form a third light emitting pixel  216   c.    
     The blue light emitting micro LEDs  204   a,    204   b,    204   c  are epitaxially grown as a monolithic array of blue light emitting micro LEDs. In-between each of the light emitting pixels  216   a ,  216   b,    216   c,  formed by the combination of a micro LED with or without colour conversion layers, there is provided an infill  206 . The infill  206  that separates the light emitting pixels. In further examples, additional or alternative structures and/or layers are used to separate the micro LEDs  204   a,    204   b,    204   c  and/or the light emitting pixels  216   a,    216   b,    216   c.  Whilst the micro LEDs  204   a,    204   b,    204   c  are configured to emit blue light at the same wavelength, in further examples, alternative or additional LEDs are provided in the array, where the alternative or additional LEDS emit light at a different predetermined primary peak wavelength. For example, blue and green LEDs might form part of a monolithic array of LEDs and red colour conversion material is selectively deposited on some of the LEDs, for example some of the blue LEDs, thereby to provide a RGB display. 
       FIG.  2 B  shows a plan view  200 ′ of the array of light emitting pixels described with respect to  FIG.  2 A . Each LED pixel  216  has a light emitting surface (these are shown as square surfaces at  FIG.  2 B —in further examples the light emitting surfaces have different shapes and are in different configurations). The pixels  216  correspond to any of the combinations of micro LED  204   a,    204   b,    204   c  with colour conversion layers  208 ,  210  or resin  212  described with respect to  FIG.  2 A  and in  FIG.  2 B  there is shown blue green and red light emitting pixels  216   a,    216   b,    216   c  described with respect to  FIG.  2 A  amongst other light emitting pixels  216 . Whilst the light emitting pixels  216   a,    216   b,    216   c  of  FIG.  2 A  and  FIG.  2 B  are shown in a particular arrangement, in further examples, arrays of light emitting pixels comprise any appropriate number of light emitting pixels in any suitable arrangement and with any suitable light emitting surface associated with each of the light emitting pixels. 
     The light emitting pixels  216  have a light emitting surface corresponding to the plan view area of the pixels  216 . Whilst the pixels are shown to be square in plan view, in further examples, alternatively or additionally the pixel plan view shapes are different. For example, the pixels  216  may assume a hexagonal shape light emitting surfaces. 
       FIG.  3    demonstrates a further cross sectional view  300  of an implementation of organic semiconductors dispersed in media to provide colour conversion films with different pixels without the need for lithographical or inkjet printing techniques. Common elements are shown with respect to  FIG.  2 A . Additionally, a further micro LED  204   d  is shown. Upon this layer there is a thinner colour conversion layer  210  than that associated with micro LED  204   c,  along with a clear resin  212 . This enables white light to be produced at a pixel  216   d  as part of a red-green-blue-white array. This enables improved emission, even at low light conditions. 
     Whilst one LED  204   c  is shown at  FIG.  3    with an associated colour conversion layer  210  that is thicker than the colour conversion layer  210  associated with LED  204   d,  in further examples, alternatively or additionally, different thicknesses, sizes, shapes and combinations of colour conversion layers forming light emitting pixels surfaces are implemented at different pixels in order to provide light suitable for the application to which it is associated. 
       FIG.  4    illustrates a method of forming a multicolour high resolution micro LED array of light emitting pixels. The method enables the efficient formation of arrays of light emitting pixels that emit different primary peak wavelengths on a smaller scale than is achievable with quantum dot material and without processing the colour conversion material in a way that deleteriously affects its ability to convert light from one LED input colour to a different output colour. 
       FIG.  4 A  shows a processed monolithic array  400 A of LED structures  104  formed in the same manner as the structure provided with reference to  FIG.  1 D . However, instead of depositing a organic semiconductor material on the processed monolithic array of LEDs  104 , an optically clear resin  402  is formed to cover LED structures  104  in the array of LEDs that are not to be associated with a colour converting organic semiconductor material that is to be deposited. This is shown at the processed array  400 B of  FIG.  4 B . The optically clear resin  402  can be formed using photodefinable methods since it does not comprise organic semiconductors (which may otherwise be affected by the lithographical techniques involved for photodefinable methods). 
     Once selected LEDs have been covered with optically clear resin  402  as described with reference to  FIG.  4 B , the process moves to  FIG.  4 C . At  FIG.  4 C  there is shown processed array  400 C where a organic semiconductor material  404  that has been deposited on the processed monolithic array of LED structures  104 . The organic semiconductor material  404  is a medium comprising organic semiconductors that are configured to absorb light from the LED structures  104  and down convert it such that light is emitted with a wavelength that is shorter than the input light absorbed from the LED structures  104 , as describe with reference to  FIGS.  1 A to  1 F . The organic semiconductor material  404  is configured to absorb blue light and emit green light. Advantageously, the efficiency of the organic semiconductor layer means that a blue blocking filter is not required over the organic semiconductor layer. The organic semiconductor material  404  comprises organic semiconductors mixed with a medium prior to deposition using suitable processing techniques. The medium is a resin. In further examples, the medium is additionally, or alternatively, an epoxy or polymer. Once the organic semiconductor material  404  has been deposited, the structure is planarised using an anisotropic etch process. This is shown at  FIG.  4 D . 
     At  FIG.  4 D  there is shown the planarised structure  400 D that has removed the organic semiconductor material  404  to expose the optically clear resin  402  formed to selectively cover some of the LED structures  104 . Whilst the planarisation is performed using an anisotropic etch back process, in further examples, additionally or alternatively, a chemical mechanical polishing process is used to planarise the structure  400 D. Once the structure  400 D has been planarised, the optically clear resin  402  is selectively removed from covering LED structures  104  with which a different colour conversion organic semiconductor is to be associated. 
       FIG.  4 E  shows a structure  400 E that is the structure  400 D of  FIG.  4 D  with the optically clear resin  402  removed from covering one of the LED structures  104 . Once the optically clear resin  402  has been selectively removed, a further medium comprising further organic semiconductors is deposited on the array. 
       FIG.  4 F  shows a structure  400 F that is the structure  400 E of  FIG.  4 E  with an additional organic semiconductor material  406  deposited on the structure  400 E. The organic semiconductor material  406  is formed from a medium in which organic semiconductors are dispersed. The organic semiconductor material  404  is a medium comprising organic semiconductors that are configured to absorb light from the LED structures  104  and down convert it such that light is emitted with a wavelength that is shorter than the input light absorbed from the LED structures  104 . The organic semiconductors are configured to absorb blue light and emit red light. Advantageously, the efficiency of the organic semiconductor layer means that a blue blocking filter is not required over the organic semiconductor layer. The organic semiconductor material  404  comprises organic semiconductors mixed with a medium prior to deposition. The medium is a resin. In further examples, the medium is additionally, or alternatively, an epoxy or polymer. Once the organic semiconductor material  406  has been deposited, the structure is planarised using an anisotropic etch process. This is shown at  FIG.  4 G . 
     At  FIG.  4 G  there is shown the planarised structure  400 G that has removed the organic semiconductor material  406  to expose the optically clear resin formed to selectively cover some of the LEDs and the organic semiconductor material  404  associated with some of the LED structures  104 . Whilst the planarisation is performed using an anisotropic etch back process, in further examples, additionally or alternatively, a chemical mechanical polishing process is used to planarise the structure. Once the structure has been planarised, the structure  400 G of  FIG.  4 G  is covered with a passivation layer  408 . This is shown in the structure  400 H at  FIG.  4 H . The passivation layer  408  is formed using an atomic layer deposition technique. In further examples, the passivation layer  408  is formed using other appropriate techniques. 
     The resultant structure formed as described above is a monolithic array of LED structures  104  that are configured independently emit light with a primary peak wavelength. The light emitted by the LED structures  104  is absorbed at the corresponding organic semiconductor material  404 ,  406 , or passes through the optically clear resin  402 , such that light of three different colours is emitted. In further examples, alternatively or additionally, light emitting pixels are configured to emit light of further primary peak wavelengths. In yet further examples, multiple layers of different organic semiconductor materials are associated with individual LED structures  104  such that light with multiple wavelengths of light are emitted. In yet further examples, organic semiconductor materials are used that comprise different organic semiconductors with different functional properties. 
     Whilst a cross-sectional view of three light emitting pixels and their associated light emitting diodes is described with reference to  FIG.  4   , the skilled person understands that arrays of any number of such light emitting pixels can be produced using the methods described herein, thereby to provide high resolution monolithic arrays of light emitting pixels based on the association of organic semiconductor-containing media and high resolution monolithic light emitting diode arrays. 
     Advantageously, a self-aligned process flow for providing a high resolution array of micro LED pixels is provided. The process avoids the need for lithographic or inkjet patterning processes when depositing the organic semiconductor material, therefore avoiding any associated deleterious effects whilst also enabling small features to be provided. 
     Advantageously, conjugated organic semiconductors can achieve full colour saturation within very thin films, typically in the order of 1 μm-2 μm without the requirement of an additional blue blocking filter. Quantum dot films require thickness in excess of 20 μm to achieve similar colour saturation performance. Advantageously, the full colour saturation within a thin film allows the organic semiconductor to define pixels at a smaller pitch than traditional quantum dot films. The methods described herein provide for high resolution micro LED based arrays of light emitting pixels with light emitting surfaces less than or equal to 100 μm 2  and preferably less than or equal to 16 μm 2 . Moreover, the method described herein provide for high resolution micro LED based arrays of light emitting pixels wherein the high resolution monolithic LED has a pixel pitch less than 10 μm, preferably less than 4 μm. Whilst the methods and arrays described herein are done so with reference to micro LEDs, the skilled person understands that the examples are also applicable to different sized LEDs and different sized LED arrays. 
     Advantageously, the ability to tune the organic semiconductor allows its full dissolution within photo definable material allowing standard semiconductor processing techniques to be utilized. The utilization of existing techniques enables economic volume processing. Quantum dots tend to suffer from increased degradation in a photo definable medium and the described methods do not suffer from such a problem. Advantageously, the use of a thin colour conversion layer leads to significantly higher efficiencies over conventional quantum dots due to less re-absorption and, beneficially, the ability to tune the absorption and emission spectrum of the organic semiconductor leads to significantly higher efficiencies than in conventional colour conversion techniques.