The present invention relates to an illumination apparatus. Such an apparatus may be used for domestic or professional lighting, for liquid crystal display backlights and for general illumination purposes.

Incandescent light sources are low cost but have low efficiency, and are relatively large requiring large light fittings. Fluorescent lamps in which a gas discharge generates ultraviolet wavelengths which pumps a fluorescent material to produce visible wavelengths, have improved efficiency compared to incandescent sources, but also have a large physical size. Heat generated by inefficiencies in these lamps is typically radiated into the illuminated environment, such that there is typically little need for additional heatsinking arrangements.

In this specification, an illumination apparatus refers to an illumination apparatus whose primary purpose is illumination of an environment such as a room or street scene, or as a display backlight such as an LCD backlight. An illumination apparatus is typically capable of significantly higher luminance than 1000 nits. This is opposed to for example displays, whose primary purpose is image display by providing light to a viewing observer's eyes so that an image can be seen. By way of comparison, if the luminance of a display is very high, for example greater than 1000 nits, then disadvantageously a display can be uncomfortably bright to view. Thus the considerations for an illumination apparatus with a primary illumination purpose and a display apparatus that provides a secondary illumination purpose are different.

If an illumination apparatus is used as a backlight in a display apparatus, losses in the spatial light modulator of the display apparatus will reduce the luminance to a level suitable for comfortable viewing. Thus such an arrangement has a secondary illumination function that is not generally suitable for the purpose of efficient and bright illumination of an environment.

Light-emitting diodes (LEDs) formed using semiconductor growth onto monolithic wafers can demonstrate significantly higher levels of efficiency compared to incandescent sources. In this specification LED refers to an unpackaged LED die (chip) extracted directly from a monolithic wafer, i.e. a semiconductor element. This is different from packaged LEDs which have been assembled into a package to facilitate subsequent assembly and may further incorporate optical elements such as a hemispherical structure which increases its size but increases light extraction efficiency. To optimise quantum efficiency, extraction efficiency and lifetime, it is desirable to minimise the junction temperature of the LED. This is typically achieved by positioning a heat dissipating structure (or heatsink) on the rear of the LED to provide extraction of heat from the chip into an ambient environment.

LED primary heatsinks typically comprise heat slugs (or heat spreaders), LED electrodes, and the dielectric layer of a metal core printed circuit board (MCPCB). LED secondary heat sinks typically comprise the metal layer of the MCPCB, MCPCB solder attachment points and formed fins in metal or thermally conductive plastic material attached to or formed on the primary heatsink arrangement. For illustrative purposes, in this specification, primary thermal resistance refers to the thermal resistance to heat generated in a light emitting element formed by the light emitting element itself, respective heat spreading elements, electrodes and electrically insulating support substrate (such as the dielectric layer of an MCPCB). The secondary thermal resistance is defined by the thermal resistance of subsequent elements, including the metal layer of an MCPCB, MCPCB solder attachment points and heatsink elements.

Assembly methods for known macroscopic LEDs typically of size lxlmm comprise a pick-and-place assembly of each LED chip onto a conductive heat slug for example silicon. The heat slug is attached to a dielectric which is bonded on a metal layer, forming a metal core printed circuit board (MCPCB). Such a primary heatsink requires multiple pick-and-place operations and is bulky and costly to manufacture. It would thus be desirable to reduce primary heatsink complexity.

Secondary heatsinks can be heavy, bulky and expensive. It is thus desirable to minimise the thickness of the secondary heatsink by minimising the resistance of the thermal paths of the primary heatsink.

In lighting applications, the light from the emitter is typically directed using a luminaire optical structure to provide the output directionality. The angular variation of intensity is termed the directional distribution which in turn produces a light radiation pattern on surfaces in the illuminated environment and is defined by the particular application. Lambertian emitters provide light to the flood a room. Non-Lambertian, directional light sources use a relatively small source size lamp such as a tungsten halogen type in a reflector and/or reflective tube Juminaire, in order io provide a more directed source. Such lamps efficiently use the light by directing it to areas of importance. These lamps also produce higher levels of visual sparkle, in which the small source provides specular reflection artefacts, giving a more attractive illumination environment. Further, such lights have low glare, in which the off-axis intensity is substantially lower than the on-axis intensity so that the lamp does not appear uncomfortably bright when viewed from most positions.

Directional LED illumination apparatuses can use reflective optics (including total internal reflective optics) or more typically catadioptric (or tulip) optic type reflectors, as described for example in US841423. Catadioptric elements employ both refraction and reflection, which may be total internal reflection or reflection from metallised surfaces.

PCT/GB2009/002340 describes an illumination apparatus and method of manufacture of the same in which an array of microscopic LEDs (of size for example 0.1x0.1mm) is aligned to an array of micro-optical elements to achieve a thin and efficient directional light source. GB1005309.8 describes an illumination apparatus, a method of manufacture of the same and a heat sink apparatus for use in said illumination apparatus in which an array of optical elements directs light from an array of light emitting elements through a heat dissipating structure to achieve a thin and efficient light source that provides directional illumination with efficient dissipation of generated heat into the illuminated environment.

According to a first aspect of the present invention, there is provided an illumination apparatus whose primary purpose is illumination as opposed to display; the illumination apparatus comprising: a structure comprising a light emitting element array and an optical array; the light emitting element array comprising a plurality of light emitting elements arrayed on a first side of a first substrate; the optical array comprising a plurality of directional optical elements arrayed on a first side of a second substrate; the first side of the first substrate facing the first side of the second substrate, and respective light emitting elements aligned with respective optical elements; wherein the first substrate is between 0.01mm and 1.1mm thick. The first substrate may be between 0.02mm and 0.4mm thick or may be between 0.05mm and 0.2mm thick. The first substrate may be formed of a metal or a glass material. The material of the first substrate may comprise a glass material. The material of the first substrate may comprise a metal foil. The metal foil may comprise a stainless steel material. A plurality of heat spreading elements may be provided on the first substrate wherein respective heat spreading elements are positioned between the first substrate and respective light emitting elements. The plurality of light emitting elements may be from a monolithic wafer arranged in an array with their original monolithic wafer positions and orientations relative to each other preserved. The second substrate may comprise a glass material. The glass material of at least the first substrate may comprise a conductive filler material. A heat sink element may be attached to the second side of the first substrate. A heat sink element may be attached to the second side of the second substrate. The heat spreading elements may comprise silicon. The heat spreading elements may comprise a metallic film formed on the first substrate. The metallic film may be of thickness greater than 100 nanometres. The metallic film may be of thickness greater than 1 micrometre. The metallic film may be of thickness greater than 10 micrometres. Each light-emitting element may have a maximum width or diameter less than or equal to 500 micrometers. Each light-emitting element may have a maximum width or diameter less than or equal to 250 micrometers. Each light-emitting element may have a maximum width or diameter less than or equal to 100 micrometres. Each optical element may have a maximum height less than or equal to 5mm. Each optical element may have a maximum height less than or equal to 2.5mm. Each optical element may have a maximum height less than or equal to 1 millimetre. At least one seal may be provided between the first substrate and second substrate.

Further aspects of the invention are as claimed in the appended claims.

Compared to known illumination apparatuses, the present embodiments advantageously provide reduced thermal resistance to heat generated in an LED array, thus providing higher device efficiency, longer lifetime and greater reliability. Further, the cost of the apparatus is reduced as secondary heatsink cost is reduced. The substrates can advantageously be formed from glass or thin metal foils, particularly stainless steel foils and can thus be made with very large area using known handling methods and can undergo known large area masking processes. The present embodiments advantageously provides many LED illumination devices with low thermal resistance to be processed in parallel, reducing cost. The thermal expansion of illumination apparatus substrates can be matched, reducing thermal distortion effects and providing greater reliability. The illumination apparatus can be conveniently arranged to provide a thin and efficient backlight illumination apparatus. Further an addressable backlight illumination apparatus with high resolution and large area can conveniently be arranged, so as to improve display contrast.

Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings in which:

Fig.l shows a method to form an illumination apparatus comprising heatsink structures;

Fig.2 shows a flip chip LED with lateral electrical connections;

Fig.3 shows a vertical thin film LED;

Fig.4 shows an LED array with lateral electrical connections;

Fig.5 shows in cross section a further illumination apparatus comprising heatsink structures ;

Fig.6 shows in plan view the illumination apparatus of Fig.5;

Fig.7 shows in cross section a further illumination apparatus with a heatsink;

Fig.8 shows an optical substrate for an illumination apparatus;

Fig.9 shows a further optical substrate for an illumination apparatus;

Fig.10 shows a roughened substrate arranged to provide improved heat extraction from an LED array;

Fig.ll shows a method to form an illumination apparatus comprising a heatsink structure with an optical array;

Fig.l2a shows a method to attach an optical substrate with an LED substrate;

Fig.12b shows a further method to attach an optical substrate with an LED substrate;

Fig.13 shows an optical substrate further comprising electrodes and light emitting elements; Fig.14 shows an LED substrate comprising an array of connection elements;

Fig.15 shows the alignment of monolithic LED wafers with the LED substrate of Fig.13;

Fig.16 shows the LED substrate following selective removal of LEDs from respective monolithic LED wafers;

Fig.17 shows an optical array substrate;

Fig.18 shows the alignment of the optical array substrate of Fig.16 with the LED substrate of Fig.15;

Fig.19 shows a further aligned optical array substrate and LED substrate;

Fig.20a shows a singulated substrate;

Fig.20b shows a further singulated substrate;

Fig.20c shows a further singulated substrate;

Fig.21 shows a roll to roll processing apparatus;

Fig.22 shows a further roll to roll processing apparatus;

Fig.23 shows in plan view an LED substrate comprising an array of connection elements and an array of electrode elements;

Fig.24 shows the LED substrate of Fig.23 further comprising an array of heat spreading elements;

Fig.25 shows the LED substrate of Fig.24 further comprising an array of LEDs and electrode elements;

Fig.26 shows in cross section a detail of the arrangement of Fig.25;

Fig.27 shows in plan view a detail of the arrangement of Fig.25;

Fig.28 shows in cross section an LED substrate comprising electrode and heat spreading elements;

Fig.29 shows in plan view an LED substrate comprising electrode and heat spreading elements;

Fig.30 shows in cross section an alternative LED substrate comprising electrode and heat spreading elements; Fig.31 shows in plan view an arrangement of Fig.30;

Fig.32 shows in cross section a display apparatus comprising a backlight illumination apparatus of the present embodiments;

Fig.33 shows an arrangement of the display apparatus of Fig.32;

Fig.34a shows in cross section a backlight illumination apparatus;

Fig.34b shows in plan view the backlight illumination apparatus of Fig.34a; and

Ftg.35 shows a further backlight illumination apparatus.

A method to form an illumination apparatus is shown in Fig.l. In a first step, a monolithic wafer comprises a substrate 2 which may be for example sapphire and a layer 3 of light emitting elements 4 such as light emitting diodes (LEDs) formed on its surface, for example in Gallium Nitride. A first bonding layer 6 which may comprise metal materials such as palladium is formed on the surface of layer 3 and gaps 7 provided between the light emitting elements 4 on the wafer, for example by etching, sawing or laser scribing.

Alternatively, the layer 3 may be continuous. A glass substrate 14 (which may be termed a motherglass) has a heat spreading element 16 formed on its surface, a dielectric layer 18 (that may be patterned) and patterned electrode layer 12 formed thereon. On the surface of the electrode 10, a second bonding layer comprising a first metal layer 10 for example comprising palladium and a second metal layer 8 for example indium is formed. The second bonding layer is patterned so that bonding regions are aligned with light emitting element 4. Other metal layers in substitution of or in addition to palladium and indium may be used, as is known in the art and including but not limited to titanium, tantalum, gold, tin, indium tin oxide, aluminium, platinum, and nickel.

In a second step, the first and second aligned bonding layers 6, 8, 10 are brought into contact and the sandwich is heated so as to provide an alloy bond layer 9 between the electrode layer 12 and the respective light emitting element 4. For example the layers 6, 8, 10 may be heated to for example 180 degrees Celsius to provide a rugged electrical and mechanical bond between the element 4 and electrode 12.

In a third step, the interface of the layer 3 and substrate 2 is illuminated by short pulse ultraviolet radiation in region 20 so as to provide decomposition of the gallium and nitrogen close to the sapphire interface. On heating the sandwich to above the melting point of metallic gallium, for example to greater than about 40degC, the substrates 2, 14 can be separated as shown, with the element 4 attached to the substrate 14 and adjacent light emitting elements in layer 3 remain attached to the substrate 2.

The second bonding layer 8,10 and ultraviolet illumination is patterned so that it can be further arranged in alignment with some others of the light emitting elements, for example light emitting element 5 to form a plurality of light emitting elements 4,5 arrayed on the first side of the substrate 14. Thus a light emitting element array 22 comprises a plurality of light emitting elements 4,5 arrayed on a first side of a first substrate 14. Advantageously, the patterning of the layers 8, 10 and of laser illumination in region 20 mean that elements 4,5 from the layer 3 may be selectively extracted with a pitch substantially the same as the pitch of the respective elements in the monolithic wafer. Thus the plurality of light emitting elements 4,5 are selectively removed from a monolithic wafer 2,3 in a manner that preserves the relative spatial position of the selectively removed light-emitting elements 4,5. Such an arrangement advantageously provides accurate location with a subsequent array of optical and electrical connection elements. Further a plurality of heat spreading elements 16 are provided on the substrate 14; wherein respective heat spreading elements are positioned between the first substrate 14 and respective light emitting elements 4,5.

In a fourth step (shown without bonding layers and for a pair of light emitting elements 4,5 on substrate 14), an LED light emitting element array 22 is formed comprising substrate 14, heat spreading elements 16, 17, phosphor elements 24, bottom electrode 26, top electrode 28 and dielectric region 30. Other known wavelength conversion layers may be substituted for phosphor elements 24. In the current embodiments, each of the steps to form a particular feature can be performed in parallel for all of the light emitting elements 4 transferred onto the substrate 14. Advantageously, such a method can significantly reduce the processing cost of such a device. In this embodiment, the primary heatsink comprises the bottom electrode 26, dielectric layer 18, heat spreading element 17 and substrate 14.

In a fifth step, an optical substrate 34 is formed comprising an array of catadioptiic directional optical elements 35 optionally separated by gaps 37. Alternatively, the directional optical elements may be reflective or refractive. Advantageously, catadioptric optical elements provide efficient capture of LED light and a directional output light beam with relatively small thickness and width for a given cone angle compared to for example parabolic optical elements. The optical substrate 34 may be formed by moulding of an optically transparent polymer material onto a support glass substrate 34 using an appropriately shaped mould. The optical substrate 34 is aligned with the LED substrate array 22 and seal regions 26 are formed to provide an illuminator cell 38. The cell may be spaced by seal 36 and or optic array 35. The gaps 37 advantageously reduce the amount of bending of the substrate 34 due to differences in shrinkage during formation of the optical elements 35. Alternatively, the gap region 37 may comprise thin regions of the material used to form the elements 35.

The term glass in this specification refers to an inorganic, non-metallic solid prepared by the action of heat and subsequent cooling with an amorphous structure, having no long range order and may have for example a borosilicate or sodalime composition. The first substrate 14 may be between 0.01mm and 1.1mm thick, preferably between 0.02mm and 0.4mm thick and more preferably between 0.05mm and 0.2mm thick. The first substrate may be formed of a metal or a glass material.

Specifically, the material of substrate 14 may be a glass which is 1.1mm, 0.7mm, 0.5mm or 0.4mm thick, or may preferably be microsheet glass of thickness less than 0.3mm such as Corning 0211 microsheet. The glass may further comprise chemical strengthening properties, such as incorporated in Dragontrail glass marketed by Ashahi glass or Gorilla glass marketed by Corning. Advantageously, the present embodiments provide a primary thermal resistance comparable with or better than MCPCB mounted LEDs; high surface quality and flatness for simultaneous lithographic processing of large plurality of light emitting elements; and robust handling characteristics due to the attachment to the optical substrate. Such advantages reduce secondary heatsink cost by reducing primary thermal resistance, provide large area processing of many elements in parallel and provide high reliability packaging. Thus the present embodiment provides an illumination apparatus whose primary purpose is illumination as opposed to display; the illumination apparatus comprising: a structure comprising a light emitting element array 22 and an optical array 39; the light emitting element array 22 comprising a plurality of light emitting elements 4 arrayed on a first side of a first substrate 14; the optical array 39 comprising a plurality of directional optical elements 35 arrayed on a first side of a second substrate 34; the first side of the first substrate 14 facing the first side of the second substrate34 , and respective light emitting elements a41igned with respective optical elements 35; wherein the first substrate 14 is between 0.01mm and 1.1mm thick. The first substrate 14 may be formed of a metal or a glass material. The second substrate 34 may comprise a glass material. Advantageously the thermal expansion coefficient of the first substrate 14 and second substrate 34 may be matched to provide mechanical and thermal ruggedness during operation.

The glass size may be limited to minimise damage or distortion to the substrate during handling, for example to 20 x 20 mm. A temporary support substrate 15 may be used to stabilise the substrate 14 during handling to provide rugged handling of large sheets, for example lm x lm size. The substrate 15 may be a plastic sheet, a rubber sheet, a metal sheet, or a glass sheet, and may incorporate a vacuum chuck. The attachment of the stabilising substrate 15 may be by means of a controlled melting point wax or other adhesive layer (not shown). The substrate 15 may be removed by temperature and/or solvent prior to the attachment of array 39, or after attachment. Alternatively, the substrate 14 may be attached to a heat spreading plate 48 prior to the attachment of the light emitting elements. A flexible heat conducting material such as at interface 52 may be positioned between the substrate 14 and plate 48. Advantageously this embodiment provides a stabilised but thin glass for robust handling and low thermal resistance. The plate 48 may comprise first thin portion 49 to support the substrate 14 during processing of light emitting elements prior to cell 38 assembly (thus having the function of the support substrate 15) and a second thicker portion 51 to support the fins.

The substrate 14 may alternatively comprise a thin metal foil suitable for large area lithographic processing. Advantageously, the foil may comprise a stainless steel material or an aluminium material. The foil may be formed by known processes such as hammering or rolling in order to create a sheet or a roll of metal foil with low cost and large area. The foil thickness may be between 0.01mm and 1.1mm thick, preferably between 0.02mm and 0.4mm thick and more preferably between 0.05mm and 0.2mm thick. The foil may comprise materials that have higher thermal conductivity than glass, for example greater than 15 WK ^' W and is advantageously rugged, stiff and low cost. The foil may have broadband optical reflectivity so that advantageously light from the light emitting element 4 is reflected in the optical output direction without the need for further reflective layers. The surface quality of the foil, including the roughness prior to forming the light emitting element array 22 may be improved by a step of polishing, over coating with a thin planarfcation layer or a combination thereof. The improvement in roughness is particularly advantageous if thin film transistors are to be deposited on the substrate as part of, for example the control circuitry of the light emitting element array. Advantageously, the thin foil can be handled in large rolls for example greater than lxlOOm, and is suitable for use in large area lithographic processing of light emitting element arrays. The thin foil may also be used in sheets and stabilised by temporary bonding to a thicker carrier sheet such as LCD glass that may be removed after processing and subsequently reused. Advantageously the temporary glass and foil may be processed in a standard LCD factory. Dielectric layers such as metal oxide layers can be further provided on the metal foil to provide electrical isolation between the foil and electrode layers, light emitting elements and other control electronics.

The process steps described above require many different operations to be performed on the substrate 14. In manufacture, such a substrate must have sufficient ruggedness to be undamaged by handling and processing, but must have sufficient flatness and surface finish to be suitable for lithographic processing. Advantageously, substrate 14 may comprise a glass substrate, such as used in the manufacture of liquid crystal display devices and so can be processed with high accuracy and precision over large areas with low cost.

The light emitting elements 4 may be microscopic LEDs; that is they have dimensions with a maximum width or diameter of less than 500 micrometres, preferably less than 250 micrometres and more preferably less than 100 micrometres. Microscopic LEDs of size lOOmicrometres advantageously use optical elements 35 arranged to provide directionality that have a pitch of approximately 2mm or less and a maximum height 11 of 5mm or less, preferably a maximum height 11 or 2.5mm or less and more preferably a maximum height of 1mm or less. Thus, the total cell 38 thickness may be of thickness for example 2mm. Such cells are conveniently handled using known substrate processing equipment, thus reducing cost of fabrication. Advantageously the thermal resistance of the substrate 14 is less than the thermal resistance of the substrate 34, thus providing a preferred path for heat dissipation from the rear of the LED substrate array 22. Further, microscopic LEDs of size for example 100 micrometres advantageously achieve better heat dissipation than large LEDs for a given current density. Advantageously, microscopic LEDs can utilise primary heatsinks with higher thermal resistance than larger LEDs and thus are more suitable for use with low thermal conductivity materials such as glass, while achieving similar or better performance.

In a sixth step, regions of cell 38 may be scribed, for example by means of scribes 40, 42 or laser cutting (not shown) on each respective substrate between seal 36 regions, or as required. Thus at least two different regions of the light emitting element array 22 are separated. Advantageously, multiple light emitting element arrays can be produced from a single array 22. In this manner, highly parallel processing techniques can be used, significantly reducing device cost. The scribe points 40 and 42 may be slightly offset to aid singulation.

In a seventh step, the cell 38 may be separated (or singulated) for example by breaking the cell 38. Optical coatings 43 and films such as anti-reflection coating or diffusers may be applied, or alternatively coating 43 may be applied to the substrate 34 prior to formation of optical elements 35, or prior to singulation.

In a eighth step, further elements may be attached including electrodes 44 and heatsink element 54 comprising a heat spreading plate 48 and fins 50, attached by means of a thermally transmitting interface 52. Interface 52 further provides a mechanically compliant thermally conductive layer on the first substrate 14 to provide an interface between the glass substrate 14 and heat spreading element plate 48 of the heatsink 54. Higher thermal resistance heatsinks typically use less material and are cheaper, thus reducing illumination apparatus cost. Thus a heatsink element 54 is attached to the second side of the first substrate 14.

Advantageously, glass materials have well characterised surface flatness and roughness together with bulk material properties that are appropriate for the accurate and repeatable deposition of electrodes, heat spreading elements, dielectrics, adhesives and solders. Such a substrate advantageously provides low cost and very large area substrates for the attachment of light emitting elements. Advantageously, glass substrates are compatible with known large area sheet (motherglass, or mothersheet) processes in which multiple lithographic and other processes can be performed across the sheet in parallel. Such sheets can be fabricated at low cost and very high area, such as greater than lxlmetre. The glass of the substrate 14 is not required to be transmissive and may further comprise conductive filler materials (which may be opaque) such as carbon, metals or ceramics with a thermal conductivity arranged to increase the thermal conductivity of the substrate 14, for example to greater than 1.5 WK 'in ^-1 , preferably greater than 5 WK 'm ^-1 and more preferably greater than 10 WK ^-1 m ^-1 , reducing the primary thermal resistance while maintaining characteristics suitable for photolithography and other large area array processing steps.

LED arrays are often formed by means of pick-and-place methods rather than the parallel method similar to that described in Fig.l. Such pick and place LED arrays do not typically benefit from parallel processing of many elements once they have been removed from the wafer. Further pick and place LED arrays typically require large chip sizes (for example lxlmm) to provide sufficient area for wire bond pads; and to reduce the number of pick and place operations, and thus cost, for a particular light output.

In comparison to small chip sizes with size for example of less than 0.3x0.3mm, preferably less than 0.2x0.2mm and more preferably less than 0.1x0. lmm typically achieve a lower junction temperature for a given heatsink arrangement. Advantageously, reduced junction temperature achieves higher output efficiency and device lifetime. Typically small chip sizes may use higher thermal resistance materials for primary heatsinks, reducing cost and enabling the use of substrates such as glass. As described herein, glass has many properties that are suitable for large area parallel processing.

Thus for a given design junction temperature, small chips can use higher thermal resistance primary heatsink arrangements in comparison with large chips. Thus, particularly when combined with heat spreading embodiments and small chips provided by parallel placement, the glass substrates of the present embodiments can unexpectedly achieve low junction temperatures for small chip sizes while enabling the use of thin glass substrates. Small chips can advantageously be fabricated by means of the methods described in

PCT/GB2009/002340.

The sparse array of light emitting elements4,5 may alternatively be extracted and transferred onto the mothersheet substrate 14 by means of a transfer carrier such as a vacuum tool, an adhesive layer, or a wax layer for example. Advantageously, such an arrangement does not risk damage to the un-transferred elements on the substrate 2 during the attachment step.

The light emitting element 4 may comprise for example a known type of flip chip lateral configuration LED 141 as shown with electrical connections in Fig.2. A substrate 102 such as sapphire has epitaxial layers formecl on its surface 103. Typically a Gallium Nitride device comprises an n-doped layer 104, a multiple quantum well structure 106 and a p-doped layer 108 with a p-electrode 110. In the region 112, a portion of the p-layer 108 and structure 106 is removed to provide a contact electrode 114 to be formed in contact with the n- doped layer 104. This arrangement suffers from current crowding in the region 113, reducing the maximum light output that can be obtained from the device. Solder connections 118, 120 are formed on electrodes 122, 124 respectively, mounted on a support substrate 126. In this specification, the term solder connections refers to known electrical connections including those formed by heating or by pressure or combination of heating and pressure applied to suitable electrically conductive materials. Further, solder connections may be formed by the curing of metal doped adhesive materials such as silver epoxy.

The light emitting element 4 may alternatively comprise a known type of VTF (vertical thin film) configuration LED 142 as shown in Fig.3, in which the n-doped layer 104 has been separated from the substrate 102, for example by means of laser lift off. An electrode 128 is applied to the p-doped layer 108 and attached by means of a solder element 130 to an electrode 132 formed on the substrate 126. The n-doped layer may have an electrode 136 to provide a solder 138 contact to an input electrode 140. Such a VTF configuration advantageously has reduced current crowding compared to the arrangement of Fig.2. However, the VTF configuration needs an electrode connection on the top surface, and so typically requires a wire bonding process. By way of comparison with the present embodiments, which employ large arrays of small LEDs, a large number of time consuming wire bonds would be needed. Further, wire bonding technology may have limited positional accuracy so that a large non-emitting bond pad 136 is required for reliable wire bonding. For example, the wire bond pad size may be 100 micrometers wide, comparable to the size of the LED.

Fig.4 shows a detail of LED elements after extraction and further processing steps (not shown). As (he array of LEDs is positioned with lithographic precision (with original wafer positions preserved), then the electrode connections can be made in parallel by metal deposition and precision photolithography (as opposed to wire bonding) process. The LEDs may incorporate inclined surfaces and dielectric layers 144 so as to provide convenient connection to the chip via solder contacts 118, 120. Advantageously this high accuracy process achieves many simultaneous connections and also reduces the size of the electrode connection pad.

Fig.5 shows an embodiment in which the substrate 34 has low thickness, for example less than 300 micrometres. A single electrical connection 33 may be provided to the array of light emitting elements.

Advantageously the substrate 34 may be formed from the same material used to form the substrate 14. Such a sandwich has matched coefficients of thermal expansion and will thus have minimised bending over a temperature cycle, increasing device reliability. A secondary heatsink element 57 is attached to the second side of the substrate 34 comprising a heat spreading element 58 and conductive fins 60. Apertures 62 are incorporated between the fins and heat spreading element so as to provide a path for light from the optical elements 35. Fig.6 shows in plan view the top secondary heatsink 56 of Fig.5. Thus the second substrate 34 comprises an opaque layer provided with light transmitting apertures 62. Advantageously such an arrangement reduces thermal resistance of the light output side of the illumination apparatus to heat generated in the light emitting elements.

Fig.7 shows an embodiment comprising front and rear secondary heatsinks. Thermal paths in the primary heatsink between top and bottom substrates may be provided for example within sealing pillars 36 or using spacers 61, such as metal spacers in the primary heatsink path, connected to the LED substrate 14. Thus a spacer may be provided between the first and second substrates. Fig.8 shows an alternative front substrate in which glass substrate 34 is not present, but replaced by a heatsink with aligned optical elements and thus may have a lower cost. Fig.9 shows a similar arrangement but the optical elements are within the heat spreading element 58. Advantageously, such an arrangement has a reduced thermal resistance between the LED substrate array 22 (not shown) and heatsink 58.

Fig.10 shows an embodiment in which the substrate 14 is provided with a rough surface 53 on the rear of the glass substrate 14. Such a surface may advantageously provide reduced thermal resistance compared to a smooth surface when combined with heatsink compound 52. Fig.11 shows a further embodiment in which a heatsink 64 of similar area to substrate 14 is attached to the cell 38 prior to the singulation step. Such a heatsink may be formed in metal such as aluminium or may be in a thermally conductive material such as carbon fibre or thermally conductive polymer for example that marketed with the trade name Stanyl. The heat spreading plate is cut at lines 66 and in a further step, the cell is singulated prior to separation of the devices. Advantageously, such an embodiment can further reduce the cost of assembly of the illumination apparatus. Alternatively, the heatsink can be attached after singulation of the cell 38.

Fig.12a shows a further embodiment in which the method of attachment of the substrate 34 and substrate 14 is by means of an optical adhesive material 72 (which may have a low refractive index) incorporated in the cavity of the catadioptric optic element 35. After alignment, the adhesive material 72 may be cured to provide both mechanical bonding and optical functions. The refractive index of the material 72 may be substantially lower than the refractive index of the material of the optical element 35. Fig.l2b shows an alternative embodiment incorporating pillars 78 of material which may be the same as the material used to form the optical elements 35. An adhesive 80 may be applied to the substrate 14 to provide attachment of the substrates and a rugged cell for subsequent processing and handling.

Fig.13 shows a further embodiment wherein reflective surfaces 71 are formed with a metallisation and a material 73 is incorporated between catadioptric optical elements 35 so as to provide a substantially plane surface between the light emitting elements on which electrodes 75 can be formed. In this manner, the optical element 35, 73, 34 can comprise a support substrate for electrode 75s, wavelength conversion layers and light emitting elements 4 as well as active electronic components 77 such as transistors and resistors. The heat spreading elements 79 can be attached to the light emitting elements and substrate 14. Advantageously such elements do not require electrodes to be formed thereon and so have low complexity and do not require precision alignment.

Fig.14 shows in plan view a glass substrate 14 comprising an array of connecting elements 200, which may comprise palladium and indium materials, or other known electrically and thermally conductive materials. Fig.15 shows alignment of monolithic wafer 204 such that connecting elements 200 are in alignment with some of the light emitting elements of the monolithic wafer 204. An additional wafer 208 is aligned with an array of connecting elements 202. The wafer 208 has regions 206 in which light emitting elements 4 were removed in a previous alignment and bonding step. Alternatively the light emitting elements 4 may be transferred through intermediate transfer substrates to avoid damage to the wafer 204, 208 during the attachment step.

Fig.16 shows the substrate 14 after the light emitting elements 4 have been removed from the respective monolithic wafers 204, 208. The light emitting elements are arranged in regions 210, 212. Fig.l7 shows in plan view an optical substrate 34 comprising a glass sheet with a first region 214 of optical elements 215 and a second region 216 of optical elements 217 different from elements 217.

Fig.18 shows the alignment of substrates 14 and 34 from Figs. 16 and 17 respectively. Seal regions 218, 220, 222 between the first substrate 14 and second substrate 34 are arranged so that different areas of illuminator devices can be extracted from the same illuminator cell, Fig.19 shows an alternative arrangement of seal regions 224 arranged to provide elongate illuminators, for example for use in fluorescent tube and troffer replacements. Figs.20a and 20b show separated elements from Fig.18 and Fig.20c shows a separated element form Fig.19. Additional seal regions (not shown) may be included within the singulated devices to provide increased ruggedness.

In this manner, the light emitting elements from many wafer separation steps can be combined onto single substrates. The substrate may comprise all or some of the light emitting elements 4 from a single wafer, or may comprise light emitting elements 4 from different wafers. Advantageously the shape and size of the illumination device need not be determined by the size and shape of the monolithic wafer. Advantageously such a process provides motherglass processing so that many devices can be processed in parallel, reducing cost while maintaining the thermal performance of the primary heatsink.

Fig.21 shows a further apparatus to achieve large area processing of light emitting elements. A wafer 2 is processed to provide an array of light emitting elements 4 that are attached to the surface of a drum 300 by means of an illumination spot 20. The rotation of the drum 300 is arranged in cooperation with the motion of a substrate 14 provided by drum 302 to position the elements on the surface of substrate 14. Prior to attachment, an electrode deposition apparatus 304 provides substrate electrodes while further electrode deposition apparatus 306 and phosphor deposition apparatus 308 are provided after the positioning step. In a following step, as shown in Fig.22, drums 310 and 312 are arranged to provide alignment and attachment of optical substrate comprising substrate 34 and optical elements 35. Advantageously such an arrangement can use substrates 14 such as those comprising thin metal foils with thickness between 0.01mm and 1.1mm that are flexible and can be conveniently arranged as rolls to provide large area parallel fabrication of light sources with sparsely separated light emitting elements 4. Alternatively the optical substrate 34, 35 may be on a roll and the substrate 14 may be curved in a roll-to-roll process. Alternatively both LED and optical substrates may be on rolls in a roll-to-roll process.

Fig.23 shows in plan view an illustrative example of substrate 14 arranged to provide connection to a plurality of light emitting elements 4. Substrate 14 has electrical connection regions 226, 228 formed on its surface, connected by means of electrodes 230. The electrical connection regions further provide heat spreading elements arranged for reducing the primary thermal resistance to heat generated in the plurality of light emitting elements 4.

Fig.24 shows the alignment of an array of for example silicon heat spreading elements 232 to the electrical connection regions 226, 228. Further electrical connection regions 234, 236 are provided on the silicon heat spreading elements 232. The array of silicon heat spreading elements may be from a silicon wafer for example. The heat spreading elements 232 may be from a monolithic array of silicon heat spreading elements and may be extracted in parallel onto the substrate 14 with their separation preserved.

Advantageously, such an arrangement provides for precise alignment of the array of silicon heat spreaders with the plurality of light emitting elements 4 extracted from a monolithic wafer with their separation preserved. Alternatively, the heat spreading elements 232 may be provided by a known pick-and-place method. Fig.25 shows light emitting elements 4 and top connecting electrodes 114 mounted on the silicon heat spreading elements 232. Fig.26 shows in cross section a portion of the structure of Fig.25. Substrate 14 has electrodes 230 formed for example by lithographic processing. Connection regions 226, 228, such as solder are provided for connection to the heat spreading element 232. Via holes 234, 236 are metallised to provide connection regions to achieve electrical connection paths between the first substrate 14 and the plurality of light-emitting elements, so connecting the light emitting element 4 bottom electrode 132 and top electrode 114 respectively. Thus the heat spreading elements 232 comprise via holes 234, 236 arranged to provide electrical connection paths between the first substrate 14 and the plurality of light-emitting elements 4. Fig.27 shows in further detail a plan view of the embodiment of Fig.26.

Advantageously the embodiment makes use of photolithographic parallel processing techniques and can be implemented over large areas, reducing cost. Such an embodiment advantageously provides enhanced primary heatsink arrangement compared to an embodiment in which the light emitting element 4 is mounted directly onto a dielectric. The silicon heat spreading element has a high thermal conductivity so that heat is distributed over a wider area than from the individual light emitting element 4. Thus, the primary thermal resistance is reduced. Advantageously the secondary thermal resistance may be increased, providing a lower cost and less bulky secondary heatsink.

The silicon heat spreading elements of Fig.27 are relatively thick and require mechanical positioning technologies. To provide a non mechanically positioned heat spreading layer and reduce cost, the heat spreading layer may comprise deposited silicon layers.

It would be desirable to further reduce cost and reduce thermal resistance using lithographically or otherwise defined metal deposition techniques. Fig.28 shows in cross section and Fig.29 shows in plan view an embodiment in which film heat spreading elements 240, 241, comprise a metallic film formed on the first substrate 14 using for example aluminium, tanatalum, copper or other thermally and electrically conductive materials. The film may be applied by means of known deposition techniques such as sputtering or evaporation and may be subsequently thickened by electroplating. The metallic film (which may be comprised of a stack of metallic films of different materials and geometries) may have a final thickness after processing of greater than 100 nanometres, preferably greater than 1 micrometer and more preferably greater than 10 micrometres, to achieve low thermal resistance for heat produced in the array of light emitting elements.

Alternatively the metallic film may be printed, for example by means of screen, stencil or flexographic printing which may advantageously provide final thicknesses (after processing) of 50 micrometres or more. Such thicknesses and material thermal conductivities advantageously provide a reduction in primary thermal resistance to heat generated by the light emitting elements 4. The deposited heat spreader layers may also comprise a thin electrically insulating layer such as an oxide.

Advantageously, metallic films in the present thickness ranges may achieve reduced primary thermal resistance when combined with substrates such as glass of the present thickness ranges. In particular, when combined with microscopic light emitting elements, system thermal performance can be significantly improved in comparison to known macroscopic (e.g.lxlmm) light emitting elements on MCPCB. Further, such metallic films can be processed in parallel over large area with high surface quality and low cost and can be combined with electrical connections to further reduce cost. Microscopic light emitting elements that are from a monolithic wafer arranged in an array with their original monolithic wafer positions and orientations relative to each other preserved, achieve efficient transfer of heat into substrates due their small size. Such microscopic light emitting elements from a monolithic wafer can advantageously be provided in large numbers with precise alignment to electrodes and optics to achieve a high brightness illumination apparatus. In combination with microscopic light emitting elements, the present embodiments thus achieve low system primary thermal resistance. Thus the cost of the system can be substantially reduced in comparison to pick-and-place methods and performance increased.

Gap regions 242 may be provided for example by photoresist patterning and etch steps, or by laser ablation. The spreading elements 240, 241 may provide the bottom electrode for the light emitting elements 4. Additional dielectric layers 238 may be applied between the heat spreading elements 241 and top electrode 114 to provide electrical isolation. In this manner, strings of light emitting elements may be assembled. Thus an electrically insulating element 238 is formed on a heat spreading element 241.

In an alternative embodiment, a lateral configuration light emitting element may be provided between adjacent heat spreading elements 244 and connected by means of contact regions 246 as shown in cross section in Fig.30 and plan view in Fig.31. Such an arrangement reduces the complexity of patterning on the substrate 14.

Fig.32 shows a display embodiment wherein an illumination device 38 is attached to a secondary heat sink 250 and used as a backlight illumination apparatus to illuminate a known liquid crystal display panel 254 comprising polarisers 256, 264, substrates 258, 262 and liquid crystal layer 260. An additional diffuser 252 may be inserted to provide increased uniformity of illumination across the panel. Advantageously such an arrangement provides very efficient coupling of light from the light emitting elements into the panel. The light source can be provided as a single element of the same size as the display panel using the methods of the present embodiments. Further, such illuminator devices can be singulated from glass the same size used to fabricate the panel 254, thus providing a common source of materials and cost reduction. To further improve display ruggedness and reduce thickness, such a backlight illumination apparatus incorporating elements 250, 38, 252 may be bonded to the polariser 256 of the display. Advantageously the present embodiments can provide high uniformity and reducing losses in the diffuser 252 (as a weaker diffuser can be used than would otherwise be required to provide high uniformity). Such a backlight illumination apparatus thus has reduced cost. Further such a backlight illumination apparatus can be used to provide high resolution segmentation of the illumination to the LCD panel as shown in Fig.33. The backlight illumination apparatus can be addressed as regions 266 to provide variable illumination functions by means of a controller 268 to adjust the illumination in cooperation with the image on the display panel 254 as well known in the display art. Advantageously the present embodiments can provide very high resolution display addressing at low cost.

Fig.34a shows an edge-lit backlight illumination apparatus suitable for illuminating a transmissive or transflective display comprising the illumination cell 38, attached to the edge of a light guide plate 270. Light rays 276 from the cell 38 enter the light guide plate 270 and are guided through light redirecting elements 272 through an optional diffuser 274. Advantageously, the width of the optical elements 35 may be 2mm or less when used with microscopic light emitting elements of size of order 100 micrometres. By way of comparison with known edge lit backlight illumination apparatuses, such an arrangement provides for efficient coupling of light in a thin package. Fig.34b shows the embodiment of Fig.34a in plan view. Linear arrays of light emitting elements can conveniently be extracted from a mothersheet to provide sufficient input illumination power. The optical elements 72 may for example comprise compound parabolic concentrators. Thus a backlight illumination apparatus comprises the illumination apparatus described herein and a further light guide plate 270 and output coupling optical element 272, 274.

A further embodiment of an edge lit backlight illumination apparatus is shown in Fig.35. Patterned microlens elements 280 are formed on the output surface of the light guide plate 278 so that off-axis light is coupled towards a prism array 282 arranged to direct off-axis light in a forward direction. As for the embodiment of Fig.34a, the cell 38 provides a very thin and efficient source for coupling light into a thin waveguide.