CN103165783A

CN103165783A - Flip-chip light emitting diode and manufacturing method and application thereof

Info

Publication number: CN103165783A
Application number: CN2012100089711A
Authority: CN
Inventors: 宋健民; 甘明吉; 蔡百掦
Original assignee: RiteDia Corp
Current assignee: RiteDia Corp
Priority date: 2011-12-15
Filing date: 2012-01-12
Publication date: 2013-06-19
Also published as: TWI473299B; TW201324847A

Abstract

The invention relates to a flip chip type light emitting diode, comprising: the semiconductor device comprises a substrate, a semiconductor epitaxial multilayer composite structure, a first diamond-like/conductive material multilayer composite structure, a second diamond-like/conductive material multilayer composite structure and an insulating protection layer, wherein the first diamond-like/conductive material multilayer composite structure and the second diamond-like/conductive material multilayer composite structure are used as a P-type electrode and an N-type electrode of the semiconductor epitaxial multilayer composite structure to buffer thermal stress caused by thermal expansion coefficient difference (coefficient thermal expansion mismatch). The invention also relates to a manufacturing method and application of the flip chip type light emitting diode.

Description

Crystal-coated light-emitting diodes and method for making thereof and application

Technical field

The invention relates to encapsulating structure on its chip board of a kind of crystal-coated light-emitting diodes and manufacture method thereof and use, can reach encapsulating structure on its chip board of the crystal-coated light-emitting diodes of buffering thermal expansion coefficient difference (coefficient thermal expansion mismatch) and manufacture method thereof and use in espespecially a kind of structure.

Background technology

From the sixties, the advantage such as luminous that the power consumption of light-emitting diode (Light Emitting Diode, LED) is low and long-lasting replaces gradually and is used in daily life throwing light on or the purposes such as the indicator light of various electric equipments or light source.What is more, and light-emitting diode has been applied in large-scale outdoor display billboard or traffic sign towards the development of multicolour and high brightness.

In recent years, flourish due to electronic industry, the electronic product demand is cumulative, so electronic product enters multi-functional and the direction such as high-effect development, also begins light-emitting diode chip for backlight unit is applied to various electronic products.Wherein especially the portable electronic product kind is day by day numerous, and volume and the weight of electronic product are more and more less, required circuit board volume also with diminish, therefore, the radiating effect of circuit board becomes one of problem of significant.

With the light-emitting diode chip for backlight unit that often uses now, because luminosity is enough high, therefore can be widely used in the various electronic installations such as display backlight source, small projector and illumination.Yet, at present in the input power of LED, the energy transform into heat energy of 80% energy meeting nearly, when if the support plate of carrying LED element can't dispel the heat effectively, just can make the light-emitting diode chip for backlight unit interface temperature raise, except affecting luminous intensity, also may accumulate in light-emitting diode chip for backlight unit because of temperature and cause the layers of material expanded by heating, impel to sustain damage in structure and life of product is produced harmful effect.

Accordingly, if can further improve the harmful effect of radiating efficiency and mitigation or the removal light-emitting diode expanded by heating of light-emitting diode, will more can impel the development of whole electronic industry.

Summary of the invention

Main purpose of the present invention is that a kind of crystal-coated light-emitting diodes is being provided, it has the structural design of buffering thermal expansion coefficient difference (coefficient thermal expansion mismatch), can continue to make heat loss in the process of light-emitting diode running generation heat.Impel overall structure to produce thermal expansion even there is the part heat not have to scatter and disappear in the self-luminous diode, the diamond like carbon that wherein arranges/electric conducting material multi-layer compound structure is thermal stress corresponding to available buffer also, and protect injury-free.

For reaching the described purpose in top, an aspect of the present invention provides a kind of crystal-coated light-emitting diodes, comprising: a substrate; Semiconductor extension multi-layer compound structure, it is positioned at this substrate top and comprises one first semiconductor epitaxial layers and one second semiconductor epitaxial layers, and wherein, this first semiconductor epitaxial layers and this second semiconductor epitaxial layers are stacking settings; One first kind diamond/electric conducting material multi-layer compound structure, be positioned at above this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, and be electrically connected this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, with as one first electrode; One Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, be positioned at above this second semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, and be electrically connected this second semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, with as one second electrode; And an insulating protective layer, cover the sidewall of this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure and the sidewall of this second semiconductor epitaxial layers.

Another aspect of the present invention provides a kind of crystal-coated light-emitting diodes, comprising: a substrate; Semiconductor extension multi-layer compound structure, it is positioned at this substrate top and comprises one first semiconductor epitaxial layers, one second semiconductor epitaxial layers and a blind hole, wherein, this first semiconductor epitaxial layers and this second semiconductor epitaxial layers are stacking settings, and this blind hole runs through this second semiconductor epitaxial layers; One first kind diamond/electric conducting material multi-layer compound structure, be positioned at above this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, and be electrically connected this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, with as one first electrode, wherein, this first kind diamond/electric conducting material multi-layer compound structure is to be filled in this blind hole of this semiconductor epitaxial multi-layer compound structure; One Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, be positioned at above this second semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, and be electrically connected this second semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, with as one second electrode; An and insulating protective layer; cover the sidewall of this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure and the sidewall of this second semiconductor epitaxial layers; and the inner wall surface of this blind hole, with contacting between isolated this first kind diamond/electric conducting material multi-layer compound structure and this second semiconductor epitaxial layers.

In the above-mentioned crystal-coated light-emitting diodes of the present invention, with being electrically connected to the counter electrode of N type semiconductor epitaxial loayer and P type semiconductor epitaxial loayer in the semiconductor epitaxial multi-layer compound structure, all be designed to diamond like carbon/electric conducting material multi-layer compound structure.In other words, be arranged at the corresponding N-type electrode of N type semiconductor epi-layer surface, can deposit in advance general metal as the N-type electrode, depositing diamond-like again, and can the selectivity repeated deposition applicable conductive material layer and diamond like carbon layer, form accordingly diamond like carbon/electric conducting material multi-layer compound structure, with the N-type electrode as corresponding N type semiconductor epitaxial loayer.Equally, for the P type semiconductor epitaxial loayer, also can deposit in advance general metal as P type electrode, depositing diamond-like again, and can the selectivity repeated deposition applicable conductive material layer and diamond like carbon layer, form accordingly diamond like carbon/electric conducting material multi-layer compound structure, with the P type electrode as corresponding P type semiconductor epitaxial loayer.

Above-mentioned diamond like carbon/electric conducting material multi-layer compound structure can allow crystal-coated light-emitting diodes of the present invention, for thermal expansion coefficient difference (the coefficient thermal expansion mismatch) stress that causes, has buffer capacity.In other words; above-mentioned diamond like carbon/electric conducting material multi-layer compound structure; can accelerated heat scatter and disappear in the process of light-emitting diode running generation heat; accumulation causes overall structure generation thermal expansion even the part heat does not have to scatter and disappear in the self-luminous diode; diamond like carbon/electric conducting material multi-layer compound structure is thermal stress corresponding to available buffer also, and can protect in crystal-coated light-emitting diodes all the other members injury-free.

In the above-mentioned crystal-coated light-emitting diodes of the present invention, this semiconductor epitaxial multi-layer compound structure can selectivity also comprise an active intermediate, and this active intermediate is to be folded between this first semiconductor epitaxial layers and this second semiconductor epitaxial layers.In addition, if be provided with blind hole in structure, this blind hole runs through this active intermediate.In the present invention, this active intermediate can be multiple quantum well layer (multiple quantum well layer), converts the efficient of luminous energy in order to promote electric energy in light-emitting diode.

in the present invention's one preferred embodiment, the more alternative reflector that comprises of crystal-coated light-emitting diodes, it can be arranged between this semiconductor epitaxial multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, the material in this reflector can be indium tin oxide (indium tin oxide, ITO), aluminum zinc oxide (aluminum zinc oxide, AZO), zinc oxide (ZnO), Graphene (graphene), aluminium, silver, nickel (Ni), cobalt (Co), palladium (Pd), platinum (Pt), gold (Au), zinc (Zn), tin (Sn), antimony (Sb), plumbous (Pb), copper (Cu), copper silver (CuAg), nickeline (NiAg), its alloy, or its metal mixture.Above-mentioned copper silver (CuAg) and nickeline (NiAg) etc. refer to eutectic metal (eutectic metal), except being used for reaching reflecting effect, also can reach the effectiveness that forms ohmic contact (ohmic contact).

Crystal-coated light-emitting diodes of the present invention is made by general through type light-emitting diode or side general formula light-emitting diode.Particularly, P type semiconductor epitaxial loayer and N type semiconductor epitaxial loayer for side general formula light-emitting diode all use diamond like carbon/electric conducting material multi-layer compound structure as its counter electrode, and make the counter electrode of P type semiconductor epitaxial loayer and the counter electrode surface both of N type semiconductor epitaxial loayer form a copline.In addition, though crystal-coated light-emitting diodes of the present invention from the through type light-emitting diode or be side general formula light-emitting diode, its semiconductor epitaxial multi-layer compound structure sidewall and/or exposed surface all can use insulating protective layer to cover.

better, this first semiconductor epitaxial layers and this first kind diamond/electric conducting material multi-layer compound structure (as the first electrode) are N-types, this second semiconductor epitaxial layers and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure (as the second electrode) are the P types, wherein, this first kind diamond/electric conducting material multi-layer compound structure, and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure can select free conductive material layer and conduction class carbon to bore the layer laminate structure, electric conducting material and diamond like carbon mixture, and electric conducting material and conductivity diamond like carbon mixture institute cohort group is at least a.

The material of above-mentioned conductive material layer or electric conducting material can be selected free indium tin oxide (indium tin oxide, ITO), aluminum zinc oxide (aluminum zinc oxide, AZO), zinc oxide (ZnO), Graphene (graphene), titanium (Ti), aluminium (Al), chromium (Cr), nickel (Ni), platinum (Pt), molybdenum (Mo), tungsten (W), silver (Ag), platinum (Pt) and golden (Au) institute cohort group is at least a.In other words, this conductive material layer or this metal can use the alloy of above-mentioned material or metal mixture to consist of.Because diamond like carbon has better thermal coefficient of expansion (coefficient of thermal expansion, CTE), therefore just can be when the Integral luminous diode expanded by heating as the diamond like carbon of electrode/electric conducting material multi-layer compound structure, the stress that the buffering thermal expansion produces, therefore light-emitting diode overall structure susceptible to not, heat loss in the time of simultaneously can also the running of accelerated luminescence diode reduces the light-emitting diode overall structure because of the impaired possibility of heat.For example, can use aluminium (Al), titanium (Ti), nickel (Ni), platinum (Pt) and gold (Au) as conductive material layer, and mutually stacking with conductivity diamond like carbon layer, can consist of diamond like carbon of the present invention/electric conducting material multi-layer compound structure.

Crystal-coated light-emitting diodes of the present invention is more alternative to be comprised: one first metal solder layer is positioned on this first kind diamond/electric conducting material multi-layer compound structure; And one second metal solder layer, be positioned on this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, wherein, the surface of the surface of this second metal solder layer and this first metal solder layer is to form a copline.The invention described above crystal-coated light-emitting diodes; as the term suggests namely engage (bonding) to cover crystal type with another circuit board, be used for the jointing metal weld layer on the P type electrode of therefore last light-emitting diode and N-type electrode surface and usually can mutually form copline.

In addition, in crystal-coated light-emitting diodes of the present invention, the conductive material layer surface of the conductive material layer of this first kind diamond/electric conducting material multi-layer compound structure surface and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure also can form a copline.Perhaps, the conduction diamond like carbon layer of this first kind diamond/electric conducting material multi-layer compound structure surface and the surperficial copline that forms of the conduction diamond like carbon layer of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure.Also or, the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure is to form a copline.from the above, by the diamond like carbon layer in adjustment diamond like carbon/electric conducting material multi-layer compound structure and the thickness of conductive material layer, can allow the first kind diamond that is electrically connected respectively the first semiconductor epitaxial layers and the second semiconductor epitaxial layers/electric conducting material multi-layer compound structure surface and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure surface form a copline, and then follow-up the first metal solder layer surface that is formed at first kind diamond/electric conducting material multi-layer compound structure surface and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure surface, aspect forms a copline with the second metal solder layer surface.

In crystal-coated light-emitting diodes of the present invention; the surface of the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, this second metal solder layer or the surface of the first metal solder layer; can selectivity exceed, lower than or etc. higher than the surface of this insulating protective layer, above-mentioned grade forms a copline higher than i.e. expression.

In the present invention's one specific embodiment; this semiconductor epitaxial multi-layer compound structure alternative more is provided with a blind hole; this blind hole runs through this active intermediate and this second semiconductor epitaxial layers; and this insulating protective layer covers the inner wall surface of this blind hole; wherein; this first kind diamond/electric conducting material multi-layer compound structure is to be filled in this blind hole that inner wall surface is coated with this insulating protective layer, and connects this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure.This crystal-coated light-emitting diodes can selectivity also comprise a reflector equally, and it is to be folded between this semiconductor epitaxial multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure.

In the above-mentioned crystal-coated light-emitting diodes of the present invention, the material of this insulating protective layer can be selected at least a in free silicon nitride, silicon dioxide and insulation diamond like carbon institute cohort group.

Another object of the present invention is that a kind of manufacture method of crystal-coated light-emitting diodes is being provided, via stratified sedimentation conductive material layer and diamond like carbon layer, so can consist of diamond like carbon/electric conducting material multi-layer compound structure with the counter electrode as semiconductor epitaxial layers, cushion by this thermal stress that thermal expansion coefficient difference causes, and then improve radiating efficiency and the life-span of light-emitting diode.

For reaching the described purpose in top, another aspect of the present invention provides a kind of manufacture method of crystal-coated light-emitting diodes, comprises the following steps: a substrate is provided; In this substrate top formation semiconductor extension multi-layer compound structure, wherein, this semiconductor epitaxial multi-layer compound structure comprises one first semiconductor epitaxial layers and one second semiconductor epitaxial layers, and wherein, this first semiconductor epitaxial layers and this second semiconductor epitaxial layers are stacking settings; Form respectively a first kind diamond/electric conducting material multi-layer compound structure and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure above this first semiconductor epitaxial layers and this second semiconductor epitaxial layers; Form respectively one first metal solder layer and one second metal solder layer on this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, wherein, the surface of the surface of this second metal solder layer and this first metal solder layer is to form a copline; And form an insulating protective layer, cover the sidewall of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, this second semiconductor epitaxial layers and this active intermediate.

Another aspect of the present invention provides a kind of manufacture method of crystal-coated light-emitting diodes, comprises the following steps: a substrate is provided; In this substrate top formation semiconductor extension multi-layer compound structure, wherein, this semiconductor epitaxial multi-layer compound structure comprises one first semiconductor epitaxial layers and one second semiconductor epitaxial layers, and wherein, this first semiconductor epitaxial layers and this second semiconductor epitaxial layers are stacking settings; Offer a blind hole in this semiconductor epitaxial multi-layer compound structure, wherein, this blind hole runs through this second semiconductor epitaxial layers; Form an insulating protective layer, cover the sidewall of this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure and the sidewall of this second semiconductor epitaxial layers, and the inner wall surface of this blind hole, with contacting between isolated this first kind diamond/electric conducting material multi-layer compound structure and this second semiconductor epitaxial layers; And form respectively a first kind diamond/electric conducting material multi-layer compound structure and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure in this first semiconductor epitaxial layers and this second semiconductor epitaxial layers top.

In the manufacture method of the above-mentioned crystal-coated light-emitting diodes of the present invention, the same alternative of this semiconductor epitaxial multi-layer compound structure also comprises an active intermediate, this active intermediate is to be folded between this first semiconductor epitaxial layers and this second semiconductor epitaxial layers, it can be multiple quantum well layer (multiple quantum well layer), converts the efficient of luminous energy in order to promote electric energy in light-emitting diode.For example, this first semiconductor epitaxial layers and this first kind diamond/electric conducting material multi-layer compound structure are N-types, and this second semiconductor epitaxial layers and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure are the P types.In addition, if be provided with blind hole in structure, this blind hole runs through this active intermediate.

In the manufacture method of the above-mentioned crystal-coated light-emitting diodes of the present invention, this first kind diamond/electric conducting material multi-layer compound structure and the optional free conductive material layer of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure and conduction class carbon bore at least a of layer laminate structure, electric conducting material and diamond like carbon mixture and electric conducting material and conductivity diamond like carbon mixture institute cohort group.Wherein, the material of this conductive material layer or this electric conducting material is to select free indium tin oxide (indium tin oxide, ITO), aluminum zinc oxide (aluminum zinc oxide, AZO), zinc oxide (ZnO), Graphene (graphene), titanium (Ti), aluminium (Al), chromium (Cr), nickel (Ni), platinum (Pt), molybdenum (Mo), tungsten (W), silver (Ag), platinum (Pt) and golden (Au) institute cohort group is at least a.

In the manufacture method of the above-mentioned crystal-coated light-emitting diodes of the present invention, the conductive material layer surface of the conductive material layer of this first kind diamond/electric conducting material multi-layer compound structure surface and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure is to form a copline; Perhaps, the conduction diamond like carbon layer surface of the conduction diamond like carbon layer of this first kind diamond/electric conducting material multi-layer compound structure surface and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure is to form a copline; Also or, the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure is to form a copline.

The manufacture method alternative of the above-mentioned crystal-coated light-emitting diodes of the present invention is further comprising the steps of: on this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, form respectively one first metal solder layer and one second metal solder layer, wherein, the surface of the surface of this second metal solder layer and this first metal solder layer is to form a copline.In addition, the surface of the surface of the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, this second metal solder layer or the first metal solder layer also can higher or lower than this insulating protective layer the surface or with its formation one copline.

In the manufacture method of the above-mentioned crystal-coated light-emitting diodes of the present invention, this first kind diamond/electric conducting material multi-layer compound structure and this first metal solder layer are to form after insulating protective layer forms or before.In addition, this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure are to form simultaneously or separately form.

In the present invention's one specific embodiment, the manufacture method of above-mentioned crystal-coated light-emitting diodes also comprises following steps: before the Equations of The Second Kind diamond/the electric conducting material multi-layer compound structure forms, form a reflector in this on this semiconductor epitaxial multi-layer compound structure.In addition, this first kind diamond/electric conducting material multi-layer compound structure also can form rear formation in this insulating protective layer.The manufacture method of this crystal-coated light-emitting diodes can selectivity also comprise following steps: before this insulating protective layer forms, form a reflector on this semiconductor epitaxial multi-layer compound structure.

In the manufacture method of the above-mentioned crystal-coated light-emitting diodes of the present invention, the material of this insulating protective layer can be silicon nitride, silicon dioxide, insulation diamond like carbon or its combination, and it is the member that directly contacts and protect it to cover between isolated two members.

In addition, another purpose more of the present invention is that (the chip on board of encapsulating structure on a kind of chip board is being provided, COB), wherein the above-mentioned light-emitting diode with conductivity diamond like carbon layer of the present invention is electrically connected circuit board with compound crystal mode or routing mode, therefore the thermal expansion stress of each layer of light-emitting diode structure can be by the buffering of the diamond like carbon layer in its structure, and then make that on chip board, encapsulating structure integral body has better radiating efficiency, luminous school and life-span.

For reaching above-mentioned purpose, another aspect more of the present invention provides encapsulating structure on a kind of chip board (chip on board, COB), comprising: a circuit board; And the above-mentioned crystal-coated light-emitting diodes of the present invention, it is to be electrically connected this circuit board via this first electrode and this second electrode.

On said chip plate of the present invention in encapsulating structure, this circuit board can comprise an insulating barrier and a circuit substrate, wherein, the material of this insulating barrier can be insulating properties diamond like carbon, aluminium oxide, pottery, diamantiferous epoxy resin or its constituent, perhaps be covered with the metal material of above-mentioned insulating barrier for the surface, and this circuit substrate can be a metallic plate, a ceramic wafer or a silicon substrate.In addition, this circuit board surface also can selectivity also comprise a diamond like carbon layer, to increase radiating effect.

Description of drawings

Above-mentioned and other purpose and advantage of the present invention are not difficult to gain in-depth understanding from the detailed description and accompanying drawing of following selected embodiment, wherein:

Figure 1A to 1F shows the flowage structure schematic diagram of the preparation method of crystal-coated light-emitting diodes in the embodiment of the present invention one.

Fig. 2 shows the structural representation of the crystal-coated light-emitting diodes of the embodiment of the present invention two.

Fig. 3 shows the structural representation of the crystal-coated light-emitting diodes of the embodiment of the present invention three.

Fig. 4 shows the structural representation of the crystal-coated light-emitting diodes of the embodiment of the present invention four.

Fig. 5 shows the structural representation of encapsulating structure on the embodiment of the present invention five chips plates.

Embodiment

Be below by particular specific embodiment, embodiments of the present invention to be described, the personage who has the knack of this technology can understand other advantages of the present invention and effect easily by content disclosed in the present specification.The present invention also can be implemented or be used by other different specific embodiments, and the every details in this specification also can based on different viewpoints and application, be carried out various modifications and change under not departing from spirit of the present invention.

In embodiments of the invention, these accompanying drawings are the schematic diagram of simplification.Only these icons only show the element relevant with the present invention, and the aspect that its shown element is non-when be actual enforcement, component number, the shape equal proportion during its actual enforcement are one optionally to design, and its component placement kenel may be more complicated.

Embodiment one

Referring to figs. 1A to Fig. 1 F, it is the flowage structure schematic diagram that shows the preparation method of the present embodiment crystal-coated light-emitting diodes.

At first, as shown in Figure 1A, provide a substrate 40.Then, as shown in Figure 1B, form semiconductor extension multi-layer compound structure 41 on this substrate 40.This semiconductor epitaxial multi-layer compound structure 41 can comprise: one first semiconductor epitaxial layers 411, an active intermediate 412 and one second semiconductor epitaxial layers 413, wherein, this first semiconductor epitaxial layers 411, this active intermediate 412, with this second semiconductor epitaxial layers 413 are stacking settings, and this active intermediate 412 is folded between this first semiconductor epitaxial layers 411 and this second semiconductor epitaxial layers 413, and this active intermediate 412 is the surfaces that appear this first semiconductor epitaxial layers 411 with this second semiconductor epitaxial layers 413.In the present embodiment, the material of this semiconductor epitaxial multi-layer compound structure 41 is gallium nitride (GaN), and this first semiconductor epitaxial layers 411 is N-types, and this second semiconductor epitaxial layers 413 is P types.But, the applicable material of semiconductor epitaxial multi-layer compound structure of the present invention is not limited to this, can also use and select material commonly used in other this areas.In addition, can select on demand whether this active intermediate is set, in the present embodiment, this active intermediate 412 is multiple quantum well layer (multiple quantum well layer), converts the efficient of luminous energy in order to promote electric energy in light-emitting diode.

As shown in Fig. 1 C, on this second semiconductor epitaxial layers 413 surfaces of this semiconductor epitaxial multi-layer compound structure 41, form a reflector 42.in the present embodiment, indium tin oxide (indium tin oxide can be selected in this reflector 42, ITO), aluminum zinc oxide (aluminum zinc oxide, AZO), zinc oxide (ZnO), Graphene (graphene), aluminium, silver, nickel (Ni), cobalt (Co), palladium (Pd), platinum (Pt), gold (Au), zinc (Zn), tin (Sn), antimony (Sb), plumbous (Pb), copper (Cu), copper silver (CuAg), and nickeline (NiAg) institute cohort group is at least a, in other words it also can be multi-layer metal structure, except being used for reaching reflecting effect, also can reach the effectiveness that forms ohmic contact (ohmic contact).This forms the step in reflector, the technical field of the invention usually know the knowledgeable according to need selectivity carry out.

Then, as shown in Fig. 1 D, on these the first semiconductor epitaxial layers 411 surfaces and these 42 surfaces, reflector of this semiconductor epitaxial multi-layer compound structure 41, form respectively a first kind diamond/electric conducting material multi-layer compound structure 46 and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43.this first kind diamond/electric conducting material multi-layer compound structure 46 bores the layer laminate structure with the optional free conductive material layer of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43 and conduction class carbon, electric conducting material and diamond like carbon mixture, and electric conducting material and conductivity diamond like carbon mixture institute cohort group is at least a, wherein, the material of this conductive material layer or this electric conducting material is to select free indium tin oxide (indium tin oxide, ITO), aluminum zinc oxide (aluminum zinc oxide, AZO), zinc oxide (ZnO), Graphene (graphene), titanium (Ti), aluminium (Al), chromium (Cr), nickel (Ni), platinum (Pt), molybdenum (Mo), tungsten (W), silver (Ag), platinum (Pt), and golden (Au) institute cohort group is at least a.In the present embodiment, this first kind diamond/electric conducting material multi-layer compound structure 46 is that titanium conductive material layer, aluminium conductive material layer and diamond like carbon layer repeat laminated construction, and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43 is that titanium conductive material layer and diamond like carbon layer repeat laminated construction.

Then, as shown in Fig. 1 E, on this first kind diamond/electric conducting material multi-layer compound structure 46 surfaces and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43 surfaces, form respectively one first metal solder layer 47 and the second metal solder layer 44, wherein, the surface of the surface of this first metal solder layer 37 and this second metal solder layer 34 is to form a copline.In the present embodiment, this first metal solder layer 47 is to be made of with golden tin layer the gold layer with this second metal solder layer 44, and should gold tin layer be an eutectic conductive material layer.

At last; as shown in Fig. 1 F; form an insulating protective layer 45; cover the sidewall of this semiconductor epitaxial multi-layer compound structure 41 (that is this first semiconductor epitaxial layers 413, this active intermediate 412 and this second semiconductor epitaxial layers 413), this reflector 42, this first kind diamond/electric conducting material multi-layer compound structure 46, Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43, this first metal solder layer 47 and this second metal solder layer 44, and expose the surface of this first metal solder layer 47 and this second metal solder layer 44.the material of this insulating protective layer 25 can be selected free silicon nitride, silicon dioxide, and at least a in insulation diamond like carbon institute cohort group, it is this first semiconductor epitaxial layers 413 that covers for the protection of it, this second semiconductor epitaxial layers 413, this active intermediate 412, this reflector 42, this first kind diamond/electric conducting material multi-layer compound structure 46, Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43, this the first metal solder layer 47 and this second metal solder layer 44, and electrically isolated this first kind diamond/electric conducting material multi-layer compound structure 46 and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43.In the present embodiment, adopt silicon dioxide as the material of this insulating protective layer 45.This insulating protective layer 45 also can not cover and appear this first metal solder layer 47 and this second metal solder layer 44.

Accordingly, as shown in Fig. 1 F, the above-mentioned crystal-coated light-emitting diodes that makes 4, it comprises: a substrate 40; Semiconductor extension multi-layer compound structure 41, it is positioned at these substrate 40 tops and comprises one first semiconductor epitaxial layers 411, an active intermediate 412 and one second semiconductor epitaxial layers 413, wherein, this first semiconductor epitaxial layers 411, this active intermediate 412, with this second semiconductor epitaxial layers 413 are stacking settings, this active intermediate 412 is folded between this first semiconductor epitaxial layers 411 and this second semiconductor epitaxial layers 413; One reflector 42 is positioned at this second semiconductor epitaxial layers 413 surfaces of this semiconductor epitaxial multi-layer compound structure 41; One first kind diamond/electric conducting material multi-layer compound structure 46 contacts this first semiconductor epitaxial layers 411 surfaces of this semiconductor epitaxial multi-layer compound structure 41, with as one first electrode; One first metal solder layer 47 is positioned on this first kind diamond/electric conducting material multi-layer compound structure 46; One Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43 is positioned at 42 surfaces, this reflector and is electrically connected this second semiconductor epitaxial layers 413 of this semiconductor epitaxial multi-layer compound structures 41 via this reflector 42, with as one second electrode; One second metal solder layer 44 is positioned on this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43, and wherein, the surface of the surface of this second metal solder layer 44 and this first metal solder layer 47 is to form a copline; An and insulating protective layer 45; cover the sidewall of this first metal solder layer 47, the second metal solder layer 44, this first kind diamond/electric conducting material multi-layer compound structure 46, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43, this reflector 42, this first semiconductor epitaxial layers 411, this second semiconductor epitaxial layers 413 and this active intermediate 412, with electrically isolated this first kind diamond/electric conducting material multi-layer compound structure 46 and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 43.

Embodiment two

With reference to figure 2, it is the structural representation that shows the present embodiment crystal-coated light-emitting diodes.

As shown in Figure 2; crystal-coated light-emitting diodes, it comprises: a substrate 50, semiconductor extension multi-layer compound structure 51, a reflector 52, a first kind diamond/electric conducting material multi-layer compound structure 56, an Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53, one first metal solder layer 57, one second metal solder layer 54 and an insulating protective layer 55.

This semiconductor epitaxial multi-layer compound structure 51 is positioned at these substrate 50 surfaces and comprises one first semiconductor epitaxial layers 511, an active intermediate 512 and one second semiconductor epitaxial layers 513, wherein, this first semiconductor epitaxial layers 511, this active intermediate 512, with this second semiconductor epitaxial layers 513 are stacking settings, this active intermediate 512 is folded between this first semiconductor epitaxial layers 511 and this second semiconductor epitaxial layers 513, and this reflector 52 is positioned at this second semiconductor epitaxial layers 513 surfaces of this semiconductor epitaxial multi-layer compound structure 51.

This first kind diamond/electric conducting material multi-layer compound structure 56 comprises one first conductive material layer 561 and a first kind diamond layer 562, and this first conductive material layer 561 is stacking settings with this first kind diamond layer 562, wherein, this first conductive material layer 561 contacts as one first electrode and with this first semiconductor epitaxial layers 511.On the other hand, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53, comprise one second conductive material layer 531 and an Equations of The Second Kind diamond layer 532, and this second conductive material layer 531 is stacking settings with this Equations of The Second Kind diamond layer 532, wherein, this second conductive material layer 531 is arranged at this 52 surfaces, reflector, with as one first electrode, and is electrically connected by this reflector 52 and this second semiconductor epitaxial layers 513.In addition, this the second conductive material layer 531 surfaces of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53 are that this first conductive material layer 561 surfaces with this first kind diamond/electric conducting material multi-layer compound structure 56 form coplines, and this Equations of The Second Kind diamond layer 532 surfaces of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53 also form coplines with this first kind diamond layer 562 surfaces of this first kind diamond/electric conducting material multi-layer compound structure 56.

This first metal solder layer 57 is positioned on this first kind diamond/electric conducting material multi-layer compound structure 56, this the second metal solder layer 54 is positioned on this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53, and the surface of the surface of this second metal solder layer 54 and this first metal solder layer 57 is to form a copline.

This insulating protective layer 55 covers the sidewall of this first metal solder layer 57, the second metal solder layer 54, this first kind diamond/electric conducting material multi-layer compound structure 56, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53, this reflector 52, this second semiconductor epitaxial layers 513 and this active intermediate 512; with electrically isolated this first kind diamond/electric conducting material multi-layer compound structure 56 and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 53, in other words namely avoid the first electrode directly contact and be short-circuited with the second electrode.

Embodiment three

With reference to figure 3, it is the structural representation that shows the present embodiment crystal-coated light-emitting diodes.

As shown in Figure 3; crystal-coated light-emitting diodes, it comprises: a substrate 60, semiconductor extension multi-layer compound structure 61, a reflector 62, a first kind diamond/electric conducting material multi-layer compound structure 66, an Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 63, one first metal solder layer 67, one second metal solder layer 64 and an insulating protective layer 65.

This semiconductor epitaxial multi-layer compound structure 61 is positioned at these substrate 60 surfaces and comprises one first semiconductor epitaxial layers 611, an active intermediate 612 and one second semiconductor epitaxial layers 613, wherein, this first semiconductor epitaxial layers 611, this active intermediate 612, with this second semiconductor epitaxial layers 613 are stacking settings, this active intermediate 612 is folded between this first semiconductor epitaxial layers 611 and this second semiconductor epitaxial layers 613, and this reflector 62 is positioned at this second semiconductor epitaxial layers 613 surfaces of this semiconductor epitaxial multi-layer compound structure 61.

This first kind diamond/electric conducting material multi-layer compound structure 66 comprises one first conductive material layer 661 and a first kind diamond layer 662, and this first conductive material layer 661 is stacking settings with this first kind diamond layer 662, wherein, this first conductive material layer 661 contacts as one first electrode and with this first semiconductor epitaxial layers 611.On the other hand, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 63, comprise one second conductive material layer 631 and an Equations of The Second Kind diamond layer 632, and this second conductive material layer 631 is stacking settings with this Equations of The Second Kind diamond layer 632, wherein, this second conductive material layer 631 is arranged at this 62 surfaces, reflector, with as one first electrode, and is electrically connected by this reflector 62 and this second semiconductor epitaxial layers 613.In addition, this Equations of The Second Kind diamond layer 632 surfaces of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 63 also form coplines with this first kind diamond layer 662 surfaces of this first kind diamond/electric conducting material multi-layer compound structure 66.

This first metal solder layer 67 is positioned on this first kind diamond/electric conducting material multi-layer compound structure 66, this the second metal solder layer 64 is positioned on this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 63, and the surface of the surface of this second metal solder layer 64 and this first metal solder layer 67 is to form a copline.

This insulating protective layer 65 covers the sidewall of this first metal solder layer 67, the second metal solder layer 64, this first kind diamond/electric conducting material multi-layer compound structure 66, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 63, this reflector 62, this second semiconductor epitaxial layers 613 and this active intermediate 612; with electrically isolated this first kind diamond/electric conducting material multi-layer compound structure 66 and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 63, in other words namely avoid the first electrode directly contact and be short-circuited with the second electrode.

Embodiment four

With reference to figure 4, it is the structural representation that shows the present embodiment crystal-coated light-emitting diodes.

As shown in Figure 4; crystal-coated light-emitting diodes, it comprises: a substrate 30, semiconductor extension multi-layer compound structure 31, a reflector 32, a first kind diamond/electric conducting material multi-layer compound structure 36, an Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 33, one first metal solder layer 37, one second metal solder layer 34 and an insulating protective layer 35.

This semiconductor epitaxial multi-layer compound structure 31 is positioned at these substrate 30 surfaces and comprises one first semiconductor epitaxial layers 311, an active intermediate 312 and one second semiconductor epitaxial layers 313, wherein, this first semiconductor epitaxial layers 311, this active intermediate 312, with this second semiconductor epitaxial layers 313 are stacking settings, this active intermediate 312 is folded between this first semiconductor epitaxial layers 311 and this second semiconductor epitaxial layers 313, and this reflector 32 is positioned at this second semiconductor epitaxial layers 313 surfaces of this semiconductor epitaxial multi-layer compound structure 31.

This first kind diamond/electric conducting material multi-layer compound structure 36 comprises one first conductive material layer 361 and a first kind diamond layer 362, and this first conductive material layer 361 is stacking settings with this first kind diamond layer 362, wherein, this first conductive material layer 361 contacts as one first electrode and with this first semiconductor epitaxial layers 311.On the other hand, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 33, comprise one second conductive material layer 331 and an Equations of The Second Kind diamond layer 332, and this second conductive material layer 331 is stacking settings with this Equations of The Second Kind diamond layer 332, wherein, this second conductive material layer 331 is arranged at this 32 surfaces, reflector, with as one first electrode, and be electrically connected by this reflector 32 and this second semiconductor epitaxial layers 313, and these Equations of The Second Kind diamond layer 332 second adjacent conductive material layers 331 of contact two make two adjacent light-emitting diode series connection.

This first metal solder layer 37 is positioned on this first kind diamond/electric conducting material multi-layer compound structure 36, this the second metal solder layer 34 is positioned on this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 33, and part surface formation one copline of the part of this first metal solder layer 37 surface and this second metal solder layer 34.

this insulating protective layer 35 covers this first metal solder layer 37, the second metal solder layer 34, this first kind diamond/electric conducting material multi-layer compound structure 36, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 33, this reflector 32, this second semiconductor epitaxial layers 313, and the sidewall of this active intermediate 312, with electrically isolated this first kind diamond/electric conducting material multi-layer compound structure 36 and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure 33, and electrically isolated this Equations of The Second Kind diamond layer 332 and the first conductive material layer 361 therebetween that connects two adjacent the second conductive material layers 331, in other words namely avoid the first electrode directly contact and be short-circuited with the second electrode.

Embodiment five

With reference to figure 5, it is the structural representation of encapsulating structure on the chip board of the present embodiment.

As shown in Figure 5, on chip board, encapsulating structure comprises: a circuit board 7; And the prepared crystal-coated light-emitting diodes 4 of above-described embodiment one, it is to be electrically connected this circuit board 7 via this first metal solder layer 47 and this second metal solder layer 44, wherein, this circuit board 7 comprises an insulating barrier 71, a circuit substrate 70 and electric connection pad 73, the mixture of the optional free diamond like carbon of the material of this insulating barrier 71, aluminium oxide, pottery, diamantiferous epoxy resin or above-mentioned material, this circuit substrate 70 are a metallic plate, a ceramic wafer or a silicon substrate.

In encapsulating structure, can utilize the scolder 72 that is formed at electric connection pad 73 surfaces on this chip board, by covering crystal type, make this first metal solder layer 47 and this second metal solder layer 44 and the electric connection pad 73 of this circuit board 7 reach electric connection.

Accordingly, (the chip on board of encapsulating structure on said chip plate of the present invention, COB) in, the thermal expansion stress of each layer of light-emitting diode structure can be by the diamond like carbon layer in its structure buffering, and then make that on chip board, encapsulating structure integral body has better radiating efficiency, luminous school and life-span.And on said chip plate of the present invention, the suitable light-emitting diode that uses in encapsulating structure, be not limited only to the prepared crystal-coated light-emitting diodes of above-described embodiment one, also can use any crystal-coated light-emitting diodes of the present invention.

Accordingly, crystal-coated light-emitting diodes of the present invention has the structural design of buffering thermal expansion coefficient difference (coefficient thermal expansion mismatch), can continue to make heat loss in the process of light-emitting diode running generation heat; Impel overall structure to produce thermal expansion even there is the part heat not have to scatter and disappear in the self-luminous diode, the diamond like carbon that wherein arranges/electric conducting material multi-layer compound structure is thermal stress corresponding to available buffer also, and protect injury-free.

The described embodiment in top gives an example for convenience of description, and the interest field that the present invention advocates should be as the criterion so that the claim scope is described certainly, but not only limits to the described embodiment in top.

Claims

1. crystal-coated light-emitting diodes comprises:

One substrate;

Semiconductor extension multi-layer compound structure, it is positioned at this substrate top and comprises one first semiconductor epitaxial layers and one second semiconductor epitaxial layers, and wherein, this first semiconductor epitaxial layers and this second semiconductor epitaxial layers are stacking settings;

One first kind diamond/electric conducting material multi-layer compound structure, be positioned at above this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, and be electrically connected this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, with as one first electrode;

One Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, be positioned at above this second semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, and be electrically connected this second semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure, with as one second electrode; And

One insulating protective layer covers the sidewall of this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure and the sidewall of this second semiconductor epitaxial layers.

2. crystal-coated light-emitting diodes as claimed in claim 1, wherein, this semiconductor epitaxial multi-layer compound structure also comprises an active intermediate, this active intermediate is folded between this first semiconductor epitaxial layers and this second semiconductor epitaxial layers.

3. crystal-coated light-emitting diodes as claimed in claim 1, wherein, this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure select free conductive material layer and conduction class carbon to bore at least a of layer laminate structure, electric conducting material and diamond like carbon mixture sandwich construction and electric conducting material and conductivity diamond like carbon mixture sandwich construction institute cohort group.

4. crystal-coated light-emitting diodes as claimed in claim 3, wherein, the material of this conductive material layer or this electric conducting material is selected at least a of free indium tin oxide, aluminum zinc oxide, zinc oxide, Graphene, titanium, aluminium, chromium, nickel, platinum, molybdenum, tungsten, silver, platinum and golden institute cohort group.

5. crystal-coated light-emitting diodes as claimed in claim 3, wherein, the conductive material layer surface of the conductive material layer of this first kind diamond/electric conducting material multi-layer compound structure surface and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure forms a copline.

6. crystal-coated light-emitting diodes as claimed in claim 3, wherein, the conduction diamond like carbon layer of this first kind diamond/electric conducting material multi-layer compound structure surface and the surperficial copline that forms of the conduction diamond like carbon layer of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure.

7. crystal-coated light-emitting diodes as claimed in claim 1, wherein, the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure forms a copline.

8. crystal-coated light-emitting diodes as claimed in claim 1, also comprise: one first metal solder layer is positioned on this first kind diamond/electric conducting material multi-layer compound structure; And one second metal solder layer, be positioned on this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, wherein, the surface of the surface of this second metal solder layer and this first metal solder layer forms a copline.

9. crystal-coated light-emitting diodes as claimed in claim 8; wherein, the surface of the surface of the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, this second metal solder layer or the first metal solder layer higher or lower than this insulating protective layer the surface or with its formation one copline.

10. crystal-coated light-emitting diodes as claimed in claim 1, also comprise a reflector, is folded between this semiconductor epitaxial multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure.

11. crystal-coated light-emitting diodes as claimed in claim 1, wherein, the material of this insulating protective layer is selected at least a in free silicon nitride, silicon dioxide and insulation diamond like carbon institute cohort group.

12. crystal-coated light-emitting diodes as claimed in claim 1, wherein, this first semiconductor epitaxial layers and this first kind diamond/electric conducting material multi-layer compound structure are N-types, and this second semiconductor epitaxial layers and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure are the P types.

13. the manufacture method of a crystal-coated light-emitting diodes comprises the following steps:

One substrate is provided;

In this substrate top formation semiconductor extension multi-layer compound structure, wherein, this semiconductor epitaxial multi-layer compound structure comprises one first semiconductor epitaxial layers and one second semiconductor epitaxial layers, and wherein, this first semiconductor epitaxial layers and this second semiconductor epitaxial layers are stacking settings;

Form respectively a first kind diamond/electric conducting material multi-layer compound structure and Equations of The Second Kind diamond/electric conducting material multi-layer compound structure above this first semiconductor epitaxial layers and this second semiconductor epitaxial layers; And

Form an insulating protective layer, this insulating protective layer covers the sidewall of this first semiconductor epitaxial layers of this semiconductor epitaxial multi-layer compound structure and the sidewall of this second semiconductor epitaxial layers.

14. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13, wherein, this semiconductor epitaxial multi-layer compound structure also comprises an active intermediate, and this active intermediate is folded between this first semiconductor epitaxial layers and this second semiconductor epitaxial layers.

15. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 14, wherein, this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure select free conductive material layer and conduction class carbon to bore at least a of layer laminate structure, electric conducting material and diamond like carbon mixture sandwich construction and electric conducting material and conductivity diamond like carbon mixture sandwich construction institute cohort group.

16. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 15, wherein, the material of this conductive material layer or this electric conducting material is selected at least a of free indium tin oxide, aluminum zinc oxide, zinc oxide, Graphene, titanium, aluminium, chromium, nickel, platinum, molybdenum, tungsten, silver, platinum and golden institute cohort group.

17. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 15, wherein, the conductive material layer of this first kind diamond/electric conducting material multi-layer compound structure surface and the surperficial copline that forms of the conductive material layer of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure.

18. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 15, wherein, the conduction diamond like carbon layer of this first kind diamond/electric conducting material multi-layer compound structure surface and the surperficial copline that forms of the conduction diamond like carbon layer of this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure.

19. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13, wherein, the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure forms a copline.

20. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13, further comprising the steps of: on this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, form respectively one first metal solder layer and one second metal solder layer, wherein, the surface of the surface of this second metal solder layer and this first metal solder layer forms a copline.

21. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 20; wherein, the surface of the surface of the surface of the surface of this first kind diamond/electric conducting material multi-layer compound structure, this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure, this second metal solder layer or the first metal solder layer higher or lower than this insulating protective layer the surface or with its formation one copline.

22. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 20, wherein, this first kind diamond/electric conducting material multi-layer compound structure and this first metal solder layer are to form after insulating protective layer forms or before.

23. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13, wherein, this first kind diamond/electric conducting material multi-layer compound structure and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure form simultaneously or separately form.

24. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13 also comprises following steps: before the Equations of The Second Kind diamond/the electric conducting material multi-layer compound structure forms, form a reflector in this on this semiconductor epitaxial multi-layer compound structure.

25. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 22, wherein, this first kind diamond/electric conducting material multi-layer compound structure forms rear formation in this insulating protective layer.

26. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 25 also comprises following steps: before this insulating protective layer forms, form a reflector on this semiconductor epitaxial multi-layer compound structure.

27. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13, wherein, the material of this insulating protective layer is silicon nitride, silicon dioxide, insulation diamond like carbon or its combination.

28. the manufacture method of crystal-coated light-emitting diodes as claimed in claim 13, wherein, this first semiconductor epitaxial layers and this first kind diamond/electric conducting material multi-layer compound structure are N-types, and this second semiconductor epitaxial layers and this Equations of The Second Kind diamond/electric conducting material multi-layer compound structure are the P types.

29. encapsulating structure on a chip board comprises:

One circuit board; And

Just like the described crystal-coated light-emitting diodes of any one in claim 1 to the 12, it is to be packaged in this circuit board via this first metal solder layer and this second metal solder layer.

30. as claimed in claim 29ly cover encapsulating structure on chip board, wherein, this circuit board comprises an insulating barrier and a circuit substrate, and the material of this insulating barrier is select free diamond like carbon, aluminium oxide, pottery and diamantiferous epoxy resin institute cohort group at least a.

31. as claimed in claim 30ly cover encapsulating structure on chip board, wherein, this circuit substrate is a metallic plate, a ceramic wafer or a silicon substrate.