CN109037260A - Micro- light-emitting diode display module and its manufacturing method - Google Patents
Micro- light-emitting diode display module and its manufacturing method Download PDFInfo
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- CN109037260A CN109037260A CN201710431792.1A CN201710431792A CN109037260A CN 109037260 A CN109037260 A CN 109037260A CN 201710431792 A CN201710431792 A CN 201710431792A CN 109037260 A CN109037260 A CN 109037260A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L27/00—Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate
- H01L27/15—Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including semiconductor components having potential barriers, specially adapted for light emission
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Abstract
The present invention is about a kind of micro- light-emitting diode display module and its manufacturing method.Micro- light-emitting diode display module, including a driving chip block, a light emitting diode block, a circuit board and a chromatograph.The driving chip block has multiple pixel electrodes.The light emitting diode block is set to the driving chip block, and has two semiconductor layers and multiple grooves, which is electrically connected the grade pixel electrodes, another one connects a light transmission conductive layer.The grade grooves define multiple micro- light-emitting diode pixels arranged in arrays, and respectively the groove at least penetrates the luminescent layer and the semiconductor layer, respectively the corresponding pixel electrode of micro- light-emitting diode pixel.The circuit board is electrically connected the driving chip block, which is set to the light transmission conductive layer.
Description
Technical field
The present disclosure generally relates to a kind of light emitting diodes, are especially a kind of micro- light-emitting diode display module and its manufacturing method
Background technique
Conventional light emitting diodes (Light Emitting Diode, LED) are chiefly used in LCD (Liquid Crystal
Device it backlight) or is directly used as light emitting pixel point, however the latter is chiefly used in due to the factor of lack of resolution
Large-scale advertisement lamp plate, it is less to be applied to consumer electrical product.
Start to develop a kind of new micro- light emitting diode of display technology-(Micro LED) in recent years, mainly by LED into
Row microminiaturization, filming and array, size are micron order.Micro LED is in addition to having previous inorganic LED's
Feature-high color saturation, high brightness, is swift in response at high efficiency, and when being applied to display equipment, it is only necessary to through spontaneous
Light is that can reach the purpose of display without backlight, and more energy conservation, mechanism be simple, the advantages such as frivolous, it is most important that, micro- hair
Optical diode also has the characteristic of ultrahigh resolution.
In addition to this, for micro- light emitting diode compared to Organic Light Emitting Diode, color is easier accurately adjustment, and has
There are longer luminescent lifetime, higher brightness, less image residue and there is preferable stability of material.
It is general to utilize such as Taiwan Patent TW 201640697A or paper " Zhao Jun Liu et al., Monolithic
LED Microdisplay on Active Matrix Substrate Using Flip-Chip Technology,IEEE
Micro- luminous two described in Journal Of Selected Topics In Quantum Electronics, pp.1-5 (2009) "
Pole pipe is come when manufacturing display module, it usually needs is produced in batches micro- light emitting diode of different colours, then by its a large amount of turns in batches
It is attached in control circuit board, recycles physical deposition processing procedure that protective layer and electrode are set, be packaged again later to complete
One micro- light-emitting diode display module.
However, during being posted micro- light emitting diodes of different colours in batches, because of the body of each micro- light emitting diode
Product is very tiny, and is not easy to shift and (picks up and place) and wiring is connect (Wire Bonding), so generation yield it is bad,
The problems such as manufacturing slow and cost consumption.
Summary of the invention
Multiple micro- light emitting diodes can be generated in array fashion and are set on driving chip block by the present invention, be made
Pixel electrode on driving chip drives individually each micro- light-emitting diode pixel, and uses light transmission conductive layer or micro- luminous two
Structure (such as semiconductor layer) inside pole pipe as multiple pixels common electrode, in this way, which each micro- shines two
Pole pipe can address control via driving chip and be operated alone and light.
In addition, in order to make micro- light-emitting diode display module can with total colouring, can in addition be arranged RGB (Red, Green,
Blue) chromatograph, such as setting RGB filter or spraying quantum dot.It can be made through such structure high-resolution micro- luminous
Diode display module;And it can reduce and generate the problems such as yield is bad in transfer process.
In order to achieve the above objectives, the present invention provides a kind of manufacturing method of micro- light-emitting diode display module, including with
Lower step: a LED wafer and one drive circuit wafer are prepared, wherein the partial region circle of the LED wafer
It is set to a light emitting diode block, the region deviding of a chip size of the driving circuit wafer is a driving chip block,
In the light emitting diode block have one first semiconductor layer, a luminescent layer and one second semiconductor layer, the luminescent layer be set to should
Between first semiconductor layer and second semiconductor layer, which connects a substrate, this first and this second half lead
Body layer one of them system is n type semiconductor layer, another one system is p type semiconductor layer;Engage the light emitting diode block and the drive
Dynamic chip block, wherein multiple pixel electrodes of second semiconductor layer and the driving chip block are electrically connected;Remove the base
Material;The light emitting diode block is etched, and forms staggered multiple grooves, wherein the grade grooves define arranged in arrays
Multiple micro- light-emitting diode pixels, each corresponding pixel electrode of the micro- light-emitting diode pixel;One light transmission conductive layer is set
In on first semiconductor layer, wherein the light transmission conductive layer has the common electrode for corresponding to micro- light-emitting diode pixel such as this;If
A chromatograph is set in the light transmission conductive layer, wherein the chromatograph system is RGB color layer.
In order to achieve the above objectives, the present invention provides a kind of micro- light-emitting diode display module, comprising: a driving chip area
Block has multiple pixel electrodes;One light emitting diode block is set to the driving chip block, and has two semiconductor layers and more
A groove, the luminescent layer be located at this first and second semiconductor layer between, the two semiconductor layers one of them be electrically connected should
Equal pixel electrodes, another one connect a light transmission conductive layer, and the light emitting diode block is between the light transmission conductive layer and the driving core
Between piece block, which defines multiple micro- light-emitting diode pixels arranged in arrays, and respectively the groove at least penetrates this
The semiconductor layer of luminescent layer and the pixel electrodes such as connect this, each corresponding pixel electrode of micro- light-emitting diode pixel, this two
Semiconductor layer one of them system is n type semiconductor layer, another one system is p type semiconductor layer;One circuit board is electrically connected the driving
Chip block, and the drive circuit chip block is between the light emitting diode block and the circuit board;One chromatograph, being set to should
Light transmission conductive layer, the light transmission conductive layer are located between the chromatograph and the light emitting diode block, which is RGB color layer.
Detailed description of the invention
Fig. 1 system is the schematic diagram of LED wafer of the invention.
Fig. 2 system is the schematic diagram of light emitting diode block of the invention.
Fig. 3 system is the diagrammatic cross-section of light emitting diode block of the invention.
Fig. 4 system is the schematic diagram of driving circuit wafer of the invention.
Fig. 5 system is the schematic diagram of driving chip block of the invention.
Fig. 6 A to Fig. 6 I system is the schematic diagram of first embodiment and other alternate embodiments.
Fig. 7 A to Fig. 7 L system is the schematic diagram of second embodiment and other alternate embodiments.
Fig. 8 A to Fig. 8 G system is the schematic diagram of 3rd embodiment and other alternate embodiments.
Fig. 9 A to Fig. 9 H system is the schematic diagram of fourth embodiment and other alternate embodiments.
Figure 10 to 11 is the schematic diagram of setting chromatography step of the invention.
Figure 10 A is the partial enlarged view of chromatograph of the invention.
Symbol description
110: LED wafer 800: micro- light-emitting diode display module
111: light emitting diode block 810: LED wafer
120: driving circuit wafer 811: light emitting diode block
121: driving chip block 812: substrate
122: pixel electrode 813:N type semiconductor layer
600: micro- light-emitting diode display module 814:N type doped layer
610: LED wafer 815:N type buffer layer
611: light emitting diode block 816: luminescent layer
612: substrate 817:P type semiconductor layer
613:N type semiconductor layer 818:P type doped layer
614:N type doped layer 819:P type buffer layer
615:N type buffer layer 821: driving chip block
616: luminescent layer 830: micro- light-emitting diode pixel
617:P type semiconductor layer 831: groove
618:P type doped layer 832: non-conductive adhesive
619:P type buffer layer 840: light transmission conductive layer
620: driving circuit wafer 850: conducting resinl
621: driving chip block 860: circuit board
630: micro- light-emitting diode pixel 900: micro- light-emitting diode display module
631: groove 910: LED wafer
632: non-conductive adhesive 911: light emitting diode block
640: light transmission conductive layer 912: sapphire substrate
650: conducting resinl 913:N type semiconductor layer
660: circuit board 914:N type doped layer
700: micro- light-emitting diode display module 915:N type buffer layer
710: LED wafer 916: luminescent layer
711: light emitting diode block 917:P type semiconductor layer
712: substrate 918:P type doped layer
713:N type semiconductor layer 919:P type buffer layer
714:N type doped layer 920: driving circuit wafer
715:N type buffer layer 921: driving chip block
716: luminescent layer 930: micro- light-emitting diode pixel
717:P type semiconductor layer 931: groove
718:P type doped layer 932: non-conductive adhesive
719:P type buffer layer 950: conducting resinl
720: driving circuit wafer 960: circuit board
721: driving chip block 970: protrusion
730: micro- light-emitting diode pixel 170: chromatograph
731: groove 171: pixel region
732: non-conductive adhesive 172: pixel region
740: light transmission conductive layer 173: pixel region
741: light transmission conductive layer 180: chromatograph
750: conducting resinl
760: circuit board
Specific embodiment
Hereinafter the possible state sample implementation of the present invention is only illustrated with embodiment, is so not intended to limit the invention and to be protected
Scope, conjunction are first chatted bright.
Fig. 1 to 5 is please referred to, shows LED wafer 110, the light-emitting diodes of just required preparation produced by the present invention
Area under control block 111, driving circuit wafer 120 and driving chip block 121.Various embodiments for ease of description, specification not
Before clearly stating, light emitting diode block 111 can be represent LED wafer 110 partial region (also with this shine
The other parts of diode wafer 110 are integrally connected), can also cut isolated area from the LED wafer 110
Block;The driving chip block 121 can be represent the driving circuit wafer 120 partial region (also with the driving circuit wafer
120 other parts are integrally connected) or from driving chip made of the driving circuit wafer 120 cutting separation.The respectively drive
There are multiple pixel electrodes 122 on dynamic chip block 121, respectively the pixel electrode 122 can independently drive a micro- light emitting diode picture
Element.
That is, the light emitting diode block 111 is cut separation and/or the drive from the LED wafer 110
Dynamic chip block 121 cuts isolated time point from the driving circuit wafer 120, can prepare the LED wafer and
The step of driving circuit wafer and the step of the driving chip block and a circuit board are electrically connected between whenever
All may be used.
In the present invention, the LED wafer 110 is being made and when the driving circuit wafer 120, it also can there are portions
Point white space (such as partial region is not provided with semiconductor layer, luminescent layer, pixel electrode), for be arranged later electrode connection gasket or
Multiple tracks cutting process is used.
In addition, the part lines in each figure, are only to indicate the follow-up process such as imaginary line of etching or cutting, reality
On can not have those lines.
It please refers to Fig. 6 C, 6D, 6E, 6F, 6G, 6H, shows the first embodiment of the present invention, the micro- of the present embodiment shines two
The manufacturing method of pole pipe display module 600 includes the following steps.
At the beginning, a LED wafer 610 and one drive circuit wafer 620 are prepared.The LED wafer 610
Partial region be defined as a light emitting diode block 611, the region deviding of a chip size of the driving circuit wafer 620 is
One driving chip block 621, wherein the light emitting diode block 611 has one first semiconductor layer, a luminescent layer 616 and one
Second semiconductor layer, the luminescent layer 616 are set between first semiconductor layer and second semiconductor layer, first semiconductor layer
Connect a substrate 612.More particularly, this first and the second semiconductor layer one of them system be n type semiconductor layer, another one
System is p type semiconductor layer, and in the present embodiment, which is n type semiconductor layer 613, the second semiconductor series of strata
For p type semiconductor layer 617.Wherein, which includes a n-type doping layer 614 and a N-type buffer layer 615, the N
Type doped layer 614 is located between the N-type buffer layer 615 and the luminescent layer 616.The p type semiconductor layer 617 further includes that a p-type is mixed
Diamicton 618 and a p-type buffer layer 619, the p-type doped layer 618 are located between the p-type buffer layer 619 and the luminescent layer 616, in
Some embodiments can also not have N-type or p-type buffer layer.Furtherly, the driving chip block 621 have it is multiple can be only
The pixel electrode and integrated circuit of vertical driving.614 system of n-type doping layer is the cathode semiconductor layer rich in electronics, which mixes
618 system of diamicton is the positive semiconductor layer rich in electric hole.And the N-type and the p-type buffer layer 615,619 are the n-type doping layers
The transition zone that pole 614 and the p-type doped layer 618 are connected with foreign material.
Then, Fig. 6 C, 6D are please referred to, which is engaged with the driving chip block 621, the p-type
Multiple pixel electrodes of semiconductor layer 617 and the driving chip block 621 are electrically connected.Preferably, to avoid influencing material
Matter, the light emitting diode block 611 and 621 system of driving chip block are with the low-temperature mixed interconnection technique lower than 200 degree Celsius
It is engaged, binds the pixel electrode of the light emitting diode block 611 and the driving chip block 621, it will be understood that, also
It can be additionally provided with electrode connection gasket, in order to bind or conductive.It is noted that in the present embodiment, the light emitting diode block 611
And 621 system of driving chip block is to have cut isolated area from the LED wafer and the driving circuit wafer respectively
Block just carries out this engagement step later.In addition, in another embodiment, it, also can be by entire LED wafer 610 such as Fig. 6 A
It is engaged with driving circuit wafer 620;It or is, such as Fig. 6 B, first to isolate the light-emitting diodes from LED wafer cutting
Area under control block 611, then the light emitting diode block 611 is bonded to the driving circuit wafer 620.
Then Fig. 6 E is please referred to, substrate 612 is removed, and etches the light emitting diode block 611, and forms staggered row
Multiple grooves 631 of column, the grade grooves 631 define multiple micro- light-emitting diode pixels 630 (micro- luminous two arranged in arrays
Pole pipe array), respectively micro- light-emitting diode pixel 630 corresponds to the pixel electrode, in this way, can pass through respectively pixel electricity
Extremely individually supply electricity to corresponding micro- light-emitting diode pixel 630.It is noted that each micro- light-emitting diode pixel 630
Size be usually be micron-sized.
Then, Fig. 6 F is please referred to, non-conductive adhesive 632 is injected to the grooves 631 such as this, to increase micro- light emitting diode picture such as this
Structural strength between element 630.It, also can be without this step in other embodiments.
Next, please referring to Fig. 6 G, a light transmission conductive layer 640 is set on the n type semiconductor layer 613.More particularly,
The light transmission conductive layer 640 includes a glassy layer for being coated with an ITO conductive film, the ITO conductive film and respectively micro- light emitting diode
Pixel 630 is electrically connected, which is the common electrode for corresponding to micro- light-emitting diode pixel 630 such as this.Also, it should
Light transmission conductive layer 640 is electrically connected the driving chip block 621 by a conducting resinl 650 (or being other conductors).Through this
Potential difference between ITO conductive film and the equal pixel electrodes, i.e., controllable respectively micro- light-emitting diode pixel 630 are shinny.
Then, Fig. 6 H is please referred to, by the driving chip block 621 and a circuit board 660 (printed circuit board or flexible circuit
Plate) it is electrically connected, furtherly, which is set on the circuit board 660, and engages through routing
The mode of (Wire Bonding) is electrically connected the driving chip block 621 and the circuit board 660.It is noted that carrying out
When this step, the driving chip block 621 and the light emitting diode block 611 be all from the driving circuit wafer and this shine
The block (being independent light-emitting diode pixel array and driving chip) of separation is cut on diode wafer.In another reality
It applies in example, such as Fig. 6 I, which can also be not connected to the driving chip block 621, and be to connect the light transmission conductive layer
640 with the circuit board 660.In some embodiments, it can be also not provided with conducting resinl, and the ITO conductive film is electrically connected other
External power supply can make each micro- light emitting diode picture as long as having potential difference between the ITO conductive film and the pixel electrode
Element is shinny.
By above-mentioned steps, that is, produce micro- light-emitting diode display module 600 as shown in figure 6h.Micro- light-emitting diodes
Pipe display module includes the driving chip block 621, the light emitting diode block 611, the light transmission conductive layer 640 and the circuit
Plate 660.The driving chip block 621 has multiple pixel electrode.The light emitting diode block 611 is set to the driving chip area
On block 621.The light emitting diode block 611 has first semiconductor layer, the luminescent layer 616, second semiconductor layer and is somebody's turn to do
Multiple grooves 631.The luminescent layer 616 be located at this first and second semiconductor layer between, second semiconductor layer be electrically connected
The equal pixel electrodes, the grade grooves 631 define multiple micro- light-emitting diode pixel 630 arranged in arrays, respectively the groove
631 penetrate first semiconductor layer, second semiconductor layer and the luminescent layer 616.Respectively micro- light-emitting diode pixel 630 is corresponding
One pixel electrode, this first and the second semiconductor layer one of them system is n type semiconductor layer 613, another one system is p-type half
Conductor layer 617.Non-conductive adhesive 632 is respectively filled in the groove 631.
The light transmission conductive layer 640 is set to the light emitting diode block 611 and connects first semiconductor layer, the light-emitting diodes
Area under control block 611 is between the light transmission conductive layer 640 and the driving chip block 621.The circuit board 660 is electrically connected the driving
Chip block 621, and the driving chip block 621 is between the light emitting diode block 611 and the circuit board 660.This is thoroughly
A conducting resinl 650 is equipped between optical conductive layer 640 and the driving chip block 621, which is electrically connected this thoroughly
Optical conductive layer 640 and the driving chip block 621.The light transmission conductive layer 640 includes the glass for being coated with an ITO conductive film
Layer, the ITO conductive film are electrically connected with respectively micro- light-emitting diode pixel 630.It also can be in this such as Fig. 6 I in another embodiment
The conducting resinl 650 is equipped between light transmission conductive layer 640 and the driving chip block 621, which is electrically connected this
Light transmission conductive layer 640 and the driving chip block 621.
Fig. 7 A, 7B, 7E, 7F, 7G, 7H, 7I are please referred to, shows the second embodiment of the present invention, micro- hair of the present embodiment
The manufacturing method of optical diode display module 700 includes the following steps.
At the beginning, a LED wafer 710 and one drive circuit wafer 720 are prepared.The LED wafer 710
Partial region be defined as a light emitting diode block 711, the region deviding of a chip size of the driving circuit wafer 720 is
One driving chip block 721, wherein the light emitting diode block 711 has one first semiconductor layer, a luminescent layer 716 and one
Second semiconductor layer, the luminescent layer 716 are set between first semiconductor layer and second semiconductor layer, first semiconductor layer
A substrate 712 is connected, this first and the second semiconductor layer one of them system is n type semiconductor layer, another one system is that p-type is partly led
Body layer.More particularly, which is n type semiconductor layer 713, which is P-type semiconductor
Layer 717.Wherein, which includes a n-type doping layer 714 and a N-type buffer layer 715, the n-type doping layer 714
Between the N-type buffer layer 715 and the luminescent layer 716.The p type semiconductor layer 717 further includes a p-type doped layer 718 and a P
Type buffer layer 719, the p-type doped layer 718 are located between the p-type buffer layer 719 and the luminescent layer 716, in some embodiments, also
Can not have N-type or p-type buffer layer.
Fig. 7 A is please referred to, the light emitting diode block 711 is etched, and forms staggered multiple grooves 731, the equal ditches
Slot 731 defines multiple micro- light-emitting diode pixels 730 (such as micro- light emitting diode matrix) arranged in arrays, respectively the groove
731 at least penetrate the p type semiconductor layer 717 and the luminescent layer 716.Furtherly, respectively the groove 731 does not penetrate the N-type and partly leads
Body layer 713,713 system of n type semiconductor layer are the common electrode for corresponding to micro- light-emitting diode pixel 730 such as this.In other implementations
Example, can also make each groove penetrate n type semiconductor layer or only penetrate n-type doping layer, as long as light transmission conductive layer is allowed to have common electricity
Pole.It will be appreciated that can be the entire light emitting diode of etching when being etched the step of the light emitting diode block
Wafer or be only to be etching through to cut isolated light emitting diode block 711.
Then, Fig. 7 B is please referred to, non-conductive adhesive 732 is injected to the grooves 731 such as this, to increase micro- light emitting diode picture such as this
Structural strength between element 730.It, also can be without this step in some embodiments.
Then, Fig. 7 E, 7F are please referred to, engages the light emitting diode block 711 and the driving chip block 721, wherein the P
Multiple pixel electrodes of the electric connection of the type semiconductor layer 717 driving chip block 721.Preferably, to avoid influencing material
Matter, the light emitting diode block 711 and 721 system of driving chip block are with the low-temperature mixed interconnection technique lower than 200 degree Celsius
It is engaged.And respectively micro- light-emitting diode pixel 730 corresponds to the pixel electrode.In this way, can pass through the respectively pixel
Corresponding micro- light-emitting diode pixel 730 is operated alone in electrode.It is noted that each micro- light-emitting diode pixel 730
Size be usually be micron-sized.In the present embodiment, the light emitting diode block 711 and 721 system of driving chip block are point
Isolated block is not cut from the LED wafer 710 and the driving circuit wafer 720, just carries out this engagement step later
Suddenly.It will be appreciated that in another embodiment, it, also can be by entire LED wafer 710 and driving circuit wafer such as Fig. 7 C
720 engagements, carry out cutting separation in subsequent step again;It or is, such as Fig. 7 D, first to divide from the LED wafer 710 cutting
The light emitting diode block 711 is separated out, then the light emitting diode block 711 is bonded in the driving circuit wafer 720 relatively
On the position answered, cut again later.
Then, Fig. 7 G is please referred to, substrate is removed.
Next, please refer to Fig. 7 H, one light transmission conductive layer 740 of setting is on the n type semiconductor layer 713, the wherein light transmission
Conductive layer 740 has the common electrode for corresponding to micro- light-emitting diode pixel 730 such as this, furtherly, the light transmission conductive layer 740 packet
A glassy layer for being coated with an ITO conductive film is included, which is electrically connected with respectively micro- light-emitting diode pixel 730, should
ITO conductive film is the common electrode for corresponding to micro- light-emitting diode pixel 730 such as this.In addition, the light transmission conductive layer 740 is by one
Conducting resinl 750 is electrically connected the driving chip block 721, through the potential difference between the ITO conductive film and the equal pixel electrodes,
I.e. controllable respectively micro- light-emitting diode pixel 730 is shinny.In another embodiment, such as Fig. 7 K and Fig. 7 L, light transmission conductive layer 741 is also
The ITO conductive layer that can be in a manner of physically splash plating (Physical Sputtering) and formed, without glassy layer.
Next, please referring to Fig. 7 I, which is separately electrically connected with a circuit board 760, to be illustrated
It is that when carrying out this step, the driving chip block 721 and the light emitting diode block 711 are all from the driving circuit wafer
720 and the LED wafer 710 on cut the block of separation and (be independent light-emitting diode pixel array and driving
Chip).In another embodiment, such as Fig. 7 J, conducting resinl 750 can also be not connected to the driving chip block 721, and be that connection should
Light transmission conductive layer 740 and the circuit board 760.In other embodiments, can also be not provided with conducting resinl, and by the ITO conductive film with
Other conductors are electrically connected other external power supplies, as long as having potential difference between ITO conductive film and pixel electrode, can be driven each
Micro- light-emitting diode pixel is shinny.
The present embodiment passes through above-mentioned steps, that is, produces micro- light-emitting diode display module 700 as shown in Figure 7 I.This is micro-
Light-emitting diode display module 700 includes the driving chip block 721, the light emitting diode block 711, the light transmission conductive layer
740 and the circuit board 760.The driving chip block 721 has multiple pixel electrode.The light emitting diode block 711 is set to
On the driving chip block 721.The light emitting diode block 711 have first semiconductor layer, the luminescent layer 716, this second
Semiconductor layer and multiple groove 731.The luminescent layer 716 be located at this first and second semiconductor layer between, this second half is led
Body layer is electrically connected the grade pixel electrodes, which defines multiple micro- light-emitting diode pixel arranged in arrays
730, respectively the groove 731 penetrates second semiconductor layer and the luminescent layer 716.Respectively micro- light-emitting diode pixel 730 corresponding one
The pixel electrode, this first and the second semiconductor layer one of them system is n type semiconductor layer 713, another one system is that p-type is partly led
Body layer 717.Non-conductive adhesive 732 is respectively filled in the groove 731.
The light transmission conductive layer 740 is set on the light emitting diode block 711 and connects first semiconductor layer, this luminous two
Pole pipe block 711 is between the light transmission conductive layer 740 and the driving chip block 721.The circuit board 760 is electrically connected the drive
Dynamic chip block 721, and the driving chip block 721 is between the light emitting diode block 711 and the circuit board 760.It should
A conducting resinl 750 is equipped between light transmission conductive layer 740 and the driving chip block 721, which is electrically connected this
Light transmission conductive layer 740 and the driving chip block 721.The light transmission conductive layer 740 includes the glass for being coated with an ITO conductive film
Layer, the ITO conductive film (also can only have ITO conductive layer such as Fig. 7 L certainly with respectively micro- electric connection of light-emitting diode pixel 730
Without glassy layer).In another embodiment such as Fig. 7 J also the conducting resinl 750 can be set to the light transmission conductive layer 740 and be somebody's turn to do
Between driving chip block 721, which is electrically connected the light transmission conductive layer 740 and the driving chip block
721。
It please refers to Fig. 8 A, 8B, 8C, 8D, 8E, 8F, shows the third embodiment of the present invention, the micro- of the present embodiment shines two
The manufacturing method of pole pipe display module 800 includes the following steps.
At the beginning, a LED wafer 810 and one drive circuit wafer are prepared.The LED wafer 810
Partial region is defined as a light emitting diode block 811, and the region deviding of a chip size of the driving circuit wafer 820 is one
Driving chip block 821, wherein the light emitting diode block 811 has one first semiconductor layer, a luminescent layer 816 and one the
Two semiconductor layers, the luminescent layer 816 are set between first semiconductor layer and second semiconductor layer, which connects
A substrate 812 is connect, this first and the second semiconductor layer one of them system is n type semiconductor layer, another one system is P-type semiconductor
Layer.More particularly, which is n type semiconductor layer 813, which is p type semiconductor layer
817.Wherein, which includes a n-type doping layer 814 and a N-type buffer layer 815, the n-type doping layer 814
Between the N-type buffer layer 815 and the luminescent layer 816.The p type semiconductor layer 817 further includes a p-type doped layer 818 and a p-type
Buffer layer 819, the p-type doped layer 818 are located between the p-type buffer layer 819 and the luminescent layer 816, in some embodiments, also may be used
Without N-type or p-type buffer layer.
The p type semiconductor layer 817 of the light emitting diode block 811 is engaged with a light transmission conductive layer 840.Furtherly,
The light transmission conductive layer 840 includes a glassy layer for being coated with an ITO conductive film, the ITO conductive film and the p type semiconductor layer 817
It is electrically connected.In the present embodiment, as shown in Figure 8 A, this step is actually to lead the LED wafer 810 with the light transmission
Electric layer 840 engages, and 840 system of light transmission conductive layer is ito glass wafer.This step terminates and then by the light emitting diode
Block 811 cuts from the LED wafer 810 and separates, as shown in Figure 8 B.It, also can be in subsequent step again in other embodiments
Light emitting diode block 811 is cut from the LED wafer 810 and is separated
Then, as described in Fig. 8 C, the substrate 812 is removed;And etch the light emitting diode block 811.The light emitting diode
Block 811 forms staggered multiple grooves 831, which defines multiple micro- light-emitting diodes arranged in arrays
Pipe pixel 830, respectively the groove 831 at least penetrates the n type semiconductor layer 813 and the luminescent layer 816.In the present embodiment, each ditch
Slot 831 does not penetrate the p type semiconductor layer 813, and the ITO conductive film and 813 system of p type semiconductor layer are to correspond to this etc. micro- luminous two
The common electrode of pole pipe pixel 830.In other embodiments, each groove can also be made to penetrate n type semiconductor layer or only penetrate N-type and mixed
Diamicton.It will be appreciated that it is brilliant that entire light emitting diode can also be etched when being etched the step of the light emitting diode block
Circle.
Then, Fig. 8 D is please referred to, non-conductive adhesive 832 is injected to the grooves 831 such as this, to increase micro- light emitting diode picture such as this
Structural strength between element 830.It, also can be without this step in some embodiments.
Then, Fig. 8 E is please referred to, engages the light emitting diode block 811 and the driving chip block 821, wherein the N-type
Semiconductor layer 813 is electrically connected multiple pixel electrodes of the driving chip block 821, preferably, to avoid influencing material properties,
The light emitting diode block 811 and 821 system of driving chip block are carried out with the low-temperature mixed interconnection technique lower than 200 degree Celsius
Engagement.Respectively corresponding pixel electrode of micro- light-emitting diode pixel 830, in this way, can pass through the respectively pixel electrode list
Solely supply electricity to corresponding micro- light-emitting diode pixel 830.It is noted that the size of respectively micro- light-emitting diode pixel 830
Usually system is micron-sized.In the present embodiment, the light emitting diode block 811 and 821 system of driving chip block are to have distinguished
Isolated block is cut from the LED wafer and the driving circuit wafer, just carries out this engagement step later.It is appreciated that
, in other embodiments, entire LED wafer can also be engaged with driving circuit wafer;Or it is, first from the hair
The light emitting diode block is isolated in the cutting of optical diode wafer, then the light emitting diode block is bonded to driving circuit crystalline substance
As on corresponding position, needing step to cut the driving circuit wafer again after in circle.
Next Fig. 8 F is please referred to, which is separately electrically connected with a circuit board 860, to be illustrated
It is that when carrying out this step, the driving chip block 821 and the light emitting diode block 811 are all from the driving circuit wafer
And the block (being independent light-emitting diode pixel array and driving chip) of separation is cut on the LED wafer.
In the present embodiment, which is electrically connected the driving chip block 821 by a conducting resinl 850, such one
It is next, through the potential difference between the ITO conductive film and the equal pixel electrodes, i.e., controllable respectively micro- light-emitting diode pixel 830
It is shinny.Also conducting resinl 850 can be electrically connected the light transmission conductive layer 840 and the circuit board 860 such as Fig. 8 G in other embodiments,
And it is not connected to driving chip block 821.In some embodiments, it can be also not provided with conducting resinl, and by the ITO conductive film with other
Conductor is electrically connected to other external power supplies, as long as having potential difference between ITO conductive film and pixel electrode, can make each
Micro- light-emitting diode pixel is shinny.
The present embodiment passes through above-mentioned steps, can produce micro- light-emitting diode display module 800 as shown in Figure 8 F.It should
Micro- light-emitting diode display module includes the driving chip block 821, the light emitting diode block 811, the light transmission conductive layer
840 and the circuit board 860.The driving chip block 821 has multiple pixel electrode.The light emitting diode block 811 is set to
On the driving chip block 821.The light emitting diode block 811 have first semiconductor layer, the luminescent layer 816, this second
Semiconductor layer and multiple groove 831.The luminescent layer 816 be located at this first and second semiconductor layer between, this second half is led
Body layer is electrically connected the grade pixel electrodes, which defines multiple micro- light-emitting diode pixel arranged in arrays
830, respectively the groove 831 penetrates second semiconductor layer and the luminescent layer 816.Respectively micro- light-emitting diode pixel 830 corresponding one
The pixel electrode, this first and the second semiconductor layer one of them system is n type semiconductor layer 813, another one system is that p-type is partly led
Body layer 817.Non-conductive adhesive 832 is respectively filled in the groove 831.
The light transmission conductive layer 840 is set to the light emitting diode block 811 and connects first semiconductor layer, the light-emitting diodes
Area under control block 811 is between the light transmission conductive layer 840 and the driving chip block 821.The circuit board 860 is electrically connected the driving
Chip block 821, and the drive circuit chip block is between the light emitting diode block 811 and the circuit board 860.This is thoroughly
A conducting resinl 850 is equipped between optical conductive layer 840 and the driving chip block 821, which is electrically connected this thoroughly
Optical conductive layer 840 and the driving chip block 821.The light transmission conductive layer 840 includes the glass for being coated with an ITO conductive film
Layer, the ITO conductive film are electrically connected with respectively micro- light-emitting diode pixel 830.It, also can should such as Fig. 8 G in another embodiment
Conducting resinl 850 is set between the light transmission conductive layer 840 and the driving chip block 821, which is electrically connected this
Light transmission conductive layer 840 and the driving chip block 821.
Fig. 9 A, 9B, 9E, 9F, 9G are please referred to, shows the fourth embodiment of the present invention, micro- light-emitting diodes of the present embodiment
The manufacturing method of pipe display module 900 includes the following steps.
At the beginning, a LED wafer 910 and one drive circuit wafer 920 are prepared.The LED wafer 910
Partial region be defined as a light emitting diode block 911, the region deviding of a chip size of the driving circuit wafer 920 is
One driving chip block 921, wherein the light emitting diode block 911 has one first semiconductor layer, a luminescent layer 916 and one
Second semiconductor layer, the luminescent layer 916 are set between first semiconductor layer and second semiconductor layer, first semiconductor layer
A sapphire substrate 912 is connected, this first and the second semiconductor layer one of them system is n type semiconductor layer, another one system is P
Type semiconductor layer.More particularly, which is n type semiconductor layer 913, which is p-type
Semiconductor layer 917.Wherein, which includes a n-type doping layer 914 and a N-type buffer layer 915, the n-type doping
Layer 914 is between the N-type buffer layer 915 and the luminescent layer 916.The p type semiconductor layer 917 further includes a p-type doped layer 918
And a p-type buffer layer 919, which is located between the p-type buffer layer 919 and the luminescent layer 916, in certain implementations
Example, can also not have N-type or p-type buffer layer.
Fig. 9 A is please referred to, the light emitting diode block 911 is etched, and forms staggered multiple grooves 931, the equal ditches
Slot 931 defines multiple micro- light-emitting diode pixels 930 arranged in arrays, and respectively the groove 931 penetrates the p type semiconductor layer
917 and the luminescent layer 916.Furtherly, respectively the groove 931 does not penetrate the n type semiconductor layer 913, the n type semiconductor layer 913
With the common electrode for corresponding to micro- light-emitting diode pixel 930 such as this.In another embodiment, can also make respectively the groove penetrate this
N-type doping layer, as long as at least partly the n type semiconductor layer can be used as common electrode.It will be appreciated that in being etched this
When the step of light emitting diode block, it can be the entire LED wafer of etching or be only to be etching through cutting separation
Light emitting diode block 911.Also, the n type semiconductor layer 913, which has, corresponds to being total to for micro- light-emitting diode pixel 930 such as this
Same electrode, and a protrusion 970 has been protruded out in the common electrode horizontal direction, in the present embodiment, which has
The protrusion 970, which lies in execute and generate in etching light emitting diode step, and 915 system of N-type buffer layer
It is the common electrode of light-emitting diode pixel for this etc..
Then, Fig. 9 B is please referred to, non-conductive adhesive 932 is injected to the grooves 931 such as this, to increase micro- light emitting diode picture such as this
Structural strength between element 930.It, also can be without this step in some embodiments.
Then, Fig. 9 E and 9F are please referred to, the light emitting diode block 911 and the driving chip block 921 are engaged, wherein should
Multiple pixel electrodes of the electric connection of the p type semiconductor layer 917 driving chip block 921.Preferably, to avoid influencing material
Matter, the light-emitting diodes plumber block are connect with 921 system of driving chip block with the low-temperature mixed interconnection technique lower than 200 degree Celsius
It closes.And respectively micro- light-emitting diode pixel 930 corresponds to the pixel electrode.In this way, can pass through the respectively pixel electrode list
Solely supply electricity to corresponding micro- light-emitting diode pixel 930.It is noted that the respectively usual ruler of micro- light-emitting diode pixel 930
Very little is micron order.It is noted that the light emitting diode block 911 and 921 system of driving chip block are in the present embodiment
Isolated block is cut from the LED wafer and the driving circuit wafer respectively, just carries out this engagement step later.It can
Understand, entire LED wafer 910 can also be connect with driving circuit wafer 920 in other embodiments such as Fig. 9 C
It closes;It or is such as Fig. 9 D, first to isolate the light emitting diode block 911 from LED wafer cutting, then this is shone
Diode block 911 is bonded in the driving circuit wafer 920 as being cut again on corresponding position later.
In addition to this, which is electrically connected the driving chip block 921 by a conducting resinl 950, through the N
Potential difference between type buffer layer 915 and the equal pixel electrodes, i.e., controllable respectively micro- light-emitting diode pixel 930 are shinny.
It is noted that this embodiment needn't remove the sapphire substrate 912.
Next, please referring to Fig. 9 G, which is separately electrically connected with a circuit board 960, to be illustrated
It is that when carrying out this step, the driving chip block 921 and the light emitting diode block 911 are all from the driving circuit wafer
And the block (being independent light-emitting diode pixel array and driving chip) of separation is cut on the LED wafer.
In another embodiment, such as Fig. 9 H, conducting resinl 950 can also be not connected to the driving chip block 921, and be to connect the protrusion
970 with the circuit board 960.In some embodiments, it can be also not provided with conducting resinl 950, and by the ITO conductive film with other conductors
Other external power supplies are electrically connected, as long as having potential difference between ITO conductive film and pixel electrode, respectively micro- hair can be made
Optical diode pixel 930 is shinny.
The present embodiment passes through above-mentioned steps, that is, produces micro- light-emitting diode display module as shown in fig. 9g.Micro- hair
Optical diode display module includes the driving chip block 921, the light emitting diode block 911 and the circuit board 960.The drive
Dynamic chip block 921 has multiple pixel electrode.The light emitting diode block 911 is set on the driving chip block 921.It should
Light emitting diode block 911 has first semiconductor layer, the luminescent layer 916, second semiconductor layer and multiple groove
931.The luminescent layer 916 be located at this first and second semiconductor layer between, which is electrically connected the pixels such as this
Electrode, the grade grooves 931 define multiple micro- light-emitting diode pixel 930 arranged in arrays, and respectively the groove 931 penetrates this
Second semiconductor layer and the luminescent layer 916.Respectively corresponding pixel electrode of micro- light-emitting diode pixel 930.The respectively groove 931
It is interior to be filled with non-conductive adhesive 932.The protrusion 970 has been protruded out in the first semiconductor layer horizontal direction.And first semiconductor
Layer is connected with the sapphire substrate 912, and first semiconductor layer is between the sapphire substrate 912 and the luminescent layer 916.
The circuit board 960 is electrically connected the driving chip block 921, and the driving chip block 921 shines two between this
Between pole pipe block 911 and the circuit board 960.A conducting resinl is equipped between the protrusion 970 and the driving chip block 921
950, which is electrically connected the protrusion 970 and the driving chip block 921.In another embodiment, such as Fig. 9 H
It is shown, conducting resinl 950 can be also set between the protrusion 970 and the circuit board 960, which is electrically connected
The protrusion 970 and the circuit board 960.
Referring to Fig. 10, in order to make micro- light-emitting diode display module of above-mentioned all embodiments issue different colours, it can
One chromatograph 170 (RGB color layer) is in addition set, so that micro- light-emitting diode display module issues three coloured light.Furtherly, the color
The generation type of layer 170 lies in above the respectively micro- light-emitting diode pixel and sprays corresponding RGB quantum dot, with respectively this micro- shine
The luminous excitation quantum dot of diode pixel generates three coloured light.Furtherly, which has multiple red, blues, green
Pixel region 171,172,173, each corresponding micro- light-emitting diode pixel of the pixel region 171,172,173, and the color
Layer 170 has multiple total colouring points (minimum unit that can show three coloured light).Respectively the total colouring point has at least three phases
Adjacent pixel region 171,172,173, respectively the total colouring point includes at least the red pixel area 171, the one blue picture
Plain 172 domain of area and the green pixel area 173.Preferably, the 1 total colouring point may include four for process requirement
Adjacent pixel region (such as 171, blue pixel areas 172 of a red pixel area and two green pixel areas
173), so that the arrangement of total colouring point is more regular.In other embodiments, as shown in figure 11, chromatograph 180 can also be filtered for RGB
Mating plate.
Claims (25)
1. a kind of manufacturing method of micro- light-emitting diode display module, the manufacturing method the following steps are included:
A LED wafer and one drive circuit wafer are prepared, wherein the partial region of the LED wafer is defined as
One light emitting diode block, the region deviding of a chip size of the driving circuit wafer are a driving chip block, wherein should
Light emitting diode block have one first semiconductor layer, a luminescent layer and one second semiconductor layer, the luminescent layer be set to this first
Between semiconductor layer and second semiconductor layer, which connects a substrate, this first and second semiconductor layer
One of them system is n type semiconductor layer, another one system is p type semiconductor layer;
The light emitting diode block and the driving chip block are engaged, wherein second semiconductor layer and the driving chip block
Multiple pixel electrodes are electrically connected;
Remove the substrate;
The light emitting diode block is etched, and forms staggered multiple grooves, wherein the grade grooves are defined arranges in matrix
Multiple micro- light-emitting diode pixels of column, respectively micro- light-emitting diode pixel corresponds to the pixel electrode;
One light transmission conductive layer is set on first semiconductor layer, wherein the light transmission conductive layer have it is corresponding this etc. micro- light-emitting diodes
The common electrode of pipe pixel;
One chromatograph is set in the light transmission conductive layer, wherein the chromatograph system is RGB color layer.
2. manufacturing method as described in claim 1, which is characterized in that the n type semiconductor layer includes a n-type doping layer and a N
Type buffer layer, the n-type doping layer are located between the N-type buffer layer and the luminescent layer.
3. manufacturing method as described in claim 1, which is characterized in that the p type semiconductor layer further includes a p-type doped layer and one
P-type buffer layer, the p-type doped layer are located between the p-type buffer layer and the luminescent layer.
4. manufacturing method as described in claim 1, which is characterized in that separately include a step: by the driving chip block separately with
One circuit board is electrically connected, and wherein the driving chip block system is the driving chip that separation is cut from the driving wafer.
5. manufacturing method as claimed in claim 4, which is characterized in that the light transmission conductive layer by a conducting resinl separately with the circuit
Plate is electrically connected.
6. manufacturing method as described in claim 1, which is characterized in that the light transmission conductive layer is electrically connected by a conducting resinl should
Driving chip block.
7. manufacturing method as described in claim 1, which is characterized in that the light transmission conductive layer is coated with ITO conduction including one
The glassy layer of film, the ITO conductive film are electrically connected with respectively micro- light-emitting diode pixel.
8. manufacturing method as described in claim 1, which is characterized in that the chromatograph system is optical filter.
9. manufacturing method as described in claim 1, which is characterized in that the chromatograph system is formed with spraying quantum point mode.
10. manufacturing method as described in claim 1, which is characterized in that in the engagement light emitting diode block and the driving core
Before the step of piece block, after the step of preparing the LED wafer, separately include a step: by the light emitting diode
Block cuts from the LED wafer and separates;Wherein engage the step of the light emitting diode block and the driving chip block
It suddenly, is that the light emitting diode block is engaged with the driving circuit wafer with the driving chip block.
11. manufacturing method as described in claim 1, which is characterized in that in the engagement light emitting diode block and the driving core
Before the step of piece block, after the step of preparing the LED wafer and the driving circuit wafer, separately include a step
It is rapid: the light emitting diode block and the driving chip block are cut from the LED wafer and the driving circuit wafer respectively
Cut separation.
12. manufacturing method as described in claim 1, which is characterized in that engage the light emitting diode block and the driving chip
The step of block is there is the LED wafer of the light emitting diode block to have the driving chip block with this this
Driving circuit wafer engages.
13. manufacturing method as described in claim 1, which is characterized in that include separately a step, non-conductive adhesive is injected the grade ditches
Slot.
14. a kind of micro- light-emitting diode display module, comprising:
One driving chip block has multiple pixel electrodes;
One light emitting diode block is set to the driving chip block, and has two semiconductor layers and multiple grooves, the luminescent layer
Positioned at this first and second semiconductor layer between, which is electrically connected the grade pixel electrodes, another
Person connects a light transmission conductive layer, and the light emitting diode block is between the light transmission conductive layer and the driving chip block, this etc.
Groove defines multiple micro- light-emitting diode pixels arranged in arrays, and respectively the groove at least penetrates the luminescent layer and connection should
The semiconductor layer of equal pixel electrodes, respectively corresponding pixel electrode of micro- light-emitting diode pixel, two semiconductor layer wherein one
Person system is n type semiconductor layer, another one system is p type semiconductor layer;
One circuit board is electrically connected the driving chip block, and the drive circuit chip block is between the light emitting diode block
Between the circuit board;
One chromatograph is set to the light transmission conductive layer, which is located between the chromatograph and the light emitting diode block, the color
Series of strata are RGB color layer.
15. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the n type semiconductor layer includes a N
Type doped layer and a N-type buffer layer, the n-type doping layer are located between the N-type buffer layer and the luminescent layer.
16. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the p type semiconductor layer further includes
One p-type doped layer and a p-type buffer layer, the p-type doped layer are located between the p-type buffer layer and the luminescent layer.
17. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the light transmission conductive layer and the circuit
A conducting resinl is equipped between plate, which is electrically connected the light transmission conductive layer and the circuit board.
18. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the light transmission conductive layer and the driving
A conducting resinl is equipped between chip block, which is electrically connected the light transmission conductive layer and the driving chip block.
19. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the light transmission conductive layer is draped over one's shoulders including one
It is covered with the glassy layer of an ITO conductive film, which is electrically connected with respectively micro- light-emitting diode pixel.
20. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the light transmitting electro-conductive series of strata are ITO
Conductive layer.
21. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the chromatograph system is optical filter.
22. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that the chromatograph system is to spray quantum dot
Mode is formed.
23. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that respectively led in the groove filled with non-
Electric glue.
24. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that respectively the groove does not penetrate the connection
The semiconductor layer of the light transmission conductive layer.
25. micro- light-emitting diode display module as claimed in claim 14, which is characterized in that respectively the groove, which penetrates, connects this thoroughly
The semiconductor layer of optical conductive layer.
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CN109448574A (en) * | 2018-12-28 | 2019-03-08 | 苏州椒图电子有限公司 | A kind of display device and its manufacturing method |
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CN102576783A (en) * | 2009-07-30 | 2012-07-11 | 3M创新有限公司 | Pixelated led |
CN103474445A (en) * | 2013-08-14 | 2013-12-25 | 中国科学院长春光学精密机械与物理研究所 | Miniaturized LED integrated array device and preparation method thereof |
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CN102576783A (en) * | 2009-07-30 | 2012-07-11 | 3M创新有限公司 | Pixelated led |
CN103474445A (en) * | 2013-08-14 | 2013-12-25 | 中国科学院长春光学精密机械与物理研究所 | Miniaturized LED integrated array device and preparation method thereof |
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Application publication date: 20181218 |