Abstract:
An active matrix LED display apparatus and a fabrication method thereof are provided. The active matrix LED display apparatus enables to miniaturize pixel by a formation of wiring on bottom layer and an assembly of each block through each eutectic layer into each transistor block receptor and/or each LED block receptor formed according to each color element unit, and to be embodied with high luminance, low power consumption, high reliability and superior optical property by assembling a transistor block having high electron mobility. And the fabricating method of the present invention enables to make efficiently an AM-LED display apparatus at room temperature in a short time by using different shapes of receptor and block depending on the function of a transistor and/or on the color of an LED.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims priority under 35 U.S.C. 119 of Korean Patent Application 10-2010-0042869 filed on May 7, 2010, the entire contents of which are hereby incorporated by reference. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to an active matrix display apparatus and a method for fabricating the same, and more particularly, to an active matrix LED display apparatus having an active matrix consisting of a transistor and a light emitting diode (LED) and to a fabrication method thereof. 
     2. Description of the Related Art 
     So far, the display devices are known such as a cathode ray tube (CRT), a plasma display panel (PDP), a field emission display (FED), a thin film transistor-liquid crystal display (TFT-LCD), and an active-matrix organic light-emitting diode (AMOLED). 
     The advantages and disadvantages of the known display devices are as like as followings. 
     The CRT is used to create a color image by an electron beam and has the relatively good performance. However, the CRT has problems such as a heavy weight, a wide thickness, and a higher voltage and power consumption. Therefore, the CRT display has been preferably alternated with other thin flat panel display device due to the problem of the thickness. 
     The PDP is used to display a screen by a plasma discharge in spaces sealed with a front glass, a back glass and partition walls. However, the PDP has problems related to low image resolution and high driving voltage. 
     The FED uses a field emission cathode to provide electrons that strike colored phosphor to produce a color image. The FED has a high luminance and a high sense of color. However, the FED has problems such as a fast thermal degradation of the cathode and a stability of high vacuum state. 
     The TFT-LCD is consisted of a bottom plate with TFT element, an upper plate with color filter, and a liquid crystal locating between the bottom and the upper plates. The TFT-LCD controls an emitting light of a back light using a slope of the liquid crystal by a voltage difference. The TFT-LCD is used widely due to the some advantages such as a thin film, a high resolution, and a long life time. However, because the TFT-LCD is one of non-directly emitting elements, it shows bad in the properties of luminance, contrast, sight angle and response speed. 
     The AMOLED is used to drive an OLED device by TFT element and does not need a back light and a color filter. Therefore, the AMOLED has some advantages such as a simple fabrication, low power consumption, an ultrafine printing and a flexible display. However, the AMOLED has a short life time due to the using an organic electroluminescence diode and is not easy to make a large size due to the difficulty of molding. 
     The flat panel display (LCD, OLED, FED etc.) is divided to an active matrix and a passive matrix depending on the driving mode. 
     The passive matrix is consisted of grid of horizontal and vertical electrode lines. The intersection of grid is a pixel for emitting light. The passive matrix is a simple structure, but needs an instantly high luminance to recognize the pixel for short time. Therefore, the passive matrix has some disadvantages such as high power consumption due to the instant luminance, a difficulty in making large size due to the reduction of luminance by the increasing of the line number, and generally a reduction of life time. 
     On the other hand, the active matrix is consisted of one or more transistors in each pixel and capacitors to store an electric charge for emitting light. Therefore, the active matrix can be turned constantly on a driving state for one frame and be used to produce a display with good efficiency, low power consumption and large size. 
     The light emitting diode (LED) according to the present invention is a kind of solid element enabling to convert an electric energy into light and is used to an illuminator, a back light unit of LCD and a display apparatus. 
     Specifically, a non-organic LED is a light emitting element with some advantages such as high efficiency for reducing the power consumption, high color purity for producing the display with good color reproducing ratio, rapid light emitting property due to the using of electron and hole with very high electrical mobility, a long life time, a low environmental pollution due to the using of non-mercury material, and considerably high reliability. 
     Among display applications, TV is required the most long life time as more than 30,000 hours. The commercial LED is taken more than 50,000 hours of life time and so is sufficient to apply TV display. 
     Also, the commercial LED has over 100 lm/W of luminous efficiency which is enough to embody a display with an ultrahigh luminance and low power consumption against OLED. Additionally, compared to the TFT-LCD having a back light of LED, the LED can make a display with very thin and considerably low power consumption and without the luminance loss by a liquid crystal, a polarizing film and a color filter. 
     By the advanced properties of the LED, the AM-LED driving by active matrix can be displayed with some advantages such as a directly emitting light, a long life time against the AMOLED with organic light emitting diode, high luminance and low power consumption. Also, the LED can be displayed with high reliability by good stability in the infinitesimal quantity of water and oxygen which cause serious thermal degradation in the organic light emitting diode. 
     The personal and household display applications have a medium and small size of display such as a cellular phone, a digital camera, a video camera, a navigation device, a PDA, handheld PCs, a PMP and so on, and also have a medium and large size of display such as a monitor, a notebook, a TV and so on. 
     Presently, the LED has many advantages compare to the other displays excepting the commercial TFT-LCD and AMOLED. However, for personal and household applications, the conventional LED shows some disadvantages such as an impossibility of a monolithic process for producing one substrate with red, green and blue elements and an expensiveness of a compound semiconductor for molding a whole substrate. 
     Generally, the commercial LED display has an electric bulletin board apparatus consisted of the LED modules. However, because a display of the electric bulletin board device is formed through matching each LED board and drive board up by the module consisted of one LED element, each pixel of the display can not be miniaturized to apply to the personal and household applications. 
     The robotic pick-and-place system can be used to assemble hetero devices on a substrate which is not formed by monolithic method. In a micron size of the device, it shows that the efficiency is reducing and the cost of process is increasing. 
     Consequently, in order to overcome the mentioned problems, some methods, as like as a fluidic self-assembly (FSA) process (e.g., U.S. Pat. No. 5,545,291), are developed to assemble on one substrate with structures, devices, and subsystems needed the incompatible fabricating process using particular forces such as capillary force, gravity, electronic force, and pattern recognition. 
     SUMMARY OF THE INVENTION 
     Technical Problem 
     The present invention is disclosed to overcome the problems in the formation of circuit structure for driving LED display apparatus and in the assembly of general LED display. More specifically, because the miniaturization of pixel to apply to personal and household applications is difficult by the known method of LED display assembly, namely, an individual integration of the LED module consisted of one LED device to a board applied for an electric bulletin board apparatus, the objective of this present invention is to disclose an LED display apparatus having an active device to be assembled with hetero LED devices, switching devices, and driving devices on the same one substrate and a fabrication method thereof to overcome the above problems. 
     Technical Solution 
     To achieve the mentioned objective, a first structure of an LED display apparatus according to the present invention, comprising: a buffer layer forming on a substrate; a switching transistor active layer and a driving transistor active layer formed separately from each other and having a source and a drain in both sides of the each active layer on the buffer layer in a color element unit; a first insulating layer formed to cover the switching and the driving transistor active layers on the substrate; a scan line formed across between the source and the drain of the switching transistor on the first insulating layer; a cathode line formed parallel to and separately from the scan line on the first insulating layer; a storage capacitor bottom electrode formed across between the source and the drain of the driving transistor and connected electrically to the drain of the switching transistor on the first insulating layer in a color element unit; a second insulating layer formed to cover the scan line, the cathode line and the storage capacitor bottom electrode on the first insulating layer; a data line formed vertically to the scan line and connected electrically to the source of the switching transistor on the second insulating layer; a power supply line formed parallel to and separately from the data line and connected electrically to the source of the driving transistor on the second insulating layer; a storage capacitor top electrode formed to overlap the storage capacitor bottom electrode and connected electrically to the power supply line on the second insulating layer in a color element unit; an anode contact layer formed between the data line and the power supply line and connected electrically to the drain of the driving transistor on the second insulating layer in a color element unit; an LED block receptor formed with a third insulating layer to cover at least one part of the data line, the power supply line, the storage capacitor top electrode and the anode contact layer on the second insulating layer in a color element unit; a cathode eutectic layer and an anode eutectic layer formed separately from each other and connected electrically to the cathode line and the anode contract layer, respectively, in the LED block receptor; and an LED block of the color element unit assembled into the LED block receptor through electrical connections of the cathode eutectic layer and the anode eutectic layer to a cathode electrode and an anode electrode of the LED block, respectively. 
     A second structure of an LED display apparatus according to the present invention, comprising: a data line, a scan line and a cathode line formed parallel to and separately from each other on a substrate; a storage capacitor bottom electrode formed between the scan line and the cathode line in a color element unit; a first insulating layer formed to cover the data line, the scan line, the cathode line and the storage capacitor bottom electrode on the substrate; a power supply line formed vertically to the data line on the first insulating layer; a storage capacitor top electrode formed to overlap the storage capacitor bottom electrode and connected electrically to the power supply line on the first insulating layer in a color element unit; an anode contact layer formed separately from the power supply line on the first insulating layer in a color element unit; a switching transistor receptor, a driving transistor receptor and an LED block receptor formed with a second insulating layer to cover at least one part of the power supply line, the storage capacitor top electrode and the anode contact layer on the first insulating layer in a color element unit; a source eutectic layer, a gate eutectic layer and a drain eutectic layer of a switching transistor formed separately from each other and connected electrically to the data line, the scan line and the storage capacitor bottom electrode, respectively, in the switching transistor receptor; a gate eutectic layer, a source eutectic layer and a drain eutectic layer of a driving transistor formed separately from each other and connected electrically to the storage capacitor bottom electrode, the power supply line and the anode contact layer, respectively, in the drive transistor receptor; a cathode eutectic layer and an anode eutectic layer formed separately from each other and connected electrically to the cathode line and the anode contact layer, respectively, in the LED block receptor; a switching transistor block of the color element unit assembled into the switching transistor receptor through electrical connections of the source eutectic layer, the gate eutectic layer and the drain eutectic layer of the switching transistor to a source electrode, a gate electrode and a drain electrode of the switching transistor block, respectively; a driving transistor block of the color element unit assembled into the driving transistor receptor through electrical connections of the source eutectic layer, the gate eutectic layer and the drain eutectic layer of the driving transistor to a source electrode, a gate electrode and a drain electrode of the driving transistor block, respectively; and an LED block of the color element unit assembled into the LED block receptor through electrical connections of the cathode eutectic layer and the anode eutectic layer to a cathode electrode and an anode electrode of the LED block, respectively. 
     A third structure of an LED display apparatus according to the present invention, comprising: a power supply line formed on a substrate; a storage capacitor bottom electrode connected electrically and vertically to the power supply line on the substrate in a color element unit; a first insulating layer formed to cover the power supply line and the storage capacitor bottom electrode on the substrate; a data line and a scan line formed parallel to each other and formed vertically to the power supply line on the first insulating layer; a storage capacitor top electrode formed to overlap the storage capacitor bottom electrode and formed near by the scan line on the first insulating layer in a color element unit; an anode contact layer formed separately from and near by the storage capacitor top electrode on the first insulating layer in a color element unit; a switching transistor receptor, a driving transistor receptor and an LED block receptor formed with a second insulating layer to cover at least one part of the data line, the scan line, the storage capacitor top electrode and the anode contact layer on the first insulating layer in a color element unit; a source eutectic layer, a gate eutectic layer and a drain eutectic layer of a switching transistor formed separately from each other and connected electrically to the data line, the scan line and the storage capacitor top electrode, respectively, in the switching transistor receptor; a gate eutectic layer, a source eutectic layer and a drain eutectic layer of a driving transistor formed separately from each other and connected electrically to the storage capacitor top electrode, the power supply line and the anode contact layer, respectively, in the driving transistor receptor; an anode eutectic layer connected electrically to the anode contact layer in the LED block receptor; a switching transistor block of the color element unit assembled into the switching transistor receptor through electrical connections of the source eutectic layer, the gate eutectic layer and the drain eutectic layer of the switching transistor to a source electrode, a gate electrode and a drain electrode of the switching transistor block, respectively; a driving transistor block of the color element unit assembled into the driving transistor receptor through electrical connections of the source eutectic layer, the gate eutectic layer and the drain eutectic layer of the driving transistor to a source electrode, a gate electrode and a drain electrode of the driving transistor block, respectively; an LED block of the color element unit assembled into the LED block receptor through electrical connection of the anode eutectic layer to an anode electrode of the LED block ; a color element defining layer formed with a third insulating layer to expose a part of the LED block on the substrate assembled with the each block; and a cathode line formed to connect electrically to the exposed part of the LED block on the color element defining layer. 
     A method for fabricating the first structure of an LED display apparatus according to the present invention, comprising: a first step, depositing a buffer layer on a display substrate and forming a switching transistor active layer and a driving transistor active layer in a color element unit; a second step, depositing sequentially a first insulating layer and a conductive material on a whole surface of the substrate and etching the conductive material to form a scan line, a cathode line and a storage capacitor bottom electrode; a third step, depositing sequentially a second insulating layer and a conductive material on a whole surface of the substrate and etching the conductive material to form a data line, a power supply line, a storage capacitor top electrode and an anode contact layer; a fourth step, depositing a third insulating layer on a whole surface of the substrate, etching the third insulating layer to form an LED block receptor in a color element unit and forming a cathode eutectic layer and an anode eutectic layer in the LED block receptor; and a fifth step, assembling an LED block of the color element unit into the LED block receptor by a fluidic self-assembly process. 
     A method for fabricating the second structure of an LED display apparatus according to the present invention, comprising: a first step, depositing a conductive material on a display substrate and etching the conductive material to form a data line, a scan line, a cathode line and a storage capacitor bottom electrode; a second step, depositing sequentially a first insulating layer and a conductive material on a whole surface of the substrate and etching the conductive material to form a power supply line, a storage capacitor top electrode and an anode contact layer; a third step, depositing a second insulating layer on a whole surface of the substrate, etching the second insulating layer to form a switching transistor block receptor, a driving transistor block receptor and an LED block receptor in a color element unit and forming eutectic layer in the each block receptor; and a fourth step, assembling a switching transistor block, a driving transistor block and an LED block into the each receptor by a fluidic self-assembly process. 
     A method for fabricating the third structure of an LED display apparatus according to the present invention, comprising: a first step, depositing a conductive material on a display substrate and etching the conductive material to form a power supply line and a storage capacitor bottom electrode; a second step, depositing sequentially a first insulating layer and a conductive material on a whole surface of the substrate and etching the conductive material to forma data line, a scan line, a storage capacitor top electrode and an anode contact layer; a third step, depositing a second insulating layer on a whole surface of the substrate, etching the second insulating layer to form a switching transistor block receptor, a driving transistor block receptor and an LED block receptor in a color element unit and forming eutectic layer in the each block receptor; a fourth step, assembling a switching transistor block, a driving transistor block and an LED block into the each receptor by a fluidic self-assembly process; a fifth step, depositing a third insulating layer on a whole surface of the substrate and etching the third insulating layer to form a color element defining layer for exposing the assembled LED block partially; and a sixth step, depositing a transparent or a semitransparent conductive material and forming a cathode contact layer to connect electrically to the exposed LED block. 
     Advantageous Effect 
     An LED display apparatus of the present invention enables to miniaturize pixel by a formation of wiring on bottom layer and an assembly of each block through each eutectic layer into each transistor block receptor and/or each LED block receptor formed according to each color element unit. Therefore, the LED display apparatus can apply to personal and household applications and can embody AM-LED display apparatus with high luminance, low power consumption, high reliability, and superior optical property by assembling a transistor block having high electron mobility. 
     And a fabricating method of an LED display apparatus according to the present invention comprises forming transistor block receptor and LED block receptor on a display substrate and assembling a prepared single-crystal silicon transistor block and a prepared LED block into the each block receptor by a fluidic self-assembly process. Consequently, the fabricating method of the present invention enables to make efficiently an AM-LED display apparatus at room temperature in a short time by using different shapes of receptor and block depending on the function of a transistor and on the color of an LED. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention may be better understood by the drawings that are briefly described below and attached hereto, in the several figures of which identical reference numbers (if any) refer to identical or similar elements. 
         FIG. 1  is a circuit diagram for embodying an AM-LED display apparatus according to the present invention. 
         FIG. 2  is a cross-section view of a structure of a block assembled into a receptor through eutectic layer by a fluidic self-assembly process (FSA). 
         FIG. 3  is a plane view of structures of LED blocks assembled into LED block receptors which have different shapes depending on a color element R (Red), G (Green), or B (Blue) in an AM-LED display apparatus according to the present invention. 
         FIG. 4  is a layout to illustrate a structure of any one color element in  FIG. 3 . 
         FIG. 5  is a cross-section view of a line AA′ to illustrate a stacked structure and an LED block receptor according to the present invention. 
         FIGS. 6 and 7  are cross-section views to illustrate a structure of an LED block assembled into an LED block receptor according to the present invention. 
         FIG. 8  is a cross-section view to illustrate a structure of the LED block in  FIG. 6  assembled into the LED block receptor in  FIG. 5 . 
         FIG. 9  is a flowchart for a first embodiment on a fabricating method of an AM-LED display apparatus according to the present invention. 
         FIG. 10  is a plane view of structures of LED blocks assembled into LED block receptors which have different shapes depending on a color element R, G, and B and structures of transistor blocks assembled into switching and driving transistor block receptors which have different shapes depending on the function of transistor in an AM-LED display apparatus according to the present invention. 
         FIG. 11  is a layout to illustrate a structure of any one color element in  FIG. 10 . 
         FIGS. 12 and 13  are cross-section views of lines BB′ and CC′ in  FIG. 11  to illustrate a stacked structure, an LED block receptor, and each transistor block receptor according to the present invention. 
         FIGS. 14 to 17  are cross-section views to illustrate the each structure of the blocks assembled into each receptor in  FIG. 12  or  FIG. 13  in an AM-LED display apparatus according to the present invention. 
         FIGS. 18 and 19  are cross-section views to illustrate different fabricating methods of a transistor block according to the present invention. 
         FIG. 20  is a flowchart for a second embodiment on a fabricating method of an AM-LED display apparatus according to the present invention. 
         FIG. 21  is another layout to illustrate a structure of any one color element in  FIG. 10 . 
         FIG. 22  is cross-section view of a line DD′ in  FIG. 21  to illustrate a stacked structure, an LED block receptor, and a transistor block receptor according to the present invention. 
         FIGS. 23 and 24  are cross-section views to illustrate one fabricating method of an LED block assembled into an LED block receptor in  FIG. 22 . 
         FIG. 25  is a cross-section view to illustrate another fabricating method of a LED block assembled into a LED block receptor in  FIG. 22 . 
         FIGS. 26 to 31  are cross-section views to illustrate the each structure of the blocks assembled into each receptor in  FIG. 22  in an AM-LED display apparatus according to the present invention. 
         FIG. 32  is a flowchart for a third embodiment on a fabricating method of an AM-LED display apparatus according to the present invention. 
       In these drawings, the following reference numbers are used throughout: reference number  1  indicates a color element,  2  means a pixel,  3  means a substrate,  4  means an LED block of color element R,  5  means an LED block of color element G,  6  means an LED block of color element B,  7  means a switching transistor block,  8  means a driving transistor block,  10  means a display substrate,  20 ,  40 ,  70 ,  72 ,  72   a ,  91 ,  91   a ,  92 ,  93 ,  93   a ,  94 , and  95  mean a insulating layer,  30  means a driving transistor active layer,  41  means an LED block receptor,  50  and  85   a  mean a storage capacity bottom electrode,  50   a  and  85  mean a storage capacity top electrode,  60  and  60   a  mean a cathode line,  71  means a switching transistor block receptor,  80  and  80   a  mean a scan line,  81  means a driving transistor block receptor,  82  and  82   a  mean a power supply line,  83 ,  83   a  and  83   b  mean a data line,  84  and  84   a  mean a anode contact layer,  96  means a color element defining layer,  100  means a receptor,  200 ,  212 ,  214 ,  222 ,  224 ,  226 ,  232 ,  234 ,  236 ,  242 ,  244  and  246  mean an eutectic layer, and  300  means a block. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A detailed description of preferred embodiments of the present invention is provided below with respect to the accompanying drawings. 
     The present invention, as shown in  FIG. 1 , is related to an active matrix (AM)-LED display apparatus, basically comprising: a data driving circuit and a scan line driving circuit; a data line and a scan line connected to the data driving circuit and the scan line driving circuit, respectively; an active matrix which is controlled by the each line and is consisted of a switching transistor Tr 1 , a driving transistor Tr 2 , a color element driving storage capacitor Cs and a light emitting diode LED in a color element unit  1 ; and a power supply line Vdd connected to a drain of the each driving transistor Tr 2 . 
     In order to drive a light emitting diode LED of one color element  1  in an AM-LED display apparatus according to the present invention, when a select signal is transferred to a scan line, which crosses the color element  1 , a switching transistor Tr 1  is turned on and then a data voltage of a data line through the color element  1  is transferred to a gate of a driving transistor Tr 2  and simultaneously charges a storage capacitor Cs. 
     At this time, the data voltage or the charged voltage of the storage capacitor Cs becomes a voltage between a source and a gate of the driving transistor Tr 2  and then a current corresponded to the voltage flows from a power supply line Vdd through the driving transistor Tr 2  to a light emitting diode LED of the color element  1 . Consequently, the LED emits light corresponding to the current. 
     Therefore, for controlling a light intensity of an LED, the voltage between a source and a gate of the driving transistor Tr 2 , namely, the voltage of the storage capacitor Cs can be regulated. 
     An AM-LED display apparatus according to the present invention is characterized by forming each transistor Tr 1 , Tr 2  and/or an LED of a color element unit  1  in  FIG. 1  into a block  300 , respectively, and assembling the each transistor block and/or the LED block  300  through an eutectic layer  200  into a receptor  100  formed to have each exposed wiring of a bottom layer on a display substrate as shown in  FIG. 2 . 
     Here, the eutectic layer  200  is a material layer consisted of a metal or a molten alloy (i.e., a metal compound) with a melting point lower than those of the exposed wiring made of a conductive material such as a metal on the bottom of the receptor  100  and the each electrode made of a conductive material such as a metal of the block  300 . 
     And, in the specification of the present invention, a color element is defined as a basic color of light, i.e., one of R (red), G (green) and B (blue), and a pixel  2  comprises three color elements R, G, and B as shown in  FIGS. 3 and 10 . 
     Referring to  FIGS. 3 to 32 , preferred embodiments of an AM-LED display apparatus and a fabricating method thereof according to the present invention are described in detail as follow: 
     [First Embodiment] 
     A structure of an AM-LED display apparatus according to a first embodiment of the present invention comprises basically, as shown in  FIG. 3 , a plurality of pixels  2  formed on the display substrate  3  and consisted of three color element units  1 , respectively. The each color element unit  1  comprises a switching transistor Tr 1 , a driving transistor Tr 2  and an LED. Here, the switching transistor Tr 1  and the driving transistor Tr 2  are built in the display substrate  3 . And the LED is formed by assembling an LED block  4  made previously into a block receptor formed on the substrate  3 . 
     A plane structure of one color element unit  1  according to the first embodiment is shown with a layout in  FIG. 4 . The structures formed on the same layer are marked with the same color in  FIG. 4 . 
     As shown in  FIGS. 4 to 8 , a structure according to the first embodiment is characterized by comprising: a buffer layer  20  formed on a substrate  10 ; a switching transistor Tr 1  active layer (not shown) and a driving transistor Tr 2  active layer  30  formed separately from each other and having a source  32  and a drain  34  in both sides of the each active layer on the buffer layer  20  in a color element unit  1 ; a first insulating layer  40  formed to cover the switching and the driving transistor active layers on the substrate  10 ; a scan line  80  formed across between the source and the drain of the switching transistor Tr 1  on the first insulating layer  40 ; a cathode line  60  formed parallel to and separately from the scan line  80  on the first insulating layer  40 ; a storage capacitor bottom electrode  50  formed across between the source and the drain of the driving transistor Tr 2  and connected electrically to the drain of the switching transistor Tr 1  on the first insulating layer  40  in a color element unit  1 ; a second insulating layer  70  formed to cover the scan line  80 , the cathode line  60  and the storage capacitor bottom electrode  50  on the first insulating layer  40 ; a data line  83  formed vertically to the scan line  80  and connected electrically to the source of the switching transistor Tr 1  on the second insulating layer  70 ; a power supply line  82  formed parallel to and separately from the data line  83  and connected electrically to the source  32  of the driving transistor Tr 2  on the second insulating layer  70 ; a storage capacitor top electrode  85  formed to overlap the storage capacitor bottom electrode  50  and connected electrically to the power supply line  82  on the second insulating layer  70  in a color element unit  1 ; an anode contact layer  84  formed between the data line  83  and the power supply line  82  and connected electrically to the drain  34  of the driving transistor Tr 2  on the second insulating layer  70  in a color element unit  1 ; an LED block receptor  41  formed with a third insulating layer  92  or  94  to cover at least one part of the data line  83 , the power supply line  82 , the storage capacitor top electrode  85  and the anode contact layer  84  on the second insulating layer  70  in a color element unit  1 ; a cathode eutectic layer  214  and an anode eutectic layer  212  formed separately from each other and connected electrically to the cathode line  60  and the anode contact layer  84 , respectively, in the LED block receptor  41 ; and an LED block  4  or  4   a  of the color element unit  1  assembled into the LED block receptor  41  through electrical connections of the cathode eutectic layer  214  and the anode eutectic layer  212  to a cathode electrode  46  or  46   a  and an anode electrode  47  or  47   a , respectively. 
     Here, the buffer layer  20  can be a silicon oxide layer or a silicon nitride layer, and the switching transistor Tr 1  active layer and the driving transistor Tr 2  active layer  30  can be an amorphous silicon layer. But the driving transistor Tr 2  active layer  30  is preferable to be a poly-silicon layer due to the operation of an LED by a driving current. 
     Additionally, the cathode eutectic layer  214  and the anode eutectic layer  212  are preferable to be a metal or a metal compound with a melting point lower than those of the scan line  80 , the cathode line  60 , the storage capacitor bottom electrode  50 , the data line  83 , the power supply line  82 , the storage capacitor top electrode  85  and the anode contact layer  84 . 
     Also, on the substrate assembled with the LED block  4  or  4   a , a thin film encapsulation layer (not shown) can be additionally formed. 
     In the structure according to the first embodiment, the LED block receptor  41  has preferably a recessed region with different plane structure depending on a color element  1  as shown in  FIG. 3  and the LED block  4  or  4   a  assembled into the LED block receptor  41  has also preferably an LED substrate  42  with a shape corresponded to the recessed region. 
     In this way, an LED display  3  can be evenly embodied with a plurality of pixels  2  consisted of three color elements R  4 , G  5  and B  6 , respectively. 
     More preferably, the LED block receptor  41  is formed to have the recessed region as a wide opening and a narrow bottom as shown in  FIG. 2  and the LED block  4  or  4   a  is formed to correspond to the shape of the LED block receptor  41 . 
     In this way, when each receptor receives each block by a self-shape recognition principle using gravity and/or fluid vibration, the mismatched blocks can be jumped out and the rightly received blocks are safely held by a capillary force. 
     On the other hand, the LED block  4  or  4   a  assembled into the LED block receptor  41  can be formed to have a conventional LED structure. However, for corresponding to the shape of each LED block receptor  41 , as shown in  FIG. 6 , the LED block  4  can be formed to have a p-type nitrogen compound semiconductor layer  43 /nitrogen compound activation layer  44 /n-type nitrogen compound semiconductor layer  45 /cathode electrode  46  and a p-type nitrogen compound semiconductor layer  43 /anode electrode  47  near by in the same direction of each other on the LED substrate  42 , or as shown in  FIG. 7 , the LED block  4   a  can be formed to have an n-type nitrogen compound semiconductor layer  45   a /nitrogen compound activation layer  44   a /p-type nitrogen compound semiconductor layer  43   a /anode electrode  47   a  and an n-type nitrogen compound semiconductor layer  45   a /cathode electrode  46   a  near by in the same direction of each other on the LED substrate  42 . 
     Here, the LED substrate  42  can be a sapphire substrate. Depending on each color element, the nitrogen compound can be preferable to be MN, GaN, InN, or a compound of nitrogen and two or more elements of Al, Ga and In. The anode electrode  47  or  47   a  and the cathode electrode  46  or  46   a  can be preferable to be Ti, W, Cr, Au, Ag, Ni, or a compound comprising one or more elements of Ti, W, Cr, Au, Ag and Ni. 
     Also, the cathode eutectic layer  214  and the anode eutectic layer  212  can be preferable to be a metal, more preferably one of Sn, Pb, Bi and In, a compound comprising one or more elements of Sn, Pb, Bi and In, or a metal compound comprising one element of Sn, Pb, Bi and In and one or more elements of Ag, Sb, Cu, Zn and Mg. 
     Next, with respect to  FIGS. 1 to 9 , a method for fabricating the structure of an AM-LED display apparatus according to a first embodiment of the present invention is described in detail. 
     First, as a first step S 110 , as shown in  FIG. 8 , a buffer layer  20  is deposited on a display substrate  10  and a switching transistor active layer (not shown) and a driving transistor active layer  30  is formed on the buffer layer  20  in a color element unit. 
     As a second step S 120 , as shown in  FIGS. 4 and 8 , a first insulating layer  40  and a conductive material are deposited sequentially on a whole surface of the substrate and the conductive material is etched to form a scan line  80 , a cathode line  60  and a storage capacitor bottom electrode  50 . 
     As a third step S 130 , a second insulating layer  70  and a conductive material are deposited sequentially on a whole surface of the substrate and the conductive material is etched to form a data line  83 , a power supply line  82 , a storage capacitor top electrode  85  and an anode contact layer  84 . 
     Here, after depositing the second insulating layer  70 , via holes are formed for contacting a source of a switching transistor, a source  32  and a drain  34  of a driving transistor before depositing the conductive material on the second insulating layer  70 . 
     As a fourth step S 140 , as shown in  FIG. 5 , a third insulating layer is deposited on a whole surface of the substrate and etched to form an LED block receptor  41  in a color element unit and a cathode eutectic layer  214  and an anode eutectic layer  212  are formed in the LED block receptor  41 . 
     At this time, the LED block receptor  41 , as shown in  FIG. 3 , can be formed to have a different shape depending on a color element, and additionally, can be preferable to be formed to have a recessed region with a wide opening and a narrow bottom as shown in  FIG. 2 . 
     As a fifth step S 150 , as shown in  FIG. 8 , an LED block  4  or  4   a  of the color element unit is assembled into the LED block receptor  41  by a fluidic self-assembly (FSA). 
     Here, the LED block  4  or  4   a  is fabricated by a separated process, which comprises forming a PN diode on an LED substrate (S 210 ), forming an anode/a cathode electrode (S 220 ) and forming an LED block  4  or  4   a  corresponded to the shape of an LED block receptor  41  by dicing saw (S 230 ). 
     By the separating process, the LED block  4  or  4   a  is also fabricated to have a different shape depending on a color element and is put onto a substrate formed with the corresponding LED block receptor  41  and immersed in a fluid. 
     In the fluid, the LED block  4  or  4   a  can be moved by gravity and/or fluid vibration and can be safely received in the corresponding LED block receptor  41  by a self-shape recognition principle or hydrophilic and hydrophobic properties. 
     When each LED block receptor is formed to have a recessed region with a wide opening and a narrow bottom as shown in  FIG. 2  and the LED block  4  or  4   a  is formed to correspond to the each LED block receptor  41  as mentioned above, the mismatched blocks can be jumped out by gravity and/or fluid vibration and the rightly received blocks are safely held by a capillary force. 
     After the LED block  4  or  4   a  is safely received into the LED block receptor  41 , the temperature of the fluid is increased to the lowest melting point of the eutectic layers  212  and  214  and then decreased to completely assemble the cathode  46  or  46   a  and the anode  47  or  47   a  of the each LED block  4  or  4   a  with the exposed wirings in the LED block receptor  41 . 
     The rate of assembly of the blocks into the each receptor can be increased by repeating the fifth step. 
     After the fluidic self-assembly (FSA) process in the fifth step, a vacant receptor in the entire pixels of display can be detected and saved with a coordinate site by using an automated optical inspection (AOI) and then can be assembled with the corresponded block by pick-and-place process using a robot. 
     The others, the undescribed parts, can be referred to the U.S. Pat. No. 5,545,291 related to the FSA process. 
     A further step S 160 , as an option, can be processed to form a thin film encapsulation layer on the substrate assembled with the LED block  4  or  4   a.    
     [Second Embodiment] 
     A structure of an AM-LED display apparatus according to a second embodiment of the present invention comprises basically, as shown in  FIG. 10 , a plurality of pixels  2  formed on the display substrate  3  and consisted of three color element units  1 , respectively. The each color element unit  1  is formed by assembling a switching transistor block  7 , a driving transistor block  8  and an LED block  4  made previously into a switching transistor block receptor, a driving transistor block receptor and an LED block receptor, respectively, which are formed on the substrate  3 . 
     The plane structure of one color element unit  1  according to the second embodiment is shown with a layout in  FIG. 11 . The structures formed on the same layer are marked with the same color in  FIG. 11 . 
     As shown in  FIGS. 11 to 19 , a structure according to the second embodiment is characterized by comprising: a data line  83   a , a scan line  80  and a cathode line  60  formed parallel to and separately from each other on a substrate  10 ; a storage capacitor bottom electrode  50  formed between the scan line  80  and the cathode line  60  in a color element unit; a first insulating layer  72  formed to cover the data line  83   a , the scan line  80 , the cathode line  60  and the storage capacitor bottom electrode  50  on the substrate  10 ; a power supply line  82  formed vertically to the data line  83   a  on the first insulating layer  72 ; a storage capacitor top electrode  85  formed to overlap the storage capacitor bottom electrode  50  and connected electrically to the power supply line  82  on the first insulating layer  72  in a color element unit; an anode contact layer  84  formed separately from the power supply line  82  on the first insulating layer  72  in a color element unit; a switching transistor receptor  71 , a driving transistor receptor  81  and a LED block receptor  41  formed with a second insulating layer  91 ,  91   a ,  93 ,  93   a  or  95  to cover at least one part of the power supply line  82 , the storage capacitor top electrode  85  and the anode contact layer  84  on the first insulating layer  72  in a color element unit; a source eutectic layer  232 , a gate eutectic layer  234  and a drain eutectic layer  236  of a switching transistor formed separately from each other and connected electrically to the data line  83   a , the scan line  81  and the storage capacitor bottom electrode  50 , respectively, in the switching transistor receptor  71 ; a gate eutectic layer  224 , a source eutectic layer  222  and a drain eutectic layer  226  of a driving transistor formed separately from each other and connected electrically to the storage capacitor bottom electrode  50 , the power supply line  82  and the anode contact layer  84 , respectively, in the driving transistor receptor  81 ; a cathode eutectic layer  214  and an anode eutectic layer  212  formed separately from each other and connected electrically to the cathode line  60  and the anode contact layer  84 , respectively, in the LED block receptor  41 ; a switching transistor block  7  of the color element unit assembled into the switching transistor receptor  71  through electrical connections of the source eutectic layer  232 , the gate eutectic layer  234  and the drain eutectic layer  236  of the switching transistor to a source electrode  77 , a gate electrode  78  and a drain electrode  79  of the switching transistor block, respectively; a driving transistor block  8  of the color element unit assembled into the driving transistor receptor  81  through electrical connections of the source eutectic layer  222 , the gate eutectic layer  224  and the drain eutectic layer  226  of the driving transistor to a source electrode  807 , a gate electrode  808  and a drain electrode  809  of the driving transistor block, respectively; and an LED block  4  or  4   a  of the color element unit assembled into the LED block receptor  41  through electrical connections of the cathode eutectic layer  214  and the anode eutectic layer  212  to a cathode electrode  46  or  46   a  and an anode electrode  47  or  47   a  of the LED block, respectively. 
     Here, the switching transistor Tr 1  and the driving transistor Tr 2  can be formed on an amorphous or polycrystal semiconductor substrate, but the driving transistor Tr 2  is preferable to be formed on a single-crystal silicon substrate due to the operation of an LED by a driving current. 
     Also, the each eutectic layer  212 ,  214 ,  222 ,  224 ,  226 ,  232 ,  234  or  236  is preferable to be a metal or a metal compound with a meting point lower than those of the scan line  80 , the cathode line  60 , the storage capacitor bottom electrode  50 , the power supply line  82 , the storage capacitor top electrode  85 , the anode contact layer  84 , the each source electrode  77  or  807 , the each gate electrode  78  or  808  and the each drain electrode  79  or  809 . 
     As an optional step, as shown in  FIG. 17 , a thin film encapsulation layer  99  can be formed on the substrate assembled with the switching transistor block  7 , the driving transistor block  8  and the LED block  4  or  4   a.    
     In the structure according to the second embodiment, the LED block receptor  41 , as shown in  FIG. 10 , has preferably a recessed region with different plane structure depending on the color element and the LED block  4  or  4   a  assembled into the LED block receptor  41  has also preferably an LED substrate  42  with a shape corresponded to the recessed region. 
     In this way, an LED display  3  can be evenly embodied with a plurality of pixels  2  consisted of three color elements R  4 , G  5  and B  6 , respectively. 
     Also, as shown in  FIG. 10 , the switching transistor block receptor  71  has preferably a recessed region with different plane structure from the driving transistor block receptor  81  and each transistor block  7  or  8  assembled into the each transistor block receptor  71  or  81  has also preferably a transistor substrate  73  or  803  with a shape corresponded to the recessed region. 
     In this way, as shown in  FIGS. 16 and 17 , when the height of the eutectic layers  222 ,  224 ,  226 ,  232 ,  234  and  236  contacted to each electrode of the each transistor is different each other, an only corresponding transistor can be selected to assemble. Also, only driving transistors Tr 2  formed on a single-crystal silicon substrate can be selected and used to assemble. 
     More preferably, as shown in  FIG. 2 , the LED block receptor  41  and the transistor block receptors  71  and  81  can be formed to have the recessed region with a wide opening and a narrow bottom, and the blocks  4 ,  4   a ,  7  and  8  can be formed to correspond to the shape of the each receptor. 
     In this case, when the blocks are safely received to the each receptor by a self-shape recognition principle using gravity and/or fluid vibration, the mismatched blocks can be jumped out and the rightly received blocks are safely held by a capillary force. 
     On the other hand, the LED block  4  or  4   a  assembled into the LED block receptor  41  can be formed to have a conventional LED structure. However, for corresponding to the shape of each LED block receptor  41 , as shown in  FIG. 6 , the LED block  4  can be formed to have a p-type nitrogen compound semiconductor layer  43 /nitrogen compound activation layer  44 /n-type nitrogen compound semiconductor layer  45 /cathode electrode  46  and a p-type nitrogen compound semiconductor layer  43 /anode electrode  47  near by in the same direction of each other on the LED substrate  42 , or as shown in  FIG. 7 , the LED block  4   a  can be formed to have an n-type nitrogen compound semiconductor layer  45   a /nitrogen compound activation layer  44   a /p-type nitrogen compound semiconductor layer  43   a /anode electrode  47   a  and an n-type nitrogen compound semiconductor layer  45   a /cathode electrode  46   a  near by in the same direction of each other on the LED substrate  42 . 
     Also, the transistor blocks  7  and  8  assembled into the each transistor block receptor  71  or  81  can be formed to have a conventional transistor structure. However, for corresponding to the shape of the each transistor block receptor  71  or  81 , as shown in  FIGS. 18 and 19 , the various structures of the transistor blocks can be formed and be used as followings: sources  74  and  804  and drains  75  and  805  are formed on the SOI substrates  73  and  803 , respectively and then each source electrode  77  or  807  and each drain electrode  79  or  809  are connected to the source  74  or  804  and the drain  75  or  805 , respectively and each gate electrode  78  or  808  is formed on a gate insulator  76  or  806  with a gate (in  FIG. 18 ) or without a gate (in  FIG. 19 ). 
     Here, the LED substrate  42  can be a sapphire substrate. Depending on each color element, the nitrogen compound can be preferable to be MN, GaN, InN, or a compound of nitrogen and two or more elements of Al, Ga and In. The each electrode  47 ,  47   a ,  46 ,  46   a ,  50 ,  77 ,  78 ,  79 ,  85 ,  807 ,  808  or  809  can be preferable to be Ti, W, Cr, Au, Ag, Ni, or a compound comprising one or more elements of Ti, W, Cr, Au, Ag and Ni. 
     Also, the each eutectic layer  212 ,  214 ,  222 ,  224 ,  226 ,  232 ,  234  or  236  can be preferable to be a metal, more preferably one of Sn, Pb, Bi and In, a compound comprising one or more elements of Sn, Pb, Bi and In, or a metal compound comprising one element of Sn, Pb, Bi and In and one or more elements of Ag, Sb, Cu, Zn and Mg. 
     Next, with respect to  FIGS. 10 to 20 , a method for fabricating the structure of an AM-LED display apparatus according to a second embodiment of the present invention is described in detail. 
     First, as a first step S 310 , as shown in  FIG. 16 , a conductive material is deposited on a display substrate  10  and the conductive material is etched to form a scan line  80 , a cathode line  60  and a storage capacitor bottom electrode  50 . 
     As a second step S 320 , as shown in  FIG. 17 , a first insulating layer  72  and a conductive material are deposited sequentially on a whole surface of the substrate and the conductive material is etched to form a power supply line  82 , a storage capacitor top electrode  85  and an anode contact layer  84 . 
     As a third step S 330 , as shown in  FIGS. 12 and 13 , a second insulating layer is deposited on a whole surface of the substrate and etched to form a switching transistor block receptor  71 , a driving transistor block receptor  81  and an LED block receptor  41  in a color element unit, and eutectic layers  212 ,  214 ,  222 ,  224 ,  226 ,  232 ,  234  and  236  are formed in the each receptor. 
     At this time, as shown in  FIG. 10 , the LED block receptor  41  can be formed to have a different shape depending on a color element and the each transistor block receptor  71  or  81  can be formed to have a different shape depending on the function. Additionally, all the receptors  41 ,  71  and  81  can be preferable to be formed to have a recessed region with a wide opening and a narrow bottom as shown in  FIG. 2 . 
     Also, after forming the receptors  41 ,  71  and  81 , via holes are formed for connecting electrically to each wiring on the bottom layer before forming the eutectic layers. 
     As a fourth step S 340 , as shown in  FIGS. 14 to 16 , a switching transistor block  7 , a driving transistor block  8  and an LED block  4  are assembled into the each receptor  41 ,  71  or  81  by a fluidic self-assembly (FSA). 
     Here, the each transistor block  7  or  8  is fabricated by a separated process, as shown in  FIG. 18  or  19 , namely, which comprises forming a source  74  or  804 /a drain  75  or  805  on a SOI substrate  73  or  803  consisted of a bottom substrate  70  or  801 /a buried oxide layer  72  or  802 /a top substrate (S 410 ), forming contact electrodes  77 ,  78  and  79 ;  807 ,  808  and  809  (S 420 ), dividing the devices to have a different shape depending on the usage or function (S 430 ) and etching the buried oxide layer  72  or  802  by HF solution to form the each transistor block  7  or  8  (S 440 ). 
     Also, the LED block  4  or  4   a  is fabricated by a separated process, which comprises forming a PN diode on an LED substrate (S 510 ), forming an anode/a cathode electrode (S 520 ) and forming an LED block  4  or  4   a  corresponded to the shape of an LED block receptor  41  by dicing saw (S 530 ). 
     By the separating process, the transistor blocks  7  and  8  and the LED block  4  or  4   a  are fabricated to have different shapes depending on the usage and the color element, respectively and are put onto a substrate formed with the corresponding block receptors  41 ,  71  and  81  and immersed in a fluid. 
     In the fluid, the blocks can be moved by gravity and/or fluid vibration and can be safely received in the each corresponding receptor  41 ,  71  or  81  by a self-shape recognition principle or hydrophilic and hydrophobic properties. 
     When the receptors  41 ,  71  and  81  are formed to have a recessed region with a wide opening and a narrow bottom, respectively, as shown in  FIG. 2  and the blocks  4 ,  4   a ,  7  and  8  are formed to correspond to the each receptor  41 ,  71  or  81 , as mentioned above, the mismatched blocks can be jumped out by gravity and/or fluid vibration and the rightly received blocks are safely held by a capillary force. 
     After the blocks  4 ,  4   a ,  7  and  8  are safely received into the each receptor  41 ,  71  or  81 , the temperature of the fluid is increased to the lowest meting point of the eutectic layers  212 ,  214 ,  222 ,  224 ,  226 ,  232 ,  234  and  236  and then decreased to completely assemble the electrodes of the safely received block with the exposed wirings in the each receptor. 
     The rate of assembly of the blocks into the each receptor can be increased by repeating the fourth step. 
     After the fluidic self-assembly (FSA) process in the fourth step, a vacant receptor in the entire pixels of display can be detected and saved with a coordinate site by using an automated optical inspection (AOI) and then can be assembled with the corresponded block by pick-and-place process using a robot. 
     The others, the undescribed parts, can be referred to the U.S. Pat. No. 5,545,291 related to the FSA process. 
     An optional step S 350 , as shown in  FIG. 17 , can be further processed to form a thin film encapsulation layer  99  on the substrate assembled with the blocks  4 ,  4   a ,  7  and  8 . 
     [Third Embodiment] 
     A structure of an AM-LED display apparatus according to a third embodiment of the present invention comprises basically, as shown in  FIG. 10 , a plurality of pixels  2  formed on the display substrate  3  and consisted of three color element units  1 , respectively. The each color element unit  1  is formed by assembling a switching transistor block  7 , a driving transistor block  8  and an LED block  4  made previously into a switching transistor block receptor, a driving transistor block receptor and an LED block receptor, respectively, which are formed on the substrate  3 . 
     The plane structure of one color element unit  1  according to the third embodiment is shown with a layout in  FIG. 21 . The structures formed on the same layer are marked with the same color in  FIG. 21 . 
     As shown in  FIGS. 21 to 31 , a structure according to the third embodiment is characterized by comprising: a power supply line  82   a  formed on a substrate  10 ; a storage capacitor bottom electrode  85   a  connected electrically and vertically to the power supply line  82   a  on the substrate in a color element unit; a first insulating layer  74  formed to cover the power supply line  82   a  and the storage capacitor bottom electrode  85   a  on the substrate; a data line  83   b  and a scan line  80   a  formed parallel to each other and formed vertically to the power supply line  82   a  on the first insulating layer; a storage capacitor top electrode  50   a  formed to overlap the storage capacitor bottom electrode  85   a  and near by the scan line  80   a  on the first insulating layer in a color element unit; an anode contact layer  84   a  formed separately from and near by the storage capacitor top electrode  50   a  on the first insulating layer in a color element unit; a switching transistor block receptor (not shown), a driving transistor block receptor  81  and an LED block receptor  41  formed with a second insulating layer  91 ,  92  or  94  to cover at least one part of the data line  83   b , the scan line  80   a , the storage capacitor top electrode  50   a  and the anode contact layer  84   a  on the first insulating layer in a color element unit; a source eutectic layer (not shown), a gate eutectic layer (not shown) and a drain eutectic layer (not shown) of the switching transistor formed separately from each other and connected electrically to the data line  83   b , the scan line  80   a  and the storage capacitor top electrode  50   a , respectively, in the switching transistor block receptor (not shown); a gate eutectic layer  244 , a source eutectic layer  242  and a drain eutectic layer  246  of a driving transistor formed separately from each other and connected electrically to the storage capacitor top electrode  50   a , the power supply line  82   a  and the anode contact layer  84   a , respectively, in the driving transistor block receptor  81 ; an anode eutectic layer  216  connected electrically to the anode contact layer  84   a  in the LED block receptor  41 ; a switching transistor block (not shown) of the color element unit assembled into the switching transistor block receptor (not shown) through electrical connections of the source eutectic layer (not shown), the gate eutectic layer (not shown) and the drain eutectic layer (not shown) of the switching transistor to a source electrode, a gate electrode and a drain electrode of the switching transistor block, respectively; a driving transistor block  8  of the color element unit assembled into the driving transistor block receptor  81  through electrical connections of the source eutectic layer  242 , the gate eutectic layer  244  and the drain eutectic layer  246  of the driving transistor to a source electrode, a gate electrode and a drain electrode of the driving transistor block, respectively; an LED block  4   b  or  4   c  of the color element unit assembled into the LED block receptor  41  through electrical connection of the anode eutectic layer  216  to an anode electrode  47   b  or  47   c  of the LED block; a color element defining layer  96  formed with a third insulating layer to expose a part of the LED block  4   b  or  4   c  on the substrate assembled with the each block; and a cathode contact layer, more preferably a cathode line,  60   a  formed to connect electrically to the exposed part of the LED block  4   b  or  4   c  on the color element defining layer  96 . 
     Here, the switching transistor Tr 1  and the driving transistor Tr 2  can be formed on an amorphous or polycrystal semiconductor substrate, but the driving transistor Tr 2  is preferable to be formed on a single-crystal silicon substrate due to the operation of an LED by a driving current. 
     And the each eutectic layer is preferable to be a metal or a metal compound with a melting point lower than those of the power supply line  82 , the storage capacitor bottom electrode  85   a , the data line  83   b , the scan line  80   a , the storage capacitor top electrode  50   a , the anode contact layer  84   a , the each source electrode, the each gate electrode and the each drain electrode. 
     Also, as shown in  FIGS. 29 to 31 , the LED block  4   c  can be electrically connected to the cathode contact layer  60   a  through the cathode electrode  46   c  formed on one side of the LED block. 
     In the structure according to the third embodiment, the LED block receptor  41  has preferably a recessed region with different plane structure depending on the color element as shown in  FIG. 10  and the LED block  4   b  or  4   c  assembled into the LED block receptor  41  has also preferably a shape corresponded to the recessed region. 
     In this way, an LED display  3  can be evenly embodied with a plurality of pixels  2  consisted of three color elements R  4 , G  5  and B  6 , respectively. 
     Also, as shown in  FIG. 10 , the switching transistor block receptor has preferably a recessed region with different plane structure from the driving transistor block receptor  81  and each transistor block  7  or  8  assembled into the each transistor block receptor has also preferably a transistor substrate  73  or  803  with a shape corresponded to the recessed region. 
     In this way, when the height of the eutectic layers contacted to each electrode of the each transistor is different each other, an only corresponding transistor can be selected to assemble. Also, only driving transistors Tr 2  formed on a single-crystal silicon substrate can be selected and used to assemble. 
     More preferably, as shown in  FIG. 2 , the LED block receptor  41  and the transistor block receptors  81  can be formed to have the recessed region with a wide opening and a narrow bottom, and the blocks  4   b ,  4   c ,  7  and  8  can be formed to correspond to the shape of the each receptor. 
     In this case, when the blocks are safely received to the each receptor by a self-shape recognition principle using gravity and/or fluid vibration, the mismatched blocks can be jumped out and the rightly received blocks are safely held by a capillary force. 
     On the other hand, the LED block assembled into the LED block receptor  41  can be formed to have a conventional LED structure. However, for corresponding to the shape of each LED block receptor  41 , the LED block, as shown in  FIG. 24 , can be stacked sequentially from the bottom to have an n-type compound semiconductor  45   b /compound activation layer  44   b /p-type compound semiconductor  43   b  with a shape of a wide bottom and a narrow top for reversely assembling in a receptor or the LED block, as shown in  FIG. 25 , can be stacked sequentially from the bottom to have an anode electrode  47   c /LED substrate as SiC  42   c /p-type compound semiconductor  43   c /compound activation layer  44   c /n-type compound semiconductor  45   c /cathode electrode  46   c  with a shape of a wide top and a narrow bottom for directly assembling in a receptor. 
     Also, the transistor blocks  7  and  8  assembled in the each transistor block receptor can be formed to have a conventional structure of transistor. However, for corresponding to the shape of the each transistor block receptor, the transistor blocks  7  and  8 , as shown in  FIGS. 18 and 19 , can be formed and be used as followings: sources  74  and  804  and drains  75  and  805  are formed on the SOI substrates  73  and  803 , respectively and then each source electrode  77  or  807  and each drain electrode  79  or  809  are connected to the source  74  or  804  and the drain  75  or  805 , respectively and each gate electrode  78  or  808  is formed on a gate insulator  76  or  806  with a gate (in  FIG. 18 ) or without a gate (in  FIG. 19 ). 
     Here, the LED substrate  42  can be a sapphire substrate. The compound semiconductor can be preferable to be GaAs, AlN, GaN, InN, or a compound of nitrogen and two or more elements of Al, Ga and In. The each electrode can be preferable to be Ti, W, Cr, Au, Ag, Ni, or a compound comprising one or more elements of Ti, W, Cr, Au, Ag and Ni. 
     Also, the each eutectic layer can be preferable to be a metal, more preferably one of Sn, Pb, Bi and In, a compound comprising one or more elements of Sn, Pb, Bi and In, or a metal compound comprising one element of Sn, Pb, Bi and In and one or more elements of Ag, Sb, Cu, Zn and Mg. 
     Next, with respect to  FIGS. 21 to 32 , a method for fabricating the structure of an AM-LED display apparatus according to a third embodiment of the present invention is described in detail. 
     First, as a first step S 610 , as shown in  FIG. 22 , a conductive material is deposited on a display substrate  10  and the conductive material is etched to form a power supply line  82   a  and a storage capacitor bottom electrode  85   a.    
     As a second step S 620 , as shown in  FIG. 21 , a first insulating layer and a conductive material are deposited sequentially on a whole surface of the substrate and the conductive material is etched to form a data line  83   b , a scan line  80   a , a storage capacitor top electrode  50   a , and an anode contact layer  84   a.    
     As a third step S 630 , as shown in  FIG. 22 , a second insulating layer is deposited on a whole surface of the substrate and etched to form a switching transistor block receptor (not shown), a driving transistor block receptor  81  and an LED block receptor  41  in a color element unit, and eutectic layers  212 ,  214 ,  222 ,  224 ,  226 ,  232 ,  234  and  236  are formed in the each receptor. 
     At this time, as shown in  FIG. 10 , the LED block receptor  41  can be formed to have a different shape depending on a color element and the each transistor block receptor  81  can be formed to have a different shape depending on the function. Additionally, all the receptors  41  and  81  can be preferable to be formed to have a recessed region with a wide opening and a narrow bottom as shown in  FIG. 2 . 
     Also, after forming the receptors, via holes are formed for connecting electrically to each wiring on the bottom layer before forming the eutectic layers. 
     As a fourth step S 640 , as shown in  FIGS. 26 to 29 , a switching transistor block  7 , a driving transistor block  8  and an LED block  4   b  or  4   c  are assembled into the each corresponding receptor by a fluidic self-assembly (FSA). 
     Here, the each transistor block  7  or  8  is fabricated by a separated process, as shown in  FIG. 18  or  19 , namely, which comprises forming a source  74  or  804 /a drain  75  or  805  on a SOI substrate  73  or  803  consisted of a bottom substrate  70  or  801 /a buried oxide layer  72  or  802 /a top substrate (S 710 ), forming the contact electrodes  77 ,  78  and  79 ;  807 ,  808  and  809  (S 720 ), dividing the devices to have a different shape depending on the usage or function (S 730 ) and etching the buried oxide layer  72  or  802  by HF solution to form the each transistor block  7  or  8  (S 740 ). 
     Also, the LED block  4   b  is fabricated by a separated process, as shown in  FIGS. 23 and 24 , which comprises depositing a sacrificial layer  42   b  and forming a PN diode on an LED substrate  42   a  (S 810 ), forming an anode electrode  47   b  and dividing the devices to fit a shape of an LED block receptor (S 820 ), and etching the sacrificial layer  42   b  by wet etching to form the LED block  4   b  (S 830 ). 
     By the separating process, the transistor blocks  7  and  8  and the LED block  4   b  or  4   c  are fabricated to have different shapes depending on the usage and the color element, respectively and are put onto a substrate formed with the corresponding block receptors  41  and  81  and immersed in a fluid. 
     In the fluid, the blocks can be moved by gravity and/or fluid vibration and can be safely received in the each corresponding receptor  41  or  81  by a self-shape recognition principle or hydrophilic and hydrophobic properties. 
     When the receptors  41  and  81  are formed to have a recessed region with a wide opening and a narrow bottom, respectively, as shown in  FIG. 2  and the blocks  4   b ,  4   c ,  7  and  8  are formed to correspond to the each receptor, as mentioned above, the mismatched blocks can be jumped out by gravity and/or fluid vibration and the rightly received blocks are safely held by a capillary force. 
     After the blocks  4   b ,  4   c ,  7  and  8  are safely received into the each receptor  41  or  81 , the temperature of the fluid is increased to the lowest meting point of the eutectic layers and then decreased to completely assemble the electrodes of the safely received block with the exposed wirings in the each receptor. 
     The rate of assembly of the blocks into the each receptor can be increased by repeating the fourth step. 
     After the fluidic self-assembly (FSA) process in the fourth step, a vacant receptor in the entire pixels of display can be detected and saved with a coordinate site by using an automated optical inspection (AOI) and then can be assembled with the corresponded block by pick-and-place process using a robot. 
     The others, the undescribed parts can be referred to the U.S. Pat. No. 5,545,291 related to the FSA process. 
     As a fifth step S 650 , as shown in  FIG. 27  or  30 , a third insulating layer is deposited on a whole surface of the substrate and etched to form a color element defining layer  96  and a part of the assembled LED block  4   b  or  4   c  is exposed through a hole  96   a  of the color element defining layer  96 . 
     As a sixth step S 660 , as shown in  FIG. 28  or  31 , a transparent or semitransparent conductive material is deposited on a whole surface of the substrate to form a cathode contact layer, more preferably a cathode line,  60   a  connected electrically to the exposed LED block  4   b  or  4   c.    
     By the above-mentioned, the concreted embodiments of an AM-LED display apparatus and a fabrication method thereof according to the present invention are described in detail. However, because it is described to be understood and practiced by a person with ordinary skill in the art, the expression of the source/drain of the each transistor can be expressed by change each other in the mentioned embodiments. Also, the stacking sequence of the LED and the place of the cathode and the anode electrodes in the mentioned embodiments can be allowed to change.