Patent Description:
Recently, a semiconductor-based light emitting diode (LED) has been used in various industries such as display applications because of its high light-emitting efficiency and long lifespan. A micro LED device has attracted much attention as a light source that forms individual pixel elements in a related art display device.

In a manufacturing process of an LED display panel, there is an issue associated with characteristic improvement of a partition wall separating light emitting regions of the LED device and efficiency of the manufacturing method thereof, together with issues such as the improvement of light-emitting efficiency, and the precision and efficiency of a transfer process.

When a partition wall is manufactured by photolithography using a photo-resin, there is a limit on the rigidity of a partition wall against a weight load and external pressure that may be generated in the manufacturing process of the display panel. Further, it is difficult to expect a reflection effect on the light emitted from the LED device. In addition, there is an increasing demand to simplify and ease a partition wall manufacturing process.

Meanwhile, a micro LED (mLED or µLED) display panel is a kind of flat display panel and may consist of a plurality of inorganic light emitting diodes (inorganic LEDs), each of which is in a size of smaller than <NUM> micrometers. Compared to a liquid crystal display (LCD) panel which needs a backlight, a micro LED display panel provides better contrast, response time, and energy efficiency. Also, while both of an organic light emitting diode (organic LED) and a micro LED have good energy efficiency, a micro LED has an advantage that it has better brightness and light emitting efficiency, and a longer lifespan than an OLED.

<CIT> describes an LED device for realizing multi-colors.

<CIT> describes a micro display panel with integrated micro-reflector.

The invention provides a display module including a high-performance partition wall, a display device, and an efficient method for manufacturing the display module including a high-performance partition wall.

Additional aspects will be set forth in part in the description which follows and, in part, will be apparent from the description or may be learned by practice of the presented embodiments.

In accordance with an aspect of the invention, a display module including: a plurality of light-emitting diodes (LEDs); a driving substrate; a driving circuit on an upper portion of the driving substrate and configured to drive the plurality of LEDs; a plurality of partition walls configured to divide light-emitting regions by each of the plurality of LEDs; and reflective layers formed on both sides of each of the plurality of partition walls.

Each of the plurality of partition walls is a part of a plurality of protrusions formed by etching of a growth substrate to form the plurality of LEDs; and the plurality of protrusions is, in accordance with the invention, formed before a plurality of semiconductor layers included in the plurality of LEDs is formed on the growth substrate.

Each of the plurality of partition walls may be formed to have a predetermined height so that wavelengths of light emitted from each of the plurality of LEDs do not overlap each other.

A width of each of the plurality of partition walls may narrow as a height increases toward an upper portion.

The display module may further include: a plurality of pixels in a matrix form, wherein the plurality of pixels may each include a red (R) sub pixel, a green (G) sub pixel, and a blue (B) sub pixel, and wherein the R-sub pixel, the G-sub pixel, and the B-sub pixel may each correspond to one LED device among the plurality of LEDs.

The display module may further include: a color conversion layer at a space between the plurality of partition walls, wherein the space between the plurality of partition walls may be formed based on a plurality of depressions formed along with the plurality of protrusions on the growth substrate, and wherein the color conversion layer may include a quantum dot (QD) or phosphor.

Each of the plurality of partition walls may include silicon.

The reflector layer may include at least one of aluminum (Al) and aluminum nitride (AlN).

The reflector layer may include: a first reflector layer including aluminum; a second reflector layer on the first reflector layer and including aluminum nitride; and a third reflector layer on the second reflector layer and including aluminum.

Each of the plurality of LEDs may be a micro LED device in a flip-chip type.

In accordance with another aspect of the invention, a method for manufacturing a display module includes: forming a plurality of light emitting diodes (LEDs); and forming a plurality of partition walls that divide light-emitting regions by each of the plurality of LEDs, wherein the forming the plurality of LEDs includes: etching a growth substrate to form a plurality of LEDs and forming a plurality of protrusions and a plurality of depressions on the growth substrate; and forming a reflector layer on a surface of the plurality of protrusions and a surface of the plurality of depressions, and wherein the forming the plurality of partition walls includes removing a part of the growth substrate so that the plurality of partition walls are formed based on the plurality of protrusions, and a space between the plurality of partition walls is formed based on the plurality of depressions.

The forming the plurality of LEDs further includes, in accordance with the invention: growing an n-type semiconductor layer on the reflector layer formed on a top surface of the plurality of protrusions in a horizontal direction; re-growing the n-type semiconductor layer grown in the horizontal direction; forming a light-emitting layer and a p-type semiconductor layer on the regrown n-type semiconductor layer; forming a region for dividing each of the plurality of LEDs and a region for disposing an n-type electrode by etching the n-type semiconductor layer, the light-emitting layer, and the p-type semiconductor layer; and forming the n-type electrode electrically connected to the n-type semiconductor layer on a region to dispose the n-type electrode, and forming, on the p-type semiconductor, the p-type electrode electrically connected to the p-type semiconductor.

A width of each of the plurality of partition walls may narrow as a height approaches toward an upper portion.

The method may further include: forming a color conversion layer at a space between the plurality of partition walls, wherein the color conversion layer may include a quantum dot (QD) or phosphor.

In accordance with another aspect of the invention, a display device includes: a plurality of display modules according to the invention;
and a support plate configured to support the plurality of display modules.

The above and other aspects, features, and advantages of certain embodiments of the present invention will be more apparent from the following description taken in conjunction with the accompanying drawings, in which:.

However, it may be understood that the disclosure is not limited to the embodiments described hereinafter, but also includes various modifications, equivalents, and/or alternatives of these embodiments. In relation to explanation of the drawings, similar drawing reference numerals may be used for similar constituent elements.

In the following description, a detailed description of the related art may be omitted when it is determined that such description may obscure the gist of the disclosure.

In addition, the following embodiments may be combined and modified in many different forms, and the scope of the invention is not limited to the following examples.

The terms used herein are to describe certain embodiments and are not intended to limit the scope of claims that define the invention.

A singular expression includes a plural expression unless otherwise specified.

In this specification, expressions such as "have," "may have," "include," "may include" or the like represent presence of a corresponding feature (for example, components such as numbers, functions, operations, or parts) and does not exclude the presence of additional feature.

In this document, expressions such as "at least one of A [and/or] B," or "one or more of A [and/or] B," include all possible combinations of the listed items. For example, "at least one of A and B," or "at least one of A or B" includes any of (<NUM>) at least one A, (<NUM>) at least one B, or (<NUM>) at least one A and at least one B.

As used herein, the terms "first," "second," or the like may denote various components, regardless of order and/or importance, and may be used to distinguish one component from another, and does not otherwise limit the components.

If it is described that a certain element (e.g., first element) is "operatively or communicatively coupled with/to" or is "connected to" another element (e.g., second element), it should be understood that the certain element may be connected to the other element directly or through still another element (e.g., third element).

On the other hand, if it is described that a certain element (e.g., first element) is "directly coupled to" or "directly connected to" another element (e.g., second element), it may be understood that there is no element (e.g., third element) between the certain element and the another element.

The term "planar" in the disclosure means that no processing is performed during the formation of nonconductor/semiconductor/conductor layers, and the term "non-planar" means that the surface treatment is performed such that the surface area becomes greater than the "planar" during formation of the nonconductive/semiconductor/conductor layers. The "non-planar" is not limited to a particular type.

Also, the expression "configured to" used in the disclosure may be interchangeably used with other expressions such as "suitable for," "having the capacity to," "designed to," "adapted to," "made to," and "capable of," depending on cases. Meanwhile, the term "configured to" does not necessarily mean that a device is "specifically designed to" in terms of hardware.

Instead, under some circumstances, the expression "a device configured to" may mean that the device "is capable of" performing an operation together with another device or component. For example, the phrase "a processor configured to perform A, B, and C" may mean a dedicated processor (e.g., an embedded processor) for performing the corresponding operations, or a generic-purpose processor (e.g., a central processing unit (CPU) or an application processor) that can perform the corresponding operations by executing one or more software programs stored in a memory device.

The display device according to various embodiments may include, for example, a television, a monitor, a smartphone, a tablet personal computer (PC), a wearable device, a portable multimedia player, a digital camera, a portable device, or the like.

It is understood that various elements and regions in the figures are shown out of scale. Accordingly, the scope of the disclosure is not limited by the relative sizes or spacing drawn from the accompanying drawings.

Hereinafter, with reference to the attached drawings, embodiments will be described in detail so that those skilled in the art to which the invention belongs to can easily make and use the embodiments.

<FIG> is a cross-sectional diagram briefly illustrating a structure of a display module <NUM> according to an embodiment of the invention.

<FIG> includes a plurality of the same or substantially similar configurations and redundant reference numbers of the same components are omitted.

As illustrated in <FIG>, the display module <NUM> according to an embodiment includes a plurality of light emitting diodes (LEDs) <NUM>, a plurality of partition walls <NUM>, and a reflector layer <NUM>. Each of the plurality of LEDs <NUM> includes a plurality of semiconductor layers, an n-type electrode <NUM>, and a p-type electrode <NUM>. Further, the plurality of semiconductor layers includes an n-type semiconductor layer <NUM>, a p-type semiconductor layer <NUM>, and a light-emitting layer <NUM>.

The n-type semiconductor layer <NUM> and the p-type semiconductor layer <NUM> may be formed of a compound semiconductor such as a III-V group, a II-VI group, or the like. The n-type semiconductor layer <NUM> and the p-type semiconductor layer <NUM> may be formed of a nitride semiconductor layer. For example, the n-type semiconductor layer <NUM> may be an n-gallium nitride (GaN) semiconductor layer and the p-type semiconductor layer <NUM> may be a p-GaN semiconductor layer, although it is understood that one or more other embodiments are not limited thereto. That is, the n-type semiconductor layer <NUM> and the p-type semiconductor layer <NUM> may be made of various materials depending on the various characteristics required, designed, or used for the LED device <NUM>.

The n-type semiconductor is a semiconductor in which free electrons are used as a carrier for relocating charges, and may be formed by doping an n-type dopant such as Si, Ge, Sn, Te, or the like. The p-type semiconductor is a semiconductor in which a hole is used as a carrier for relocating charges and may be formed by doping a p-type dopant such as Mg, Zn, Ca, Ba, or the like.

The light-emitting layer <NUM>, the n-type semiconductor layer <NUM>, and the p-type semiconductor layer <NUM> may be formed of various semiconductors having a band gap corresponding to a specific region within the spectrum. For example, a red LED device <NUM> having a light wavelength of <NUM>-<NUM> may include one or more layers based on an AlInGaP-based semiconductor. A blue LED device <NUM> having a light wavelength of <NUM>-<NUM> and a green LED device <NUM> having a light wavelength of <NUM>-<NUM> may each include one or more layers based on an AlInGaN-based semiconductor.

The light-emitting layer <NUM> is disposed between the n-type semiconductor layer <NUM> and the p-type semiconductor layer <NUM>, and is a layer in which an electron that is a carrier of the n-type semiconductor layer <NUM> and a home that is a carrier of the p-type semiconductor layer <NUM> meet. When (or based on) the electron and hole meet in the light-emitting layer <NUM>, a potential barrier is formed as the electron and hole are recombined. When (or based on) the electron and hole transition beyond a potential barrier to a low energy level according to an applied voltage, light of a corresponding wavelength is emitted.

The light-emitting layer <NUM> may have a multi-quantum wells (MQW) structure, although it is understood that one or more other embodiments are not limited thereto. For example, according to one or more other embodiments, the light-emitting layer <NUM> may have a variety of structures, such as a single quantum well (SQW) structure or a quantum dot (QD) structure. If the light-emitting layer <NUM> is formed in a MQW structure, the well layer/barrier layer of the light-emitting layer <NUM> may be formed in the same structure as, but not limited to, InGaN/GaN, InGaN/InGaN, GaAs(InGaGs)/AlGaAs, or the like. The number of quantum wells included in the light-emitting layer <NUM> is also not limited to a particular number.

In <FIG>, it is illustrated that the light-emitting layer <NUM> is formed on the n-type semiconductor layer <NUM> and the p-type semiconductor layer <NUM> is formed on the light-emitting layer <NUM>. It is understood, however, that it is also possible that the light-emitting layer <NUM> is formed on the p-type semiconductor layer <NUM> and the n-type semiconductor layer <NUM> is formed on the light-emitting layer <NUM>.

The plurality of partition walls <NUM> serve to distinguish the light-emitting regions for each of the plurality of LEDs <NUM>, and a structure including the plurality of partition walls <NUM> may be referred to as a so-called rib-structure. Specifically, each of the plurality of partition walls <NUM> may be formed to have a predetermined height so that the wavelengths of light emitted by each of the plurality of LED device <NUM> do not overlap with each other. For example, when the color conversion layer formed in the space between the plurality of partition walls <NUM> includes a quantum dot (QD), each of the plurality of partition walls <NUM> may be formed to have a height of <NUM> or more. As described below, when the color conversion layer formed in the space between the plurality of partition walls <NUM> includes a phosphor, each of the plurality of partition walls <NUM> may be formed to have a height of <NUM> or more.

The plurality of partition walls <NUM> according to an embodiment are formed by etching of the growth substrate to form the plurality of LEDs <NUM>. Specifically, the plurality of partition walls <NUM> are a part of a plurality of protrusions formed by etching of the growth substrate, wherein the plurality of protrusions are, in accordance with the invention, formed before a plurality of semiconductor layers included in the plurality of LEDs <NUM> are grown on the growth substrate. That is, the plurality of partition walls <NUM> according to the invention are not formed through a separate process after manufacturing of the LED device <NUM>, but are formed on the basis of the etching of the growth substrate performed before the plurality of semiconductor layers included in the LED device <NUM> are grown on the growth substrate. The process of forming the plurality of partition walls <NUM> is described below with reference to <FIG>, <FIG>, and <FIG>.

The reflector layer <NUM> is formed on both sides of each of the plurality of partition walls <NUM>. The reflector layer <NUM> reflects the light emitted from the LED device <NUM> so as not to be absorbed by the partition wall <NUM>, thereby improving the light extraction efficiency (LEE) of the LED device <NUM>. The reflector layer <NUM> may be composed of or include at least one of aluminum (Al) and aluminum nitride (AlN), but the material of the reflector layer <NUM> according to the disclosure is not limited to a particular material. The process of forming the reflector layer <NUM> is described below with reference to <FIG>, <FIG>, and <FIG>.

Specifically, the reflector layer <NUM> may be formed of an aluminum layer that is formed during epi growth by in-situ processing. In addition, the reflector layer may include a plurality of layers, and the outermost layer may include aluminum. For example, the reflector layer <NUM> may be composed of a multi-layer in a loop-layer structure including a first reflector layer of aluminum, a second reflector layer formed on the first reflector layer and made of aluminum nitride, and a third reflector layer formed on the second reflector layer and made of aluminum.

As another example, the reflector layer <NUM> may include a first reflector layer made of aluminum, a second reflector layer formed on the first reflector layer and made of sequentially stacked aluminum nitride, AlxGa1-xN (general formula:<NUM>=x<<NUM>) and aluminum nitride, and a third reflector layer formed on the second reflector layer and made of aluminum.

The thickness of the reflector layer <NUM> may be formed in several nanometers to dozens of nanometers. A material and thickness of the reflector layer <NUM> are not limited thereto.

It has been described that the reflector layer <NUM> is formed on both sides of each of the plurality of partition walls <NUM>, but it is understood that the reflector layer <NUM> may be additionally formed on the both sidewalls of the LED device <NUM> and on an opposite surface of the light emitting surface of the LED device <NUM>. In this case, the reflector layer <NUM> may be formed of a metal reflector or a distributed-Bragg-reflector structure.

As illustrated in <FIG>, the LED device <NUM> according to an embodiment may be implemented as a flip-chip type in which a first electrode and a second electrode are disposed toward the opposite surface of the light emitting surface of the LEDs <NUM>. The LED device <NUM> may be a micro LED device <NUM>. Specifically, the LED device <NUM> may be a micro LED device <NUM> having a width and a height length greater than or equal to <NUM> µm and less than or equal to <NUM> gm.

Further, the display module <NUM> includes a driving circuit which is described below with reference to <FIG>.

The display module <NUM> according to an embodiment may not only be implemented as a separate device, but may also be implemented as a unit for configuring the display panel. The plurality of display modules <NUM> may be connected in a matrix form to form one display panel. An example of a plurality of display modules <NUM> forming a display panel is described below with reference to <FIG>.

According to an embodiment as described above, since the plurality of partition walls <NUM> are formed based on a growth substrate of the LED device <NUM>, such as silicon, the stiffness and/or strength of the partition wall <NUM> is remarkably improved compared to the partition wall formed of the photo resin as in a related-art. Accordingly, the stability of the weight load, the external pressure, or the like, which may be generated throughout a manufacturing process of the display module <NUM>, may be expected. In addition, since the display module <NUM> according to an embodiment includes the reflector layer <NUM> formed on both sides of the partition wall <NUM>, improvement of light-emitting efficiency is expected.

According to an embodiment, light-emitting efficiency may be further improved according to angles of the plurality of partition walls <NUM>, which is described below with reference to <FIG> and <FIG>.

<FIG> illustrates a structure of a display module and <FIG> is a diagram illustrating light-emitting efficiency according to an angle of a plurality of partition walls <NUM> according to an embodiment.

The angle of the plurality of partition walls <NUM> may be determined so that the plurality of partition walls <NUM> do not limit the light-emitting efficiency of the plurality of LEDs <NUM> according to the angle. Further, the angle of the plurality of partition walls <NUM> may be determined to improve light-emitting efficiency. The reflector layer <NUM> is formed on both sides of the plurality of partition walls <NUM> according to an embodiment and thus, the angle of the plurality of partition walls <NUM>, and the angle of the reflector layer <NUM> may have a large effect on the light-emitting efficiency.

According to an embodiment, the width of each of the plurality of partition walls <NUM> narrows toward an upper portion. In this case, the width of each of the plurality of partition walls <NUM> (or barrier ribs) narrowing toward the upper part thereof may mean that an angle between the lower surface of the partition wall <NUM> and both sides of the partition wall <NUM> is less than <NUM> degrees with respect to a cross-section of the partition wall <NUM>. Hereinafter, the angle between the lower surface of the partition wall <NUM> and both sides of the partition wall <NUM> is referred to as an angle of the partition wall <NUM> with respect to the cross-section of the partition wall <NUM>.

If the angle of the partition wall <NUM> exceeds <NUM> degrees, the width of the light-emitting surface of the LED device <NUM> becomes narrower toward the upper portion, thereby reducing the light extraction efficiency (LEE) of the LED device <NUM>. Thus, the angle of each of the plurality of partition walls <NUM> according to an embodiment may be less than <NUM> degrees, as illustrated in <FIG>.

<FIG> illustrates a cross-sectional diagram of the display module <NUM> in which the angle of the partition wall <NUM> is <NUM> degrees. <FIG> is a graph showing external quantum efficiency (EQE) when the angle of the partition wall <NUM> is <NUM> degrees (<NUM>) and the angle of the barrier rib <NUM> is <NUM> degrees (<NUM>), respectively. The EQE is defined as the number of emitted photons being divided by the number of electrons injected, and is a function of the internal quantum efficiency (IQE) and light extraction efficiency of the LED device <NUM>. The light-emitting efficiency of the LED device <NUM> varies depending on the internal quantum efficiency and the external quantum efficiency.

As illustrated in <FIG>, when the angle of the partition wall <NUM> is <NUM> degrees <NUM>, the external quantum efficiency of the LED device <NUM> is improved compared to the case <NUM> where the angle of the barrier rib <NUM> is <NUM> degrees. The more the angle of the partition wall <NUM> is reduced from <NUM> degrees to <NUM> degrees, the more external quantum efficiency of the LED device <NUM> increases. Thus, the angle of the partition wall <NUM> according to one or more embodiments approaches <NUM> degrees.

As described above with reference to <FIG>, and described in detail below with reference to <FIG> and <FIG>, the plurality of partition walls <NUM> according to an embodiment is formed based on a plurality of protrusions formed before a plurality of semiconductor layers included in the LED device <NUM> are grown on the growth substrate. Accordingly, the angle of the partition wall <NUM> as described above with reference to <FIG> and <FIG> is also determined during the manufacturing process of the LED device <NUM>.

Although the above description is with respect to the angle of the plurality of partition wall <NUM>, it is assumed that the reflector layer <NUM> formed on both sides of the plurality of partition walls <NUM> has a layer structure, so that the angle of the plurality of partition walls <NUM> and the angle of the reflector layer <NUM> correspond to each other.

According to another embodiment, the angle of the partition wall <NUM> may itself be <NUM> degrees, and the reflector layer <NUM> formed on both sides of the plurality of partition walls <NUM> may have an angle of less than <NUM> degrees. In other words, the reflector layer <NUM> and a plurality of layers included in the reflector layer may be formed to become narrower toward the upper portion.

The method of manufacturing the display module <NUM> and an effect thereof will now be described below.

<FIG> is a flowchart briefly illustrating a method for manufacturing the display module <NUM> according to an embodiment; <FIG> is a flowchart illustrating each operation of <FIG> in greater detail. <FIG> and <FIG> are cross-sectional diagrams illustrating each operation of a method for manufacturing the display module <NUM> according to an embodiment.

Reference will now be made to <FIG> and <FIG> along with <FIG> and <FIG>. Since the configurations included in the display module <NUM> and the functions thereof have been described in detail with reference to <FIG>, a detailed description may not be repeated below. In <FIG>, a reference number is marked only for a configuration or a space formed in the corresponding step, to clarify the configurations formed in each operation.

As illustrated in <FIG>, a method of manufacturing the display module <NUM> according to an embodiment includes forming a plurality of LEDs <NUM> in operation S3100 and forming a plurality of partition walls <NUM> for dividing a light emitting region by each of the plurality of LEDs <NUM> in operation S3200. The forming the plurality of LEDs <NUM> in operation S3100 includes a plurality of operations S3110 to S3170 as shown in <FIG>. In addition, the forming the plurality of partition walls <NUM> in operation S3200 may be performed in the same manner as operation S3210 of <FIG>.

<FIG> illustrates a growth substrate <NUM> for forming the LED device <NUM> according to an embodiment. The growth substrate <NUM> may be a material suitable for the growth of a semiconductor, a carrier wafer, or the like. The growth substrate <NUM> may be made of a material such as silicon (Si) or sapphire (Al2SO4), but may also be made of a material such as SiC, GaN, GaAs, ZnO, or the like.

The growth substrate <NUM> according to an embodiment is preferably composed of silicon (Si). As described below, in the case of the silicon growth substrate <NUM>, it is easy to etch the growth substrate <NUM> such that each of the plurality of partition walls <NUM> is formed to a predetermined height so that the wavelengths of light emitted by each of the plurality of LED light emitting elements <NUM> do not overlap each other. However, the growth substrate <NUM> used in the disclosure is not limited to the growth substrate <NUM> of a particular material.

When the growth substrate <NUM> is provided, as illustrated in <FIG>, the growth substrate <NUM> for forming the plurality of LEDs <NUM> is etched in operation S3110. Specifically, the growth substrate <NUM> for forming the plurality of LEDs <NUM> is etched to form a plurality of depressions and a plurality of protrusions corresponding to the plurality of depressions, on the growth substrate <NUM>. In other words, if the growth substrate <NUM> is provided, a growth substrate <NUM>' having a so-called patterned sapphire/ silicon substrate (PSS) structure is formed before the plurality of semiconductor layers are grown on the growth substrate <NUM> The growth substrate <NUM>' of the PSS structure may refer to forming a pattern of a predetermined shape on the surface of the growth substrate <NUM> for forming the LED device <NUM>. If a semiconductor layer is grown on the PSS structure growth substrate <NUM>', crystal defects and internal total reflection may be reduced as compared to a case of growing on a planar growth substrate. Accordingly, it is possible to increase light-emitting efficiency. Forming the PSS structure may be performed mainly using an etching technique such as dry plasma etching, but is not limited to a specific process technology. A specific form of the PSS structure is not limited to a particular type, either.

In the disclosure, the etching of the growth substrate <NUM> to form the plurality of LEDs <NUM> is characterized in that a plurality of partition walls <NUM> are formed based on the etching. As described below with reference to <FIG>, a plurality of partition walls <NUM> are formed based on the plurality of protrusions formed by etching, and a space between the plurality of partition walls <NUM> is formed based on the plurality of depressions formed by etching together with a plurality of protrusions.

Therefore, the etching of the growth substrate <NUM> according to an embodiment may be performed in consideration of the height and angle of the plurality of partition walls <NUM>. The etching of the growth substrate <NUM> may be performed such that each of the plurality of partition walls <NUM> have a predetermined height so that the wavelengths of light emitted by each of the plurality of LEDs <NUM> do not overlap with each other. Further, the etching of the growth substrate <NUM> may be performed such that the width of each of the plurality of barrier ribs <NUM> becomes narrower toward an upper portion.

If the growth substrate <NUM> is etched, as illustrated in <FIG>, the reflector layer <NUM> are formed on the surfaces of a plurality of protrusions and a plurality of depressions in operation S3120. The reflector layer <NUM> may be formed of at least one of aluminum (Al) and aluminum nitride (AlN), and may have a thickness of several nanometers or tens of nanometers. However, the material and thickness of the reflector layer <NUM> are not limited thereto.

Specifically, the process of forming the reflector layer <NUM> may be performed by coating an entire part of an aluminum layer on the surface of the plurality of protrusions and the plurality of depressions, and then performing C+ axis orientation control to form an aluminum nitride layer such that the polar surface of aluminum may be formed on the outermost surface of the growth crystal, that is, the top surface of the plurality of protrusions formed on the growth substrate <NUM>. Additionally forming an aluminum nitride layer on the top surface of the plurality of protrusions after the coating of the aluminum layer may be to adjust the polarity of the reflector layer <NUM> to facilitate horizontal growth of the n-type semiconductor layer <NUM> as described below. If the Al polarity is not actively controlled, the Al-polar and the N-polar are mixed to increase the threading dislocation density (TDD) and this may lead to degradation of the light-emitting efficiency.

However, the process of forming the reflector layer <NUM> according to the disclosure is not limited to the above-described process, and after the aluminum layer is entirely coated on the surface of the plurality of protrusions and the plurality of depressions, aluminum may be additionally formed on the upper surface of the plurality of protrusions formed on the growth substrate <NUM>.

When (or based on) the partition wall <NUM> is formed as described below, the reflector layer <NUM> is disposed on both sides of the plurality of partition walls <NUM> on the display module <NUM>, and reflects the light emitted from the LED device <NUM> so as not to be absorbed by the partition wall <NUM>, thereby increasing the light extraction efficiency (LEE) of the LED device <NUM>.

The reflector layer <NUM> may be formed of an aluminum layer that is formed during epi growth using in-situ process. In addition, the reflector layer may include a plurality of layers, and the outermost layer may be formed of aluminum. For example, the reflector layer <NUM> may be formed of a loop-layer structure multi-layer including a first reflector layer of aluminum, a second reflector layer formed on the first reflector layer and made of aluminum nitride, and a third reflector layer formed on the second reflector layer and made of aluminum.

As another example, the reflector layer <NUM> may include the first reflector layer made of aluminum, the second reflector layer formed on the first reflector layer and made of sequentially stacked aluminum nitride, AlxGa1-xN (general formula:<NUM>=x<<NUM>) and aluminum nitride, and a third reflector layer formed on the second reflector layer and made of aluminum.

When the reflector layer <NUM> is formed, as illustrated in <FIG>, the n-type semiconductor layer <NUM> is grown in the horizontal direction on the reflector layer <NUM> formed on the upper surface of the plurality of protrusions in operation S3130. The n-type semiconductor layer <NUM> may be an Al xGa yN (<NUM> ≥ x ≥ <NUM>, x+y=<NUM>) layer. When the n-type semiconductor layer <NUM> is grown in the horizontal direction on the reflector layer <NUM> formed on the upper surface of the plurality of protrusions, the upper portion of the plurality of depressions is closed by the grown n-type semiconductor layer <NUM>. Here, the shape formed by the closing of the depressions is not limited to the shape shown in <FIG> and <FIG>, or the like.

The horizontal growth process of the n-type semiconductor layer <NUM> may be performed by an epitaxial lateral overgrowth (ELO) technique. The horizontal epi growth technique is a technique for growing a semiconductor layer in a horizontal direction to reduce crystal defects such as a threading dislocation due to a lattice constant difference between the growth substrate <NUM> and the semiconductor layer.

As described above, when the aluminum nitride layer is additionally formed on the upper surface of the plurality of protrusions formed on the growth substrate <NUM> after coating the aluminum layer, the polarity of the reflector layer <NUM> is adjusted to facilitate horizontal growth of the n-type semiconductor layer <NUM>. However, it is understood that one or more other embodiments are not limited thereto. For example, according to another embodiment, it is also possible to grow the n-type semiconductor layer <NUM> in a horizontal direction after the aluminum layer is additionally formed on the upper surface of the plurality of protrusions formed on the growth substrate <NUM> after the aluminum layer is formed.

When the n-type semiconductor layer <NUM> is grown in the horizontal direction, the n-type semiconductor layer <NUM> is re-grown in operation S3140. When the n-type semiconductor layer is grown, as illustrated in <FIG>, the light-emitting layer <NUM> and the p-type semiconductor layer <NUM> are formed on the n-type semiconductor layer <NUM> in operation S3150. The process of forming the n-type semiconductor layer <NUM>, the p-type semiconductor layer <NUM>, and the light-emitting layer <NUM> may be performed by a technique such as metal organic chemical vapor deposition (MOCVD), metal organic chemical vapor phase epitaxy (MOVPE), molecular beam epitaxy (MBE), or the like.

When the light-emitting layer <NUM> and the p-type semiconductor layer <NUM> are formed, as shown in <FIG>, the n-type semiconductor layer <NUM>, the light-emitting layer <NUM>, and the p-type semiconductor layer <NUM> are etched to form a region <NUM> for separating each of the plurality of LEDs <NUM> and a region <NUM> for disposing the n-type electrode <NUM> in operation S3160. Specifically, the region to be etched may be patterned by a photoresist process prior to etching, and the etching may be performed using wet etching or dry etching techniques. For example, the etching may be performed using dry etching techniques such as reactive ion etching (RIE), electro-cyclotron resonance (ECR), inductively coupled plasma reactive ion etching (ICP)-RIE, chemically assisted ion-beam etching (CAIBE), or the like.

If a region for separating each of the plurality of LEDs <NUM> and a region for disposing the n-type electrode <NUM> are formed, the n-type electrode <NUM> electrically connected to the n-type semiconductor layer <NUM> is formed on the region <NUM> for disposing the n-type electrode <NUM>, and the p-type electrode <NUM> electrically connected to the p-type semiconductor layer <NUM> is formed on the p-type semiconductor layer <NUM>, as shown in <FIG> in operation S3170. The n-type electrode <NUM> and the p-type electrode <NUM> may be formed by a variety of processing techniques, such as sputtering, evaporation, and spin coating on electrode materials such as Al, Ti, Ni, Pd, Ag, Au, Au, and indium-tin-oxide (ITO) and ZnO.

As shown in <FIG>, when (or based on) the plurality of LEDs <NUM> are formed according to the plurality of steps S3110 to S3170 as described above, a portion of the growth substrate <NUM> is removed to form a plurality of partition walls <NUM> in operation S3210. Specifically, the formation process of the plurality of partition walls <NUM> may be performed by a process of removing a portion of the growth substrate <NUM> such that a plurality of partition walls <NUM> is formed based on the plurality of protrusions and a space between the plurality of partition walls <NUM> is formed based on the plurality of depressions. More specifically, the plurality of partition walls <NUM> may be formed by removing the growth substrate <NUM> from its bottom in the same state as <FIG> until a portion of the plurality of protrusions form the plurality of partition walls <NUM>, and the plurality of depressions may form part of the space between the plurality of partition walls <NUM>, as illustrated in <FIG>.

The process of removing the growth substrate <NUM> is performed while the reflector layer <NUM> is formed on the surface of the plurality of protrusions and the plurality of depressions formed on the growth substrate <NUM> and thus, the presence of the reflector layer <NUM> reduces the etching rate of the removal process of the growth substrate <NUM>. As a result, the plurality of partition walls <NUM> and the reflector layer <NUM> remain without a separate additional process, and the forming the partition wall <NUM> is facilitated. In addition, as the etching rate is reduced by the reflector layer <NUM>, damage to the LED device and the partition wall may be prevented in the process of removing the growth substrate <NUM>.

The removing process of the growth substrate <NUM> is not performed by only a specific method in all embodiments. By way of example, the removing of the growth substrate <NUM> made of a material safe against a chemical solution, such as silicon or sapphire, may be performed by wet etching.

When the plurality of LEDs <NUM> is formed according to the plurality of steps S3110 to S3170 as described above, a plurality of LEDs <NUM> may be formed on a relay substrate <NUM>, as shown in <FIG>, prior to finally forming the partition wall <NUM> by removing a portion of the growth substrate <NUM>. If a process of forming the plurality of partition walls <NUM> and combining process of the relay substrate <NUM> is performed, as shown in <FIG> or <FIG>, a color conversion layer may be formed in a space between the plurality of partition walls <NUM>. The color conversion layer may include a quantum dot (QD) or a phosphor.

As illustrated in <FIG>, when (or based on) the plurality of LEDs are blue LEDs <NUM> emitting blue light, the color conversion layer may include a color conversion layer <NUM> for converting blue light emitted from the plurality of LEDs <NUM> into red light, and a color conversion layer <NUM> for converting the emitted blue light into green light. In this case, a color conversion layer for converting a plurality of LEDs emitting blue light into blue light is not required, as the plurality of LEDs emitting blue light.

As illustrated in <FIG>, if the plurality of LEDs are LED devices <NUM> that emit ultraviolet rays, the color conversion layer may include a color conversion layer <NUM> for converting the ultraviolet light emitted from the plurality of LEDs <NUM> into red light, a color conversion layer <NUM> for converting the emitted ultraviolet light into green light, and a color conversion layer <NUM> for converting the emitted ultraviolet light into blue light.

If a color conversion layer is formed, a color filter (CF), a protection layer, or the like, are formed on the color conversion layer, encapsulation is performed, and a packaging process of a chip scale is completed.

In the case of forming a plurality of configurations that are mutually equal to each other such as forming the n-type electrode <NUM> and the p-type electrode <NUM> as described above, there is no time-series element between the two operations. In addition, the order of the manufacturing method as described above may vary within a scope for achieving the objectives of the disclosure.

According to various embodiments as described above, by forming a plurality of partition walls <NUM> based on the etching of the growth substrate <NUM> to form the LED device <NUM>, the process of forming the partition wall <NUM> is significantly simplified compared to the deposition using a related art photo-resin, and process costs may be reduced.

According to the related art, after forming the LED device <NUM>, the processes of performing photolithography, exposure, developing, or the like, and then the forming of a black matrix, or the like, are required. Meanwhile, according to one or more embodiments, a plurality of partition walls <NUM> may be formed by etching the growth substrate <NUM> for forming the LED device <NUM> and removing a portion of the growth substrate <NUM> performed after the LED device <NUM> is formed. The presence of the reflector layer <NUM> formed on the side surface of the partition wall <NUM> causes the etching rate of the removing process of the growth substrate <NUM> to be varied, and the partition wall <NUM> and the reflector layer <NUM> remain without a separate additional process. Therefore, the process of forming the partition wall <NUM> may be further facilitated.

According to an embodiment, spacing between the plurality of LEDs <NUM> on the display module <NUM> is not determined depending solely on the transfer process, but may also be determined through the process of performing the etching of the growth substrate <NUM> in consideration of the spacing between the plurality of LEDs <NUM>. Considering this point and the packaging process of the chip scale performed thereafter, minimization of the size of a device and improvement of the contrast ratio may be expected.

<FIG> is a diagram briefly illustrating a process for transferring an LED chip on a driving substrate according to an embodiment.

As described above, when the LED device <NUM> is manufactured and the chip scale packaging process including the LED device <NUM> is completed, a process of transferring the plurality of formed chips to the driving substrate is performed. The transfer process according to various embodiments may be performed through various methods such as, but not limited to, an electrostatic method, a stamp method, a printing method, a metal bonding method, or the like.

In the process of manufacturing the display module <NUM> including the LED device <NUM>, improving the accuracy and efficiency of the transfer process is beneficial because the transfer process and, specifically, a process of precisely transferring a large number of microchips to the drive substrate, is important to implement the micro LED display.

According to an embodiment, the spacing between the plurality of LEDs <NUM> is determined according to the spacing between the plurality of partition walls <NUM>, and the spacing between the plurality of partition walls <NUM> is determined in the process of forming a plurality of protrusions and a plurality of depressions by etching the growth substrate for the formation of the LEDs <NUM>. Therefore, according to an embodiment, after etching the growth substrate in consideration of the spacing between the plurality of LEDs <NUM>, if the process of forming the LED device <NUM> as described above and the packaging process of the chip scale are performed, the accuracy and efficiency of the transfer process performed thereafter may be significantly improved.

For example, according to an embodiment, a transfer process may be performed on a chip-by-chip basis including three LEDs <NUM> as shown in <FIG> or <FIG>. As illustrated in <FIG>, by transferring the chips including three LEDs corresponding to an R sub-pixel, a G sub-pixel, and a B sub-pixel to the driving substrate on a chip-by-chip basis, the transfer process in a pixel unit is possible. By way of another example, by performing the transfer process on a line-by-line basis, it is possible to transfer lines corresponding to each of the R sub-pixel, the G sub-pixel, and the B sub-pixel to the driving substrate adjacent to each other, and to configure one pixel with the neighboring R sub-pixel, the G sub-pixel, and the B sub-pixel.

Hereinafter, with reference to <FIG>, a process of forming the LED device <NUM>, a process of packaging of the chip scale, and a specific process of the display module <NUM> manufactured by performing the transfer process, or the like, is described.

<FIG> is a diagram illustrating a structure of the display module <NUM> according to an embodiment.

As illustrated in <FIG>, the display module <NUM> according to an embodiment includes the plurality of LEDs <NUM> and the driving substrate <NUM>. The driving substrate <NUM> may include a driving circuit. The driving circuit may be configured separately from the driving substrate <NUM>.

The driving circuit is a circuit for driving a plurality of LEDs <NUM>. Specifically, the plurality of LEDs <NUM> may be mounted on the driving substrate <NUM> including a driving circuit, and may be electrically connected to each of the driving circuits. Further, a driving circuit according to an embodiment is disposed on an upper portion of the driving substrate <NUM>. In other words, according to an embodiment, a driving circuit may be formed (or provided) on the driving substrate <NUM>, and a plurality of LEDs may be formed (or provided) on the driving circuit. The driving of the display module <NUM> according to an embodiment may be performed in the active matrix manner, and the driving substrate <NUM> and the driving circuit may be designed to be suitable to the driving method. Another embodiment may also be applied to a passive matrix method.

The driving circuit may include a plurality of switching devices together with a plurality of electrode pads, a plurality of circuit elements, or the like. The switching device is a semiconductor device configured to control the driving of the plurality of LEDs <NUM> included in the display module <NUM>, and serves as a kind of switch for individual pixels of the display device <NUM>. As shown in <FIG>, a thin film transistor (TFT) <NUM>-<NUM>, <NUM>-<NUM>, and <NUM>-<NUM> may be used as the switching device.

The n-type electrodes included in the plurality of LEDs <NUM> are connected to the electrode pads in the form of a common electrode, and the p-type electrodes may be individually connected to each of the pixel electrodes. Accordingly, the light emission of each of the plurality of LEDs <NUM> may be individually controlled.

<FIG> is a diagram illustrating a configuration of a display module <NUM> according to an embodiment.

As illustrated in <FIG>, the display module <NUM> according to an embodiment may include a plurality of pixels <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM> arranged in a matrix form, and the plurality of pixels <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM> may each include an R sub-pixel <NUM>, a G sub-pixel <NUM>, and a B sub-pixel <NUM>. Although <FIG> illustrates an example in which a plurality of sub-pixels are arranged in a form of <NUM> X <NUM> in one pixel, and a plurality of sub-pixels are arranged in a form of <NUM> X <NUM> in one pixel, it is understood that this is just an example and one or more other embodiments are not limited thereto.

The R sub-pixel <NUM>, the G sub-pixel <NUM>, and the B sub-pixel <NUM> may each correspond to the LED devices <NUM>. That each of the sub-pixels <NUM>, <NUM>, <NUM> corresponds to the LED device <NUM> may mean that each of the sub-pixels <NUM>, <NUM>, and <NUM> may be implemented by driving of the LED device <NUM>.

The configurations of the pixels and sub-pixels of the display module <NUM> described with reference to <FIG> are considered in performing packaging process and transfer process, or the like, of a chip scale, as described above.

<FIG> is a block diagram illustrating a simple configuration of a display device <NUM> according to an embodiment and <FIG> is a diagram illustrating a configuration of a display panel according to an embodiment.

The display device <NUM> according to an embodiment may be implemented by at least one of a television (TV), a monitor, a smartphone, a laptop computer, a desktop computer, a portable multimedia player, and a wearable device. Any type of device capable of displaying visual information through the display module <NUM> may be included in the display device <NUM> according to the disclosure.

Referring to <FIG>, the display device <NUM> according to an embodiment includes a display panel <NUM>, a panel driver <NUM>, and a timing controller <NUM>.

The display panel <NUM> displays an image under the control of the panel driver <NUM>. The display panel <NUM> includes a plurality of display modules <NUM> and a support plate <NUM>. The display module <NUM> has been described above with reference to <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, and <FIG>.

The support plate <NUM> supports the plurality of LED modules <NUM> so that the plurality of LED modules <NUM> connected to each other may form one display panel <NUM>. The structure of the plurality of LED modules <NUM> forming one display panel <NUM> through the support plate <NUM> is described below with reference to <FIG>.

The panel driver <NUM> includes a plurality of driver integrated circuits (ICs), and the display module <NUM> controls the driving of the display panel <NUM> or the display panel <NUM> through the plurality of driving ICs. Specifically, the plurality of driving ICs included in the panel driver <NUM> may control the light emission of the plurality of LEDs <NUM> connected to each of the driving circuits by driving the driving circuit included in the driving substrate <NUM>.

The timing controller <NUM> controls the panel driver <NUM>. Specifically, the timing controller <NUM> may adjust the image data signal to a signal required by the panel driver <NUM> and transmit the adjusted signal to the panel driver <NUM>. The timing controller <NUM> may be referred to in the art as a timing controller (T-CON), a data hub, a receiving card, a controller, or the like, but it should be understood that the timing controller <NUM> may be applied to the disclosure without limiting its name but based on a configuration that may control the panel driver <NUM> within a range that may accomplish the objectives of the disclosure.

As described above, the plurality of LEDs <NUM> are individually connected to the driving circuit, and light emission of each of the plurality of LEDs <NUM> may be individually controlled according to the control of the timing controller <NUM> and the panel driver <NUM>.

Further, the display device <NUM> according to an embodiment may also include a memory and at least one processor. The memory may store at least one command related to the control of the display device <NUM>, software related to the operation of the display device <NUM>, image data, or the like. The at least one processor may control the overall operation of the display device <NUM>.

Referring to <FIG>, a display panel <NUM> according to an embodiment may include a plurality of display modules <NUM>. Specifically, the plurality of display modules <NUM> may be connected in a matrix form to form one display panel <NUM>. That is, the display module <NUM> according to an embodiment may not only be implemented as an independent device, but may also be implemented as a unit for configuring the display panel <NUM>.

The support plate <NUM> supports the plurality of LED modules <NUM> so that the plurality of LED modules <NUM> connected to each other may form one display panel <NUM>. As illustrated in <FIG>, the plurality of display modules <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, and <NUM>-<NUM> may form one display panel <NUM> through the support plate <NUM>.

In <FIG>, it has been illustrated as an example that six display modules <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, and <NUM>-<NUM> are connected in a <NUM> x <NUM> format to form the display panel <NUM>. It is understood that the disclosure is not limited to the number and arrangement format of the display module <NUM>.

<FIG> is a diagram illustrating a computer-readable recording medium having instructions for performing each operation of a method for manufacturing the display module <NUM> stored therein, according to an embodiment; and <FIG> is a diagram illustrating a computer-readable recording medium having instructions for performing each operation of a method for controlling the display module <NUM> stored therein, according to an embodiment.

As described above, a method for controlling the display module <NUM> may be implemented as a program and provided to the display device <NUM>. The method for manufacturing the display module <NUM> as described above may be implemented as a program and provided to a device performing a manufacturing process of the display module <NUM> or a system including a plurality of devices.

A program including a method for controlling the display device <NUM> or a method for manufacturing the display module <NUM> may be stored and provided in a non-transitory computer readable medium. The non-transitory computer readable medium refers to a medium that stores data semi-permanently rather than storing data for a very short time, such as a register, a cache, a memory or etc., and is readable by an apparatus. In detail, the aforementioned various applications or programs may be stored in the non-transitory computer readable medium, for example, a compact disc (CD), a digital versatile disc (DVD), a hard disc, a Blu-ray disc, a universal serial bus (USB), a memory card, a read only memory (ROM), and the like, and may be provided.

As illustrated in <FIG>, the computer readable medium <NUM> may include at least one instruction <NUM> for controlling an operation of the display module <NUM>. As illustrated in <FIG>, the computer readable medium <NUM> may include at least one instruction <NUM> for controlling a system for performing a manufacturing process of the display module <NUM>.

The computer-readable recording medium <NUM> according to an embodiment may include instructions for controlling a system including a plurality of devices or devices for performing each step for forming a plurality of LEDs <NUM>. In addition, the computer-readable recording medium <NUM> may include instructions for controlling a manufacturing device or system for performing each of the steps involved in the manufacturing process of the display module <NUM>, including steps for forming a plurality of partition walls.

For example, the computer-readable recording medium <NUM> may include instructions for controlling an n-type semiconductor layer, a p-type semiconductor layer, and a metal organic chemical vapor deposition (MOCVD) device for growing the light-emitting layer included in the LED light-emitting device <NUM>. By way of another example, the computer-readable recording medium <NUM> may include instructions for controlling a device for etching a growth substrate or etching a plurality of semiconductor layers.

According to various embodiments of the disclosure as described above, since a plurality of partition walls are formed based on a growth substrate of an LED device such as silicon, the stiffness/strength of the partition wall is remarkably improved compared to a partition wall formed by a photo resin as in the related art. Accordingly, the stability of the weight load, the external pressure, etc., which may be generated in an overall manufacturing process of the display module <NUM>, may be expected. The display module <NUM> according to an embodiment includes a reflector layer formed on both sides of the partition wall and thus, the light emitting efficiency may be improved. When the angle of the plurality of partition walls according to the disclosure is adjusted to be less than <NUM> degrees, such as close to <NUM> degrees, the light emitting efficiency may be further improved.

According to the invention, by forming a plurality of partition walls based on etching of a substrate to form the LED device, a process of forming a partition wall is remarkably simplified as compared to stacking using a related art photo-resin and thus, a process cost may be saved.

According to the related art, there is a need of processes such as forming an LED device, performing photolithography, exposure, developing, or the like, and then forming a black matrix, or the like. Meanwhile, according to an embodiment, a plurality of partition walls may be formed by a process of etching a substrate for forming an LED device and removing a part of a substrate after the LED device is formed.

In particular, the presence of the reflector layer formed on the side of the partition wall causes the etching rate of the removal process of the substrate to be varied, thereby making the forming of the partition wall easier, as the plurality of partition walls and the reflector layers remain without a separate additional process.

According to an embodiment, the spacing between the plurality of LEDs on the display module <NUM> may not be determined entirely based on the transfer process, but may also be determined through the process of performing the etching of the substrate taking into account the spacing between the plurality of LED elements. Considering this point and the packaging process of the chip scale performed thereafter, it is also possible to minimize the size of the device and improve contrast ratio.

According to an embodiment, after performing etching of the substrate in consideration of the spacing between a plurality of LEDs and performing a process of forming the LED device and a process of packaging of a chip scale, precision and efficiency of the transfer process performed thereafter may be remarkably improved.

In conclusion, according to various embodiments, the display module <NUM> including a high-performance partition wall, the display device <NUM>, and an efficient method for manufacturing the display module <NUM> including a high-performance partition wall may be provided.

A display module according to the disclosure may be applied while being installed on a wearable device, a portable device, a handheld device, and various kinds of electronic products or electronic parts for which displays are needed as a single unit, or it may be applied to display devices such as a monitor for a personal computer (PC), a high resolution TV, signage, and an electronic display through a plurality of assembly arrangements as a matrix type.

Each of the components (for example, a module or a program) according to one or more embodiments may be composed of one or a plurality of objects, and some subcomponents of the subcomponents described above may be omitted, or other subcomponents may be further included in the embodiments. Alternatively or additionally, some components (e.g., modules or programs) may be integrated into one entity to perform the same or similar functions performed by each respective component prior to integration. Further, various features from various different embodiments may be combined.

Operations performed by a module, program, or other component, in accordance with embodiments, may be performed sequentially, in parallel, repetitive, or heuristic manner, or at least some operations may be performed in a different order, omitted, or other operations can be added.

Claim 1:
A display module (<NUM>) comprising:
a plurality of light-emitting diodes (<NUM>), LEDs;
a driving substrate (<NUM>);
a driving circuit on an upper portion of the driving substrate and configured to drive the plurality of LEDs;
a plurality of partition walls (<NUM>) configured to divide light-emitting regions by each of the plurality of LEDs;
reflective layers (<NUM>) formed on both sides of each of the plurality of partition walls,
each of the plurality of partition walls being a part of a plurality of protrusions formed by etching of a growth substrate (<NUM>) to form the plurality of LEDs; characterised by
the plurality of protrusions being formed before a plurality of semiconductor layers (<NUM>, <NUM>) included in the plurality of LEDs is formed on the growth substrate.