Patent Publication Number: US-2023142411-A1

Title: Deposition mask made of metal for oled pixel deposition and method for manufacturing deposition mask

Description:
TECHNICAL FIELD 
     An embodiment is for improving deposition performance in a deposition mask in which elliptical-shaped through-holes are disposed in a zigzag form. 
     BACKGROUND ART 
     A display device is used by being applied to various devices. For example, the display device is used by being applied to not only small devices such as smart phones and tablet PCs but also large devices such as TVs, monitors, and public displays (PDs). In particular, recently, the demand for ultra-high definition (UHD) of 500 pixels per inch (PPI) or more has increased, and high-resolution display devices have been applied to small devices and large devices. Accordingly, interest in technologies for realizing low power and high resolution is increasing. 
     Generally used display devices may be largely classified into a liquid crystal display (LCD), an organic light emitting diode (OLED), and the like according to a driving method. 
     The LCD is a display device driven by using a liquid crystal, and has a structure in which a light source including a cold cathode fluorescent lamp (CCFL), a light emitting diode (LED), or the like is disposed at lower portion of the liquid crystal. The LCD is a display device driven by controlling an amount of light emitted from the light source using the liquid crystal disposed on the light source. 
     In addition, the OLED is a display device that is driven by using an organic material, and does not require a separate light source, and the organic material itself may function as a light source and may be driven with low power consumption. In addition, OLED has attracted attention as a display device that may express an infinite contrast ratio, has a response speed of about 1000 times faster than the LCD, and may replace the LCD with an excellent viewing angle. 
     In particular, the organic material included in an emission layer of the OLED may be deposited on a substrate by a deposition mask called a fine metal mask (FMM), and the deposited organic material may be formed in a pattern corresponding to the pattern formed on the deposition mask to serve as a pixel. The deposition mask is generally manufactured by an invar alloy metal plate containing iron (Fe) and nickel (Ni). In this case, through-holes passing through the one surface and the other surface may be formed on one surface and the other surface of the metal plate, and the through-holes may be formed at positions corresponding to a pixel pattern. Accordingly, organic materials such as red, green, blue, and the like may be deposited on the substrate through the through-holes of the metal plate, and the pixel pattern may be formed on the substrate. 
     When the deposition mask has a circular through-hole, a uniform through-hole may be formed. Accordingly, a uniform deposition pattern may be formed. 
     Meanwhile, when elliptical-shaped through-holes are disposed in a zigzag form, there is a problem that a size of a deposition pattern differs according to a direction. 
     Therefore, there is a need for a deposition mask having a new structure in which the uniformity of the through-holes may be improved regardless of a direction while the elliptical-shaped through-holes are disposed in the zigzag form and a method of manufacturing the same. 
     DISCLOSURE 
     Technical Problem 
     An embodiment is directed to providing a deposition mask having a uniform pore diameter by controlling a size deviation of a large pore diameter and a size deviation of an island of the deposition mask. 
     Technical Solution 
     A deposition mask according to an embodiment includes a metal plate including a deposition region and a non-deposition region, wherein the deposition region includes a plurality of effective regions forming a deposition pattern and a separation region between a plurality of effective portions, the plurality of effective regions include a plurality of through-holes, and the plurality of through-holes include: a plurality of small surface holes formed on one surface; a plurality of large surface holes formed on the other surface opposite to the one surface; and a communication portion for communicating the small surface hole and the large surface hole, wherein the communication portion has an elliptical shape having a first diameter and a second diameter different from the first diameter, the through-hole includes a communication portion connected to a first large surface hole in which one surface of the metal plate in a transverse-axis direction and the first diameter are inclined at an acute angle and a communication portion connected to a second large surface hole in which one surface of the deposition mask in the transverse-axis direction and the first diameter are inclined at an obtuse angle, the first large surface hole and the second large surface hole are alternately disposed in a row in a longitudinal-axis direction of the metal plate, the first large surface hole and the second large surface hole are alternately disposed in a row in the transverse-axis direction of the metal plate, a first island portion is disposed between two adjacent first large surface holes in a first diagonal direction connecting the first diameter of the communication portion connected to the first large surface hole, a second island portion is disposed between two adjacent second large surface holes in a second diagonal direction connecting the first diameter of the communication portion connected to the second large surface hole, a rib is disposed between the first island portion and the second island portion, and a size deviation between the first island portion and the second island portion that are adjacent to each other is 30% or less. 
     Advantageous Effects 
     A deposition mask according to an embodiment can improve the uniformity of a pore diameter of the deposition mask. 
     In detail, in the deposition mask according to the embodiment, the uniformity of large surface holes and small surface holes of the through-holes can be improved regardless of a direction while through-holes including elliptical-shaped through-holes are disposed in a zigzag form. 
     That is, in the deposition mask according to the embodiment, the uniformity of a shape of the through-holes in a transverse-axis direction, a longitudinal-axis direction, and a diagonal direction can be improved. 
     Accordingly, the deposition mask according to the embodiment can improve the quality of a deposition pattern. 
    
    
     
       DESCRIPTION OF DRAWINGS 
         FIG.  1    is a perspective view illustrating an organic material deposition apparatus including a deposition mask according to an embodiment. 
         FIG.  2    is a cross-sectional view illustrating the organic material deposition apparatus including the deposition mask according to the embodiment. 
         FIG.  3    is a view illustrating that the deposition mask according to the embodiment is stretched to be mounted on a mask frame. 
         FIG.  4    is a view illustrating that a plurality of deposition patterns are formed on a substrate  300  through a plurality of through-holes of the deposition mask. 
         FIG.  5    is a view illustrating a plan view of the deposition mask according to the embodiment. 
         FIG.  6    is a view illustrating a plan view of an effective portion of a deposition mask according to Comparative Example. 
         FIG.  7    is a photograph of the effective portion of the deposition mask according to Comparative Example. 
         FIG.  8    is a view illustrating a plan view of an effective portion of a deposition mask according to an embodiment. 
         FIG.  9    is a photograph of the effective portion of the deposition mask according to the embodiment. 
         FIG.  10    is a view illustrating each cross section in an overlapping manner in order to describe a step and a size in height between a cross section in a A-A′ direction and a cross section in a B-B′ direction of  FIG.  8   . 
         FIG.  11    is a view illustrating a process of forming a large surface hole of the deposition mask according to Comparative Example. 
         FIG.  12    is a view illustrating a process of forming a large surface hole of the deposition mask according to the embodiment. 
         FIG.  13    is a view illustrating a size of a deposition pattern in a diagonal direction of Comparative Example. 
         FIG.  14    is a view illustrating a size of a deposition pattern in a diagonal direction according to the embodiment. 
         FIGS.  15  and  16    are views illustrating a deposition pattern formed through a deposition mask according to an embodiment. 
     
    
    
     MODES OF THE INVENTION 
     Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the spirit and scope of the present invention is not limited to a part of the embodiments described, and may be implemented in various other forms, and within the spirit and scope of the present invention, one or more of the elements of the embodiments may be selectively combined and replaced. In addition, unless expressly otherwise defined and described, the terms used in the embodiments of the present invention (including technical and scientific terms may be construed the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the terms such as those defined in commonly used dictionaries may be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art. 
     In addition, the terms used in the embodiments of the present invention are for describing the embodiments and are not intended to limit the present invention. In this specification, the singular forms may also include the plural forms unless specifically stated in the phrase, and may include at least one of all combinations that may be combined in A, B, and C when described in “at least one (or more) of A (and), B, and C”. 
     Further, in describing the elements of the embodiments of the present invention, the terms such as first, second, A, B, (A, and (b) may be used. These terms are only used to distinguish the elements from other elements, and the terms are not limited to the essence, order, or order of the elements. 
     In addition, when an element is described as being “connected” or “coupled” to another element, it may include not only when the element is directly “connected” or “coupled” to other elements, but also when the element is “connected” or “coupled” by another element between the element and other elements. 
     Further, when described as being formed or disposed “on (over)” or “under (below)” of each element, the “on (over)” or “under (below)” may include not only when two elements are directly connected to each other, but also when one or more other elements are formed or disposed between two elements. 
     Furthermore, when expressed as “on (over)” or “under (below)”, it may include not only the upper direction but also the lower direction based on one element. 
     Hereinafter, a deposition mask according to an embodiment will be described with reference to drawings. 
       FIGS.  1  to  4    are conceptual views for describing a process of depositing an organic material on a substrate  300  using a deposition mask  100  according to an embodiment. 
       FIG.  1    is a perspective view illustrating an organic material deposition apparatus including a deposition mask according to an embodiment,  FIG.  2    is a cross-sectional view illustrating the organic material deposition apparatus including the deposition mask  100  according to the embodiment, and  FIG.  3    is a view illustrating that the deposition mask  100  according to the embodiment is stretched to be mounted on a mask frame  200 . In addition,  FIG.  4    is a view illustrating that a plurality of deposition patterns are formed on the substrate  300  through a plurality of through-holes of the deposition mask  100 . 
     Referring to  FIGS.  1  to  4   , the organic material deposition apparatus may include the deposition mask  100 , the mask frame  200 , the substrate  300 , an organic material deposition container  400 , and a vacuum chamber  500 . 
     The deposition mask  100  may include a metal. For example, the deposition mask may include iron (Fe) and nickel (Ni). 
     The deposition mask  100  may include a plurality of through-holes TH in an effective portion for deposition. The deposition mask  100  may be a substrate for the deposition mask including the plurality of through-holes TH. In this case, the through-hole may be formed to correspond to a pattern to be formed on the substrate. The deposition mask  100  may include an ineffective portion other than the effective portion including a deposition region. 
     The mask frame  200  may include an opening  205 . The plurality of through-holes of the deposition mask  100  may be disposed on a region corresponding to the opening  205  of the mask frame  200 . Accordingly, the organic material supplied to the organic material deposition container  400  may be deposited on the substrate  300 . The deposition mask  100  may be disposed and fixed on the mask frame  200 . For example, the deposition mask  100  may be stretched with a constant tensile force and fixed on the mask frame  200  by welding. 
     That is, the mask frame  200  includes a plurality of frames  201 ,  202 ,  203 , and  204  surrounding the opening  205 . 
     The deposition mask  100  may be stretched in opposite directions at the outermost portion of the deposition mask  100 . In the deposition mask  100 , one end of the deposition mask  100  and the other end opposite to the one end may be stretched in opposite directions in a longitudinal direction (transverse-axis direction) of the deposition mask  100 . 
     The substrate  300  may be a substrate used for manufacturing a display device. For example, the substrate  300  may be a substrate  300  for depositing an organic material for an OLED pixel pattern. Patterns of red (R), green (G), and blue (B) may be formed on the substrate  300  to form a pixel having three primary colors of light. That is, an RGB pattern may be formed on the substrate  300 . 
     The organic material deposition container  400  may be a crucible. An organic material may be disposed inside the crucible. The organic material deposition container  400  may move in the vacuum chamber  500 . 
     As a heat source and/or current are supplied to the crucible that is the organic material deposition container  400  in the vacuum chamber  500 , the organic material may be deposited on the substrate  100 . 
     Referring to  FIG.  4   , the deposition mask  100  may include one surface  101  and the other surface  102  opposite to the one surface. 
     The one surface  101  of the deposition mask  100  may include a small surface hole V 1 , and the other surface  102  may include a large surface hole V 2 . For example, each of the one surface  101  and the other surface  102  of the deposition mask  100  may include a plurality of small surface holes V 1  and a plurality of large surface holes V 2 . 
     In addition, the deposition mask  100  may include a through-hole TH. The through-hole TH may be communicated by a communication portion CA to which a boundary between the small surface hole V 1  and the large surface hole V 2  is connected. 
     In addition, the deposition mask  100  may include a first inner surface ES 1  in the small surface hole V 1 . The deposition mask  100  may include a second inner surface ES 2  in the large surface hole V 2 . The through-hole TH may be formed by communicating the first inner surface ES 1  in the small surface hole V 1  and the second inner surface ES 2  in the large surface hole V 2  with each other. For example, the first inner surface ES 1  in one small surface hole V 1  may communicate with the second inner surface ES 2  in one large surface hole V 2  to form one through-hole. Accordingly, the number of the through-holes TH may correspond to the number of the small surface holes V 1  and the large surface holes V 2 . 
     A width of the large surface hole V 2  may be greater than a width of the small surface hole V 1 . In this case, the width of the small surface hole V 1  may be measured on the one surface  101  of the deposition mask  100 , and the width of the large surface hole V 2  may be measured on the other surface  102  of the deposition mask  100 . 
     The small surface hole V 1  may be disposed toward the substrate  300 . The small surface hole V 1  may be disposed close to the substrate  300 . Accordingly, the small surface hole V 1  may have a shape corresponding to the deposition material, that is, a deposition pattern DP. 
     The large surface hole V 2  may be disposed toward the organic material deposition container  400 . Accordingly, the large surface hole V 2  may accommodate the organic material supplied from the organic material deposition container  400  in a wide width, and a fine pattern may be quickly formed on the substrate  300  through the small surface hole V 1  having a width smaller than the large surface hole V 2 . 
       FIG.  5    is a view illustrating a plan view of the deposition mask  100  according to the embodiment. The deposition mask  100  will be described in more detail with reference to  FIG.  5   . 
     Referring to  FIG.  5   , the deposition mask  100  according to the embodiment may include a deposition region DA and a non-deposition region NDA. 
     The deposition region DA may be a region for forming a deposition pattern. The deposition region DA may include a pattern region and a non-pattern region. The pattern region may be a region including the small surface hole V 1 , the large surface hole V 2 , the through-hole TH, and an island portion IS, and the non-pattern region may be a region not including the small surface hole V 1 , the large surface hole V 2 , the through-hole TH, and the island portion IS. 
     In addition, one deposition mask  100  may include a plurality of deposition regions DA. For example, the deposition region DA of the embodiment may include a plurality of effective portions AA 1 , AA 2 , and AA 3  capable of forming a plurality of deposition patterns. 
     The deposition region DA may include a plurality of isolation regions IA 1  and IA 2  included in one deposition mask  100 . Isolation regions IA 1  and IA 2  may be disposed between adjacent effective portions. That is, adjacent effective regions may be distinguished from each other by the isolation regions IA 1  and IA 2 , and one deposition mask  100  may support a plurality of effective regions. 
     The deposition mask  100  may include the non-deposition region NDA in both sides in a longitudinal direction of the deposition region DA. The deposition mask  100  according to the embodiment may include the non-deposition region NDA on both sides in a horizontal direction of the deposition region DA. 
     The non-deposition region NDA may include frame fixing regions FA 1  and FA 2  for fixing the deposition mask  100  to the mask frame  200 , half-etched portions HF 1  and HF 2 , and an open portion. 
     The non-deposition region NDA may include the half-etched portions HF 1  and HF 2 . For example, the non-deposition region NDA of the deposition mask  100  may include a first half-etched portion HF 1  on one side of the deposition region DA and may include a second half-etched portion HF 2  on the other side opposite to the one side of the deposition region DA. The first half-etched portion HF 1  and the second half-etched portion HF 2  may be regions in which grooves are formed in a depth direction of the deposition mask  100 . The first half-etched portion HF 1  and the second half-etched portion HF 2  may have a groove having a depth of about ½ of a thickness of the deposition mask, so that stress may be dispersed during stretching the deposition mask  100 . 
     The deposition mask  100  according to the embodiment may include a plurality of half-etched portions. In detail, the deposition mask  100  according to the embodiment is illustrated as including the half-etched portions HF 1  and HF 2  only in the non-deposition region NDA, but the embodiment is not limited thereto, and at least one of the deposition region DA and the non-deposition region NDA may further include a plurality of half-etched portions. Accordingly, the stress of the deposition mask  100  may be uniformly dispersed. 
     The non-deposition region NDA may include the frame fixing regions FA 1  and FA 2  for fixing the deposition mask  100  to the mask frame  200 . 
     The frame fixing regions FA 1  and FA 2  may be disposed between the half-etched portions HF 1  and HF 2  of the non-deposition region NDA and the effective portion of the deposition region DA adjacent to the half-etched portions HF 1  and HF 2 . For example, the first frame fixing region FA 1  may be disposed between the first half-etched portion HF 1  of the non-deposition region NDA and a first effective portion AA 1  of the deposition region DA adjacent to the first half-etched portion HF 1 . For example, the second frame fixing region FA 2  may be disposed between the second half-etched portion HF 2  of the non-deposition region NDA and a third effective portions AA 3  of the deposition region DA adjacent to the second half-etched portion HF 2 . Accordingly, it is possible to simultaneously fix a plurality of deposition pattern portions. 
     In addition, the deposition mask  100  may include semicircular openings at both ends in a horizontal direction X. For example, the non-deposition region NDA may include the open portion. 
     In addition, although not shown in the drawings, the half-etched portion may be further formed in an ineffective portion UA of the deposition region DA. A plurality of the half-etched portions may be dispersed in all or part of the ineffective portion UA to disperse stress during stretching the deposition mask  100 . 
     In addition, the half-etched portions HF 1  and HF 2  may be formed in the frame fixing regions FA 1  and FA 2  and/or in the peripheral regions of the frame fixing regions FA 1  and FA 2 . Accordingly, stress of the deposition mask  100  generated when the deposition mask  100  is fixed to the mask frame  200  and/or when the deposition material is deposited after fixing the deposition mask  100  to the frame may be uniformly dispersed. Accordingly, the deposition mask  100  may be maintained to have uniform through-holes. 
     The deposition mask  100  may include the plurality of effective portions AA 1 , AA 2 , and AA 3  spaced apart in the longitudinal direction and the ineffective portions UA other than the effective portions. In detail, the deposition region DA may include a plurality of effective portions AA 1 , AA 2 , and AA 3  and the ineffective portions UA other than the effective portions AA. 
     The effective portions AA 1 , AA 2 , AA 3  may include the plurality of small surface holes V 1  formed on one surface of the deposition mask  100 , the plurality of large surface holes V 2  formed on the other surface opposite to the one surface, and the through-hole TH formed by the communication portion CA to which the boundary between the small surface hole V 1  and the large surface hole V 2  is connected. 
     In addition, the effective portions AA 1 , AA 2 , and AA 3  may include the island portion IS for supporting between the plurality of through-holes TH. 
     The island portion IS may be positioned between adjacent through-holes TH among the plurality of through-holes TH. That is, in the effective portions AA 1 , AA 2 , and AA 3  of the deposition mask  100 , a region other than the through-hole TH may be the island portion IS. 
     The island portion IS may refer to a portion that is not etched on one surface  101  or the other surface  102  of the effective portion of the deposition mask. In detail, the island portion IS may be an unetched region between the through-hole TH and the through-hole TH on the other surface  102  on which the large surface hole V 2  of the effective portion of the deposition mask  100  is formed. Therefore, the island portion IS may be disposed parallel to the other surface  102  of the deposition mask  100 . In detail, an upper surface of the island portion IS may be disposed parallel to the other surface  102 . 
     The island portion IS may be disposed on the same plane as the other surface  102  of the deposition mask  100 . Accordingly, the island portion IS may have the same thickness as at least a portion of the ineffective portion on the other surface  102  of the deposition mask  100 . In detail, the island portion IS may have the same thickness as an unetched portion of the ineffective portion on the other surface  102  of the deposition mask  100 . Accordingly, the deposition uniformity of sub-pixels may be improved through the deposition mask  100 . 
     Alternatively, the island portion IS may be disposed on a plane parallel to the other surface  102  of the deposition mask  100 . Here, the parallel plane may include that a height difference between the other surface of the deposition mask  100  on which the island portion IS is disposed by the etching process around the island portion IS and the other surface of the non-etched deposition mask  100  among the ineffective portions is ±1 μm or less. 
     The island portion IS may have a width W 1  in the longitudinal direction and a width in the horizontal direction different from each other. That is, the island portion IS may have the width in the longitudinal direction greater than the width in the horizontal direction. In more detail, the island portion IS may have a width parallel to the longitudinal direction of the deposition mask greater than a width parallel to a width direction of the deposition mask. 
     The deposition mask  100  may include the ineffective portion UA disposed at an outer portion of the effective portions AA 1 , AA 2 , and AA 3 . The effective portion AA may be an inner region when the outer portions of the through-holes positioned at the outermost portion for depositing the organic material among the plurality of through-holes are connected. The ineffective portion UA may be an outer region when the outer portions of the through-holes positioned at the outermost portion for depositing the organic material among the plurality of through-holes are connected. 
     The ineffective portion UA is a region excluding the effective portions AA 1 , AA 2 , and AA 3  in the deposition region DA and the non-deposition region NDA. The ineffective portion UA may include outer regions OA 1 , OA 2 , and OA 3  surrounding the outer portion of the effective portions AA 1 , AA 2 , and AA 3 . 
     The number of the outer regions OA 1 , OA 2 , and OA 3  may correspond to the number of the effective portions AA 1 , AA 2 , and AA 3 . That is, one effective portion may include one outer region respectively separated by a predetermined distance in horizontal and vertical directions from an end of the effective portion. 
     The first effective portion AA 1  may be included in a first outer region OA 1 . The first effective portion AA 1  may include a plurality of through-holes TH for forming a deposition material. The first outer region OA 1  surrounding an outer portion of the first effective portion AA 1  may include a plurality of through-holes. 
     For example, the plurality of through-holes included in the first outer region OA 1  is to reduce etching defects of through-holes TH positioned at the outermost portion of the first effective portion AA 1 . Accordingly, the deposition mask  100  according to the embodiment may improve the uniformity of the plurality of through-holes positioned in the effective portions AA 1 , AA 2 , and AA 3 , thereby improving the quality of the deposition pattern manufactured. 
     In addition, a shape of the through-hole TH of the first effective portion AA 1  may correspond to a shape of the through-hole TH of the first outer region OA 1 . Accordingly, the uniformity of the through-hole TH included in the first effective portion AA 1  may be improved. As an example, the shape of the through-hole TH of the first effective portion AA 1  and the shape of the through-hole of the first outer region OA 1  may be circular. However, the embodiment is not limited thereto, and the through-hole TH may have various shapes such as a diamond pattern, an elliptical pattern, and the like. 
     The second effective portion AA 2  may be included in a second outer region OA 2 . The second effective portion AA 2  may have a shape corresponding to that of the first effective portion AA 1 . The second outer region OA 2  may have a shape corresponding to that of the first outer region OA 1 . 
     The second outer region OA 2  may further include two through-holes in each of the horizontal direction and the vertical direction from a through-hole positioned at the outermost portion of the second effective portion AA 2 . For example, in the second outer region OA 2 , two through-holes may be disposed in a row in the horizontal direction at each of positions of upper and lower portions of the through-hole positioned at the outermost portion of the second effective portion AA 2 . For example, in the second outer region OA 2 , two through-holes may be disposed in a row in the vertical direction at each of left and right sides of the through-hole positioned at the outermost portion of the second effective portion AA 2 . The plurality of through-holes included in the second outer region OA 2  are to reduce etching defects of the through-holes positioned at the outermost portion of the effective portion. Accordingly, the deposition mask according to the embodiment may improve the uniformity of the plurality of through-holes positioned in the effective portion, thereby improving the quality of the deposition pattern manufactured. 
     The third effective portion AA 3  may be included in a third outer region OA 3 . The third effective portion AA 3  may include a plurality of through-holes for forming a deposition material. The third outer region OA 3  surrounding an outer portion of the third effective portion AA 3  may include a plurality of through-holes. 
     The third effective portion AA 3  may have a shape corresponding to that of the first effective portion AA 1 . The third outer region OA 3  may have a shape corresponding to that of the first outer region OA 1 . 
     In addition, through-holes TH included in the effective portions AA 1 , AA 2  and AA 3  may have a shape partially corresponding to through-holes included in the ineffective portion UA. As an example, the through-holes included in the effective portions AA 1 , AA 2  and AA 3  may have different shapes from through-holes positioned at an edge portion of the ineffective portion UA. Accordingly, the difference in stress according to a position of the deposition mask  100  may be adjusted. 
     Structural characteristics of a deposition mask according to an embodiment will be described by comparing  FIGS.  6  to  9   . 
       FIGS.  6  and  7    are views illustrating a plan view of an effective portion of a deposition mask  100  according to Comparative Example. 
     When the through-hole of the deposition mask has a symmetrical shape, the uniformity of the island portion may be high. For example, a deposition mask having a circular through-hole may have a high uniformity of the through-hole regardless of a direction, and a size of the island portion may be uniform. Accordingly, the uniformity of the deposition pattern manufactured through the deposition mask may be high, and the quality of the deposition pattern may be high. 
     Meanwhile, as in Comparative Examples of  FIGS.  6  and  7   , when the through-hole of the deposition mask has an asymmetric shape, there is a problem that the uniformity of the size of the island portion is deteriorated. Here, the asymmetric shape may refer that the elliptical-shaped through-holes are disposed in a first diagonal direction different from the transverse-axis direction and the longitudinal-axis direction of the deposition mask and a second diagonal direction different from the first diagonal direction. That is, in the deposition mask of the Comparative Example, a direction transverse to a maximum diameter of a plurality of elliptical-shaped through-holes may be the first diagonal direction different from the transverse-axis direction and the longitudinal-axis direction of the deposition mask. In addition, the direction transverse to the maximum diameter of the plurality of elliptical-shaped through-holes may be the second diagonal direction different from the transverse-axis direction, the longitudinal-axis direction, and the first diagonal direction of the deposition mask. Accordingly, a size deviation may occur in the island portion positioned on a line extending a center in a direction of the maximum or minimum diameter of adjacent elliptical-shaped through-holes according to a cross-sectional direction. That is, in the deposition mask according to Comparative Example, the uniformity of the shape of the through-hole may be deteriorated according to a cross-sectional direction of a diagonal line. In addition, in the deposition mask according to Comparative Example, the size deviation of the island portion may be large according to the cross-sectional direction of the diagonal line. Accordingly, in the deposition mask according to the Comparative Example, there is a problem that the quality of the deposition pattern is low. 
     An object of the embodiment is to reduce the size deviation of the through-hole and the size deviation of the island portion in the deposition mask having the asymmetrical-shaped through-hole. Accordingly, the embodiment may improve the uniformity of the through-holes in different diagonal directions in the deposition mask having the asymmetrical-shaped through-holes. The through-holes of the deposition mask according to the embodiment may have the elliptical shape disposed in a zigzag form and have a uniform size in the transverse-axis direction, the longitudinal-axis direction, the first diagonal direction, and the second diagonal direction. In addition, the island portion positioned between the through-holes of the deposition mask according to the embodiment may have a uniform size in the transverse-axis direction, the longitudinal-axis direction, the first diagonal direction, and the second diagonal direction. Accordingly, the deposition mask according to the embodiment may have uniform through-holes, and thus the quality of the deposition pattern manufactured may be excellent. 
     Hereinafter, effects of the present invention will be described in detail with reference to  FIGS.  6  to  9   . 
     Referring to  FIGS.  6  and  7   , in the deposition mask according to Comparative Example, as a pattern of the large surface holes has an elliptical shape inclined at different angles, there is a problem that the island portion is not uniform. 
     For example, a size of a first island portion IS 1  positioned in a first diagonal direction I 1  may be greater than a size of a second island portion IS 2  positioned in a second diagonal direction I 2 . 
     Accordingly, a size deviation between adjacent first island portions IS 1  and second island portions IS 2  may exceed 30%. For example, a size deviation of the first island portion and the second island portion disposed in a row in the longitudinal-axis direction may exceed 20%. A size deviation of the first island portion and the second island portion disposed in a row in the transverse-axis direction may exceed 10%. Accordingly, in the deposition mask of the Comparative Example, there is a problem that the uniformity of the deposition pattern is deteriorated according to a deposition direction. 
       FIGS.  8  and  9    are views illustrating a plan view of an effective portion of a deposition mask  100  according to an embodiment. 
       FIGS.  6  to  9    may be plan views of any one of the first effective portion AA 1 , the second effective portion AA 2 , and the third effective portion AA 3  of the deposition mask  100 . In addition,  FIGS.  8  and  9    are views for describing a shape of a through-hole TH and the arrangement between the through-holes TH according to the embodiment, and the deposition mask  100  according to the embodiment is not limited to the number of through holes TH shown in the drawings. 
     Referring to  FIGS.  8  and  9   , the deposition mask  100  may include a plurality of through-holes TH including communication portions CA. In this case, the communication portions CA of the plurality of through-holes may have an elliptical shape. A diameter in one direction and a diameter in the other direction of the communication portion CA may be different from each other. 
     The communication portion CA of the through-hole TH may have an elliptical shape having a first diameter D 1  and a second diameter D 2  different from the first diameter. Here, the first diameter D 1  may refer to a maximum diameter of the elliptical shape, and the second diameter D 2  may refer to a minimum diameter of the elliptical shape. In this case, a direction of the first diameter D 1  and a direction of the second diameter D 2  may have an angle of 90 degrees or an angle similar angle thereto. Here, the similar angle may refer to a difference of less than 2 degrees before and after 90 degrees. Alternatively, the similar angle herein may refer to a difference of less than 1 degree before and after 90 degrees. Alternatively, the similar angle herein may refer to a difference of less than 0.5 degrees before and after 90 degrees. 
     The large surface hole and the communication portion may have different shapes. For example, the communication portion may be formed in the elliptical shape as described above. In addition, the large surface hole may be formed in a circular shape. That is, in the communication portion, a diameter in one direction and a diameter in the other direction may be different from each other, and in the large surface hole, a diameter in one direction and a diameter in the other direction may be the same or similar to each other. 
     A size deviation between the first large surface hole and the second large surface hole may be 10% or less. The size deviation between the first large surface hole and the second large surface hole may be 5% or less. The size deviation between the first large surface hole and the second large surface hole may be 3% or less. When the size deviation of the first large surface hole and the second large surface hole exceeds 10%, deposition efficiency may be deteriorated, and the quality of a deposition pattern manufactured through a deposition mask may be deteriorated. 
     The first diameter may be 50 μm or less. For example, the first diameter may be 40 μm or less. For example, the first diameter may be 30 μm or less. 
     A difference between the first diameter D 1  and the second diameter D 2  may be 10 μm or less. The difference between the first diameter D 1  and the second diameter D 2  may be 7 μm or less. The difference between the first diameter D 1  and the second diameter D 2  may be 5 μm or less. When the difference between the first diameter D 1  and the second diameter D 2  exceeds 10 μm, the size deviation of the island portions positioned in different diagonal directions increases, and thus the deposition quality may be deteriorated. 
     A ratio of the second diameter D 2  to the first diameter D 1  (second diameter/first diameter) may be between 0.7 and 0.93. As an example, the first diameter D 1  may be 40 μm, the second diameter D 2  may be 30 μm, and the ratio of the second diameter D 2  to the first diameter D 1  may be 0.75 ( 30/40). 
     A ratio of the first island portion IS 1  to the second island portion IS 2  (size of the first island portion/size of the second island portion) may be 0.6 to 0.9. As an example, a size of the first island portion IS 1  may be 34.0 μm, a size of the second island portion IS 2  may be 22 μm, and the ratio of the first island portion IS 1  to the second island portion IS 2  may be about 0.65. 
     The communication portion of the through-hole TH may have an elliptical shape that is disposed to be inclined at a predetermined angle. The communication portions of the plurality of through-holes may be respectively disposed in the elliptical shape. In the communication portions of the plurality of through-holes, an elliptical shape inclined in a first diagonal direction OL 1  and an elliptical shape inclined in a second diagonal direction OL 2  may be alternately disposed. 
     For example, the communication portions of the plurality of through-holes may be disposed to be spaced apart in a zigzag form in the longitudinal direction (transverse-axis direction). In detail, in the communication portions of the plurality of through-holes, the elliptical shape inclined in the first diagonal direction OL 1  and the elliptical shape inclined in the second diagonal direction OL 2  may be alternately disposed in the longitudinal direction, and an imaginary extension line connecting the maximum diameter direction of the elliptical shape inclined in the first diagonal direction OL 1  and the elliptical shape inclined in the second diagonal direction OL 2  may have a zigzag shape Z 1 . 
     For example, the communication portions of the plurality of through-holes may be disposed to be spaced apart in a zigzag form in a direction (longitudinal-axis direction) perpendicular to the longitudinal direction of the metal plate. In detail, in the communication portions of the plurality of through-holes, the elliptical shape inclined in the first diagonal direction OL 1  and the elliptical shape inclined in the second diagonal direction OL 2  may be alternately disposed in the longitudinal direction, and an imaginary extension line connecting the maximum diameter direction of the elliptical shape inclined in the first diagonal direction OL 1  and the elliptical shape inclined in the second diagonal direction OL 2  may have a zigzag shape Z 2 . 
     For example, the communication portion of the through-hole may be disposed while having an inclination at a predetermined angle. In detail, a vertical direction of the communication portion of the through-hole may be disposed to be inclined at a predetermined angle with respect to a width direction of the metal plate. 
     Here, the first diagonal direction OL 1  may be a direction of an imaginary line connecting the maximum diameter of an elliptical shape inclined in a first direction. The second diagonal direction OL 2  may be a direction of an imaginary line connecting the maximum diameter of an elliptical shape inclined in a second direction. The first diagonal direction OL 1  and the second diagonal direction OL 2  may cross each other. 
     For example, when an angle between the first diagonal direction OL 1  and one end of the deposition mask in the transverse-axis direction is an acute angle, an angle between the second diagonal direction OL 2  and one end of the deposition mask in the transverse-axis direction may be an obtuse angle. For example, when the angle between the first diagonal direction OL 1  and one end of the deposition mask in the transverse-axis direction is an obtuse angle, the angle between the second diagonal direction OL 2  and one end of the deposition mask in the transverse-axis direction may be an acute angle. 
     For example, in the communication portion of the through-hole, a vertical direction of the through-hole may be disposed to be inclined at an angle of 1° to 60° or −1° to −60° with respect to the width direction of the metal plate. For example, in the communication portion of the through-hole, the vertical direction of the communication portion may be disposed to be inclined at an angle of 1° to 45° or −1° to −45° with respect to the width direction of the metal plate. For example, in the communication portion of the through-hole, the vertical direction of the communication portion may be disposed to be inclined at an angle of 1° to 10° or −1° to −10° with respect to the width direction of the metal plate. 
     An imaginary line connecting a first diameter D 1  of the communication portion connected to a first large surface hole V 2 - 1  disposed in a row in the longitudinal-axis direction and a first diameter D 1  of the communication portion connected to a second large surface hole V 2 - 2  may have a zigzag shape. 
     An imaginary line connecting the first diameter D 1  of the communication portion connected to the first large surface hole V 2 - 1  disposed in a row in the transverse-axis direction and the first diameter D 1  of the communication portion connected to the second large surface hole V 2 - 2  may have a zigzag shape. 
     The large surface hole may include the first large surface hole V 2 - 1  connected to the communication portion in which one surface of the deposition mask in the transverse-axis direction and the first diameter D 1  is inclined at an acute angle and the second large surface hole V 2 - 2  connected to the communication portion in which one surface of the deposition mask in the longitudinal direction and the first diameter D 1  is inclined at an obtuse angle. 
     The first large surface hole V 2 - 1  and the second large surface hole V 2 - 2  may be alternately disposed in a row in the longitudinal-axis direction. 
     The first large surface holes V 2 - 1  and the second large surface holes V 2 - 2  may be alternately disposed in a row in the transverse-axis direction. 
     A communication portion of two adjacent through-holes in the transverse-axis direction and a communication portion of two through-holes positioned in the longitudinal-axis direction of each of the two through-holes may form a pinwheel-shaped through-hole set SET. For example, a communication portion set of four through-holes constituted of a communication portion connected to two adjacent first large surface holes V 2 - 1  in the longitudinal-axis and transverse-axis directions and a communication portion connected to the two second large surface holes V 2 - 2  may have a pinwheel shape. 
     The communication portion of the first through-hole and the communication portion of the second through-hole that are adjacent in the transverse-axis direction in one set of through-holes may have a shape facing each other with a mirror interposed therebetween. The communication portion of the third through-hole and the communication portion of the fourth through-hole that are adjacent in the transverse-axis direction in one set of through-holes may have a shape facing each other with a mirror interposed therebetween. In addition, the communication portion of the first through-hole and the communication portion of the third through-hole that are adjacent in the longitudinal-axis direction in one set of through-holes may have a shape facing each other with a mirror interposed therebetween. The communication portion of the second through-hole and the communication portion of the fourth through-hole that are adjacent in the longitudinal-axis direction in one set of through-holes may have a shape facing each other with a mirror interposed therebetween. 
     The four through-hole sets SET in which the communication portion has a pinwheel shape may be disposed in a row in the transverse-axis direction and the longitudinal-axis direction of the deposition mask. For example, the four through-hole sets SET having the pinwheel shape may include a first through-hole set SET 1  and a second through-hole set SET 2 . The first through-hole set SET 1  and the second through-hole set SET 2  may be disposed in a row in the transverse axis. The first through-hole set SET 1  and the second through-hole set SET 2  may be disposed in a row in the longitudinal axis. 
     The first island portion IS 1  may be positioned between the first through-hole set SET 1  and the second through-hole set SET 2 . The second island portion IS 2  may be positioned at a center of four through-holes in the first through-hole set SET 1 . The second island portion IS 2  may be positioned at a center of four through-holes in the second through-hole set SET 2 . 
     In the four through-hole sets SET, the two through-holes adjacent in the transverse-axis direction may refer to a first elliptical through-hole including the elliptical-shaped communication portion disposed in the first diagonal direction OL 1  and a second elliptical through-hole including the elliptical-shaped communication portion disposed in the second diagonal direction OL 2 . The two through-holes positioned in the longitudinal-axis direction of each of the two through-holes may include a third elliptical through-hole including the elliptical-shaped communication portion disposed in the second diagonal direction OL 2  positioned in the longitudinal-axis direction of the first elliptical through-hole and a fourth elliptical through-hole including the elliptical-shaped communication portion disposed in the first diagonal direction OL 1  positioned in the longitudinal-axis direction of the second elliptical through-hole. 
     When the through-holes TH are disposed in a row on the longitudinal axis and the transverse axis, respectively, the island portion IS may be positioned between two adjacent through-holes TH in the diagonal direction that is a direction intersecting both the longitudinal axis and the transverse axis. That is, the island portion IS may be positioned between two adjacent through-holes TH positioned in the diagonal direction. 
     For example, the island portion IS may be disposed between the first through-hole TH 1  and the fourth through-hole TH 4 . In addition, the island portion IS may be disposed between the second through-hole TH 2  and the third through-hole TH 3 . 
     The island portion IS may be positioned in an inclination angle direction of about +45 degrees and an inclination angle direction of about −45 degrees based on the transverse axis crossing two adjacent through-holes, respectively. Here, the inclination angle direction of about ±45 may refer to a diagonal direction between the transverse axis and the longitudinal axis, and an inclination angle in the diagonal direction may be measured on the same plane of the transverse axis and the longitudinal axis. 
     The first island portion IS 1  may be disposed between two adjacent first large surface holes V 2 - 1  in the first diagonal direction I 1  connecting the second diameter D 2  of the communication portion connected to the first large surface hole V 2 - 1 . 
     The second island portion IS 2  may be disposed between two adjacent second large surface holes V 2 - 2  in the second diagonal direction I 2  connecting the first diameter D 1  of the communication portion connected to the second large surface hole V 2 - 1 . 
     A size deviation between the adjacent first island portion IS 1  and the second island portion IS 2  may be 30% or less. The size deviation between the adjacent first island portion IS 1  and the second island portion IS 2  may be 20% or less. The size deviation between the adjacent first island portions IS 1  and the second island portions IS 2  may be 10% or less. In the deposition mask of the embodiment, the size deviation between the adjacent first island portions IS 1  and the second island portions IS 2  may be 30% or less, and thus the uniformity of the size of the through-holes may be improved. 
     The first island portion IS 1  and the second island portion IS 2  may be alternately disposed in a row in the longitudinal-axis direction. The first island portion IS 1  and the second island portion IS 2  may be alternately disposed in a row in the transverse-axis direction. 
     A size deviation between the adjacent first island portions IS 1  and the second island portions IS 2  measured in the longitudinal-axis direction or the transverse-axis direction may be 50% or less. For example, the size deviation between the adjacent first island portions IS 1  and the second island portions IS 2  measured in the longitudinal-axis direction or the transverse-axis direction may be 30% or less. For example, the size deviation between the adjacent first island portions IS 1  and the second island portions IS 2  measured in the longitudinal-axis direction or the transverse-axis direction may be 10% or less. When the size deviation between the adjacent first island portions IS 1  and the second island portions IS 2  measured in the longitudinal-axis direction or the transverse-axis direction exceeds 50%, there is a problem that the size of the deposition pattern differs according to the diagonal direction. 
     The island portion IS of  FIGS.  6  to  9    may refer to a non-etched surface between the through-holes TH on the other surface  102  of the deposition mask  100  in which the large surface hole V 2  of the effective portion AA is formed. In detail, the island portion IS may be the other surface of the deposition mask  100  that is not etched except for the second inner surface ES 2  positioned in the large surface hole and the through-hole TH in the effective portion AA of the deposition mask. 
     Referring to  FIGS.  8  and  9   , in the deposition mask according to the embodiment, the uniformity of the island portion may be improved while a pattern of the communication portion has an elliptical shape inclined at different angles. 
     For example, a size of the first island portion I 1  positioned in the first diagonal direction I 1  may be the same as or similar to a size of the second island portion IS 2  positioned in the second diagonal direction I 2 . A size deviation between the size of the first island portion I 1  and the size of the second island portion IS 2  may be 50% or less. Here, the similarity in size may refer that the size deviation between the size of the first island portion I 1  and the size of the second island portion IS 2  is 30% or less. For example, a size deviation of the first island portion and the second island portion disposed in a row in the longitudinal-axis direction may be 20% or less. A size deviation of the first island portion and the second island portion disposed in a row in the transverse-axis direction may be 10% or less. 
     In the deposition mask of the embodiment, the uniformity of the deposition pattern may be improved regardless of the deposition direction. That is, in the deposition mask of the embodiment, a deviation between the size of the two island portions adjacent to the transverse-axis direction, the size of the two island portions adjacent to the longitudinal-axis direction, and the size of the two island portions adjacent to the diagonal direction may be 50% or less and 30% or less, and thus the uniformity of the deposition pattern may be improved. 
     The deposition mask  100  of the embodiment may be for deposition of high-resolution to ultra-high-resolution OLED pixels having a resolution of 400 PPI or more. The deposition mask  100  of the embodiment may be for deposition of high-resolution to ultra-high-resolution OLED pixels having a resolution of 600 PPI or more. The deposition mask  100  of the embodiment may be for deposition of high-resolution to ultra-high-resolution OLED pixels having a resolution of 700 PPI or more. The deposition mask  100  of the embodiment may be for deposition of high-resolution to ultra-high-resolution OLED pixels having a resolution of 800 PPI or more. 
     For example, the deposition mask  100  of the embodiment may be for forming a deposition pattern having a high resolution of Full HD (High Definition) having a resolution of 400 PPI or more. For example, the deposition mask  100  of the embodiment may be for deposition of an OLED pixel in which the number of pixels in the horizontal and vertical directions is 1920*1080 or more and 400 PPI or more. That is, one effective portion included in the deposition mask  100  of the embodiment may be for forming the number of pixels having a resolution of 1920*1080 or more. 
     For example, the deposition mask  100  of the embodiment may be for forming a deposition pattern having a high resolution of quad high definition (QHD) having a resolution of 500 PPI or more. For example, the mask  100  for deposition according to the embodiment may be for deposition of an OLED pixel in which the number of pixels in the horizontal and vertical directions is 2560*1440 or more and 530 PPI or more. Through the deposition mask  100  of the embodiment, the number of pixels per inch may be 530 PPI or more based on a 5.5-inch OLED panel. That is, one effective portion included in the deposition mask  100  of the embodiment may be for forming the number of pixels having a resolution of 2560*1440 or more. 
     For example, the deposition mask  100  of the embodiment may be for forming a deposition pattern having an ultra-high resolution of ultra-high definition (UHD) having a resolution of 700 PPI or more. For example, the deposition mask  100  of the embodiment may be for forming a deposition pattern having a resolution of ultra-high definition (UHD) for deposition of an OLED pixel in which the number of pixels in the horizontal and vertical directions is 3840*2160 or more and 794 PPI or more. 
     A diameter of the through-hole TH may be a width between the communication portions CA. In detail, the diameter of the through-hole TH may be measured at a point where an end of an inner surface in the small surface hole V 1  meets an end of an inner surface in the large surface hole V 2 . The first diameter D 1  defined as the maximum diameter of the through-hole TH may be 33 μm or less. Here, the diameter may refer to an average diameter of various through-holes. Therefore, the deposition mask  100  according to the embodiment may implement QHD-level resolution. For example, the first diameter D 1  may be about 15 μm to about 33 μm. For example, the first diameter D 1  may be about 19 μm to about 33 μm. For example, the first diameter D 1  may be about 20 μm to about 27 μm. When the first diameter D 1  exceeds about 33 μm, it may be difficult to implement a resolution of 500 PPI or more. Meanwhile, when the first diameter D 1  is less than about 15 μm, a deposition defect may occur. 
     In addition, as shown in  FIG.  9   , the large surface holes V 2 : V 2 - 1  and V 2 - 2  may include a plurality of inner surfaces. In detail, the large surface hole V 2  may include a 2-1 inner surface ES 2 - 1  and a 2-2 inner surface ES 2 - 2 . The large surface hole is formed by connecting a plurality of 2-1 inner surfaces ES 2 - 1  and a plurality of 2-2 inner surfaces ES 2 - 2 . The plurality of 2-1 inner surfaces ES 2 - 1  and the plurality of 2-2 inner surfaces ES 2 - 2  form a large surface hole of one through-hole. 
     The 2-1 inner surface ES 2 - 1  of the large surface hole is an inner surface positioned in the first diameter D 1  direction based on a center of the large surface hole of the through-hole. Preferably, the 2-1 inner surface ES 2 - 1  is an inner surface positioned on both sides in a maximum diameter direction based on the center of the large surface hole. Therefore, the 2-1 inner surface ES 2 - 1  includes a first sub 2-1 inner surface adjacent to one end of the first diameter based on the center of the large surface hole of the through-hole and a second sub 2-1 inner surface positioned at the other end opposite to the one end of the first diameter. Meanwhile, a cross-sectional inclination angle of the first sub 2-1 inner surface may correspond to a cross-sectional inclination angle of the second sub 2-1 inner surface. 
     The 2-2 inner surface ES 2 - 2  of the large surface hole is an inner surface positioned in the second diameter D 2  direction based on the center of the large surface hole of the through-hole. Preferably, the 2-2 second inner surface ES 2 - 2  is an inner surface positioned on both sides in the minimum diameter direction based on the center of the large surface hole. Therefore, the 2-2 inner surface ES 2 - 2  includes a first sub 2-2 inner surface positioned at one end of the second diameter based on the center of the large surface hole of the through-hole and a second sub 2-2 inner surface positioned at the other end opposite to the one end of the second diameter. Meanwhile, a cross-sectional inclination angle of the first sub 2-2 inner surface may correspond to a cross-sectional inclination angle of the second sub 2-2 inner surface. 
     The 2-1 inner surface ES 2 - 1  and the 2-2 inner surface ES 2 - 2  may be surfaces formed by an etching factor during an etching process. The 2-1 inner surface ES 2 - 1  and the 2-2 inner surface ES 2 - 2  may be inner surfaces extending from the through-hole TH to the other surface  102  of the deposition mask  100 . For example, the 2-1 inner surface ES 2 - 1  and the 2-2 inner surface ES 2 - 2  may extend from the end of the through-hole TH toward the adjacent through-hole TH and extend toward the island portion IS. In addition, the 2-1 inner surface ES 2 - 1  and the 2-2 inner surface ES 2 - 2  may extend toward the ineffective portion UA. That is, the 2-1 inner surface ES 2 - 1  and the 2-2 inner surface ES 2 - 2  may extend in a direction in which a non-etched surface is formed among the other surfaces  102  of the deposition mask  100 . 
     Ribs RB 1  and RB 2  may be positioned between the through-holes TH. A rib RB may be positioned between the through-holes TH adjacent to each other. In detail, the ribs RB may be positioned between the large surface holes V 2  adjacent to each other. In more detail, the rib RB may be positioned in a region where the 2-1 inner surfaces ES 2 - 1  adjacent to each other are connected to each other. In more detail, the rib RB may be positioned in a region where the 2-2 inner surfaces ES 2 - 2  adjacent to each other are connected to each other. That is, the rib RB may be a region where boundaries of the large surface holes V 2  adjacent to each other are connected. 
     The deposition mask  100  according to the embodiment may deposit an OLED pixel having a resolution of 400 PPI or more. In detail, in the deposition mask  100  according to the embodiment, the diameter of the through-holes TH is about 33 μm or less, and a pitch between the through-holes TH is about 48 μm or less, and thus an OLED pixel having a resolution of 500 PPI or more may be deposited. That is, it is possible to implement QHD-level resolution using the deposition mask  100  according to the embodiment. 
     The diameter of the through-hole TH and the pitch between the through-holes TH may be a size for forming a green sub-pixel. For example, the diameter of the through-hole TH may be measured based on a green (G) pattern. Since the green (G) pattern has a low recognition rate through vision, more patterns are required than a red (R) pattern and a blue (B) pattern, and the pitch between the through-holes TH may be smaller than the red (R) pattern and the blue (B) pattern. The deposition mask  100  may be an OLED deposition mask for realizing QHD display pixels. 
       FIG.  10    is a view illustrating each cross section in an overlapping manner in order to describe a step and a size in height between a cross section in a A-A′ direction and a cross section in a B-B′ direction of  FIG.  8   . 
     First, a horizontal cross section in the A-A′ direction will be described. The A-A′ direction is a horizontal cross section crossing a central region between two adjacent first through-holes TH 1  and TH 3  in the vertical direction. That is, the horizontal cross section in the A-A′ direction may not include the through-holes TH. 
     The island portion IS may be positioned in the horizontal cross section in the A-A′ direction. Accordingly, the island portion IS may include a surface parallel to one surface of the deposition mask that is not etched. Alternatively, the island portion IS may include a surface that is the same as or parallel to the other surface of the deposition mask  100  that is not etched. 
     Next, a horizontal cross section in the B-B direction will be described. The direction B-B′ is a horizontal cross section crossing a center of each of the two adjacent first through-holes TH 1  and TH 2  in the horizontal direction. That is, the horizontal cross section in the B-B′ direction may include a plurality of through-holes TH. 
     The rib RB that is a region where an etched surface in the large surface holes and an etched surface in the adjacent large surface holes are connected to each other may be positioned in the horizontal cross section in the B-B′ direction. Here, the rib RB may be a region where a boundary between two adjacent large surface holes is connected. Since the rib RB is an etched surface, a thickness of the rib RB may be smaller than that of the island portion IS. 
     For example, a width of the island portion may be 2 μm or more. That is, a long width of the island portion IS may be 2 μm or more. When a width of one end and the other end of one island portion is 2 μm or more, the entire volume of the deposition mask may be increased. The deposition mask having such a structure may ensure sufficient rigidity with respect to the tensile force applied in an organic material deposition process, and the like and may be advantageous in maintaining the uniformity of the through-holes. 
     A process of forming a large surface hole of Example and Comparative Example is compared with reference to  FIGS.  11  to  13   . 
       FIG.  11    is a view illustrating a cross section in the first diagonal direction I 1  of Comparative Example according to  FIGS.  6  and  7   . 
     Referring to  FIGS.  6 ,  7  and  11   , the size of the first island portion IS 1  in the first diagonal direction I 1  according to the Comparative Example may be greater than the size of the second island portion IS 2  in the second diagonal direction I 2 . The size of the first island portion IS 1  in the first diagonal direction I 1  is greater than the size of the second island portion IS 2  in the second diagonal direction I 2 . Accordingly, a size of a second diameter D 2 ′ of the large surface hole V 2  positioned in the first diagonal direction I 1  may be smaller than a size of the second diameter D 2  of the large surface hole V 2  positioned in the second diagonal direction I 2 . That is, in the deposition mask according to the Comparative Example, the size of the island portion is different according to the diagonal direction and the size deviation of the large surface hole is large, and thus there is a problem that deposition efficiency is deteriorated. 
       FIG.  12    is a view illustrating a cross section in the first diagonal direction I 1  of the embodiment according to  FIGS.  8  and  9   . 
     Referring to  FIGS.  8 ,  9  and  12   , the size of the first island portion IS 1  in the first diagonal direction I 1  according to the embodiment may be the same as or similar to the size of the second island portion IS 2  in the second diagonal direction I 2 . Here, the similarity in size may refer that the size deviation between the size of the first island portion IS 1  and the size of the second island portion IS 2  is 30% or less. 
       FIG.  12    is a view illustrating a size difference between the second diameter D 2 ′ of the large surface hole V 2  of the Comparative Example and the second diameter D 2  of the large surface hole V 2  of the embodiment that are measured in the first diagonal direction I 1  in an overlapping manner. 
     Referring to  FIG.  12   , the size of the first island portion IS 1  in the first diagonal direction I 1  may be the same as or similar to the size of the second island portion IS 2  in the second diagonal direction I 2 . Accordingly, the second diameter D 2  of the large surface hole V 2  positioned in the first diagonal direction I 1  may be the same as or similar to the second diameter D 2  of the large surface hole V 2  positioned in the second diagonal direction I 2 . That is, in the deposition mask according to the embodiment, the size of the island portion is uniform regardless of the diagonal direction and the size deviation of the large surface hole is small, and thus deposition efficiency may be improved. 
       FIG.  12    illustrates a size difference between an open region of a second photoresist layer PR 2 ′ when the large surface hole V 2  of the Comparative Example is formed in the first diagonal direction I 1  and an open region of a second photoresist layer PR 2  when the large surface hole V 2  of the embodiment is formed in an overlapping manner. In the embodiment, when the first island portion IS 1  is formed in the first diagonal direction I 1 , the open region of the second photoresist layer PR 2  may be set to be larger than that of the Comparative Example. Accordingly, in the embodiment, the size of the first island portion IS 1  in the first diagonal direction I 1  may be set smaller than that of the Comparative Example. Accordingly, the embodiment may solve a problem that deposition efficiency is reduced as the elliptical through-holes are disposed in a zigzag form and the island portions are also alternately generated in the zigzag form. That is, the embodiment is to solve a problem that the size of the large surface hole differs in different diagonal directions. To this end, the embodiment may provide a deposition mask having a predetermined size of the island portion regardless of the diagonal direction and having uniform first and second diameters of the large surface holes. 
       FIG.  13    is a view illustrating cross sections in the first diagonal direction I 1  and the second diagonal direction I 2  of Comparative Example according to  FIGS.  6  and  7   . 
     In the deposition mask of Comparative Example, as the elliptical through-holes is alternately disposed in a zigzag form, there is a problem that the uniformity of the size of the large surface hole and the size of the island portion is deteriorated. Accordingly, there is a problem that a first deposition pattern DP 1  formed through a cross section in the first diagonal direction I 1  is smaller than a second deposition pattern DP 2  formed through a cross section in the second diagonal direction I 2 . That is, in the deposition mask of the Comparative Example, the size of the through-hole may differ depending on the cross-sectional direction of the diagonal line, and thus there is a problem that the size deviation of the deposition pattern manufactured is large. 
       FIG.  14    is a view illustrating cross sections in the first diagonal direction I 1  and the second diagonal direction I 2  of the embodiment according to  FIGS.  8  and  9   . 
     In the deposition mask of the embodiment, while the elliptical through-holes are alternately disposed in a zigzag form, the size of the large surface hole and the uniformity of the size of the island portion may be improved by design compensation. Accordingly, the first deposition pattern DP 1  formed through the cross section in the first diagonal direction I 1  may be uniform with the second deposition pattern DP 2  formed through the cross section in the second diagonal direction I 2 . That is, in the deposition mask of the embodiment, the size of the through-hole may be uniform regardless of the cross-sectional direction, so that the deposition pattern manufactured may have a uniform size, and thus it may be manufactured with excellent quality. 
       FIGS.  15  and  16    are views illustrating a deposition pattern formed through a deposition mask according to an embodiment. 
     Referring to  FIG.  15   , in the deposition mask  100  according to the embodiment, a height H 1  between one surface of the deposition mask  100  in which the small surface hole V 1  is formed and the communication portion may be about 5 μm or less. Accordingly, a distance between the one surface of the deposition mask  100  and the substrate on which the deposition pattern is disposed may be close, thereby reducing deposition defects caused by a shadow effect. For example, when R, G, and B patterns are formed using the deposition mask  100  according to the embodiment, it is possible to prevent a defect in which different deposition materials are deposited in a region between two adjacent patterns. In detail, as shown in  FIG.  16   , when the patterns are formed in an order of R, G, and B from left to right, it is possible to prevent the R pattern and the G pattern from being deposited by the shadow effect in a region between the R pattern and the G pattern. 
     In addition, the deposition mask  100  according to the embodiment may reduce the size of the island portion IS in the effective portion. In detail, since an area of the upper surface of the island portion IS, which is a non-etched surface, may be reduced, the organic material may easily pass through the through-hole TH during deposition of the organic material, thereby improving deposition efficiency. 
     The characteristics, structures, effects, and the like described in the above-described embodiments are included in at least one embodiment of the present invention, but are not limited to only one embodiment. Furthermore, the characteristic, structure, and effect illustrated in each embodiment may be combined or modified for other embodiments by a person skilled in the art. Therefore, it should be construed that the contents related to such combination and modification are included in the scope of the present invention. 
     In addition, the above description has been focused on the embodiments, but it is merely illustrative and does not limit the present invention. Those skilled in the art to which the embodiments pertain may appreciate that various modifications and applications not illustrated above are possible without departing from the essential features of the embodiment. For example, each component particularly represented in the embodiments may be modified and realized. In addition, it should be construed that differences related to such a modification and an application are included in the scope of the present invention defined in the appended claims.