FIELD OF THE INVENTION

The present invention relates to color organic light-emitting displays having a tri-color light-emitting pixel pattern.

BACKGROUND OF THE INVENTION

Tang et al. in U.S. Pat. Nos. 5,294,869 and 5,294,870 recognized the advantages of constructing organic electroluminescent multicolor image display devices by providing integrated shadow masks for the generation of laterally separated pixels capable of emitting light of different hue. Such shadow masks are comprised of walls, pillars, or ribs which are formed on a support or a substrate in a predetermined pattern, and having a height dimension selected to cast a shadow with respect to an obliquely incident vapor stream. These shadow masks separate each color subpixel from an adjacent color subpixel.

Tang et al., U.S. Pat. No. 5,550,066 describes a method of fabricating an active-matrix organic electroluminescent panel based on polysilicon thin-film transistor (TFT) arrays. With an active-matrix TFT array and integrated drivers on the substrate, organic EL displays provide many desirable attributes not commonly found in any one class of conventional displays. These attributes are high resolution, compact display geometry, self luminance, high efficiency, and a wide viewing angle. Other display technologies, in comparison, have certain deficiencies. For instance, the most common active-matrix liquid crystal displays have limited viewing angles and require a back-light for illumination. The plasma displays are self emissive, but are not power efficient. The inorganic thin-film EL displays are rugged and compact, but they require high drive voltage and are not efficient.

Tang et al., U.S. Pat. No. 5,550,066 describes the fabrication processes for an active-matrix array based on polysilicon Tufts and its integration with a monochromatic organic EL device. The integration process for the monochromatic EL device is relatively simple, involving only the deposition of the organic EL medium directly on the substrate pre-patterned with TFT pixels and necessary bus electrodes and drivers. The EL medium refers to the organic layers constituting the EL device. For full-color, active-matrix organic EL display panel providing red, green and blue colors, the EL medium requires patterning into separate and adjacent color pixels in relationship to the active matrix TFT pixels. This patterning procedure can be quite complex depending on the resolution requirements and the configuration of the EL device. This patent describes an organic color EL displays fabricated with an integrated shadow mask on the display which provides a way of patterning the organic EL medium into red, green and blue color pixels.

SUMMARY OF THE INVENTION

The present invention provides a full-color active-matrix addressable organic electroluminescent display panel.

Accordingly, it is an object of the present invention to provide a high resolution, full-color, organic electroluminescent display requiring only one level of photolithography in generating a tri-color (RGB) pixel pattern.

In one aspect of the present invention, this object is achieved in an organic electroluminescent color display, comprising:

a) a substrate;

b) a plurality of color pixels formed on the substrate;

c) each color pixel containing three primary color (red, green, and blue) subpixels;

d) an active matrix electrical addressing element associated with each color subpixel;

e) an integrated shadow mask for forming the color subpixels and includes a plurality of pillar structures erected on the substrate;

f) the pillar structures having a geometric arrangement which permits the formation of each color subpixel independent of the formation of the other two color subpixels and wherein the formation of each color subpixel is provided by a line-of-sight vapor deposition for selective patterning the color subpixel; and

g) a common light-transmissive electrode over the plurality of color pixels.

In another aspect of the present invention, this object is achieved in an organic light-emitting color display, comprising:

a) a substrate;

b) a plurality of color pixels formed on the substrate;

c) each color pixel containing three primary color (red, green, and blue) subpixels;

d) an active matrix electrical addressing element associated with each color subpixel;

e) an integrated shadow mask for forming the color subpixels includes a plurality of pillar structures erected on the substrate and wherein the pillar structures having a geometric arrangement which permits the formation of each color subpixel independent of the formation of the other two color subpixels and wherein the formation of each color subpixel is provided by a line-of-sight vapor deposition for selective patterning the color changing medium;

f) each color subpixel having a short wavelength organic electroluminescent (EL) emitter and a fluorescent color conversion layer formed over the EL emitter; and

g) a common light-transmissive electrode over the EL emitter.

In a further aspect of the present invention, this object is achieved in an organic light-emitting color display, comprising:

a) a substrate;

b) a plurality of color pixels formed on the substrate;

c) each color pixel containing three primary color (red, green, and blue) subpixels;

d) an active matrix electrical addressing element associated with each color subpixel;

e) an integrated shadow mask for forming the color subpixels includes a plurality of pillar structures erected on the substrate;

f) the pillar structures having a geometric arrangement which permits the formation of each color subpixel independent of the formation of the other two color subpixels; wherein

g) each color subpixel having an organic electroluminescent (EL) emitter with an emissive layer capable of producing a primary color; wherein

h) the formation of each color subpixel is provided by a line-of-sight vapor deposition for selective patterning the emissive layer of the EL emitter; and

i) a common light-transmissive electrode over the EL emitter.

ADVANTAGES

An advantage of this invention is that the fabrication of a full-color active-matrix organic light-emitting diode (OLED) display panel is simple and economical. The fabrication requires only one additional level of photolithography for the construction of an integrated shadow mask and for the color subpixel patterning scheme.

The integrated shadow mask (also referred to as an in-situ shadow mask) ensures that the deposited fluorescent color conversion layer is self-aligned with respect to a designated color subpixel area. This self-alignment feature is highly precise and therefore it is particularly useful for the fabrication of high-resolution color OLED display panels. Color pixel pitch of less than 10 micrometers can be readily achieved by the pillar structure shadow masks of the invention.

Excellent optical coupling between a short wavelength OLED emitter and a fluorescent color conversion or a fluorescent color changing layer is ensured, since the fluorescent layer is formed within a fraction of a micrometer over the short wavelength light-emitting layer. Thus, efficient color conversion from near ultraviolet or blue to green and from near ultraviolet or blue to red can be accomplished.

Vapor deposition for producing a color conversion fluorescent layer is fully compatible with OLED device fabrication. In particular, the exposure of an ambient-sensitive OLED device to ambient air throughout the entire production cycle is not necessary, thus avoiding the possibility of device degradation due to the elements of air and/or moisture. The color OLED panel fabrication can proceed in a vacuum deposition chamber without a vacuum break, starting with the deposition of the blue emitting OLED array to the deposition of the fluorescent color conversion layers.

The integrated shadow mask structures can also be used to provide full-color display panels having red, green, and blue light-emitting pixels (or subpixels) formed directly from layers of organic electroluminescent (EL) materials.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-6

show the fabrication of a full-color active-matrix organic EL display panel using integrated shadow mask structures to pattern color conversion (color changing) layers in accordance with the present invention, wherein

FIG. 1

is a schematic side view of a subpixel arrangement over a substrate and including subpixel electrodes and associated active matrix electrical addressing transistor elements;

FIG. 2

shows an electrically insulative passivation layer covering the transistor addressing elements and providing an exposed portion of each subpixel electrode;

FIG. 3

shows a first embodiment of an integrated shadow mask structure erected on the passivation layer at designated locations;

FIG. 4

depicts a blue light-emitting organic electroluminescent (EL) layer formed over each subpixel, and a common light-transmissive electrode formed over the blue light-emitting layer;

FIG. 5

shows the deposition of a fluorescent green color conversion layer by vapor deposition from an oblique angle with respect to the shadow mask and the consequent formation of a green color subpixel; and

FIG. 6

shows the deposition of a fluorescent red color conversion layer by vapor deposition from an oblique angle (in opposite direction) with respect to the shadow mask and the consequent formation of a red color subpixel.

FIGS. 7-10

show the fabrication of a full-color active matrix organic EL display panel using integrated shadow mask structures of a second embodiment to pattern color conversion (color changing) layers in accordance with the present invention, wherein

FIG. 7

is a schematic side view of a subpixel arrangement over a substrate, subpixel electrodes and associated active matrix electrical addressing elements, an electrically insulative passivation layer, and a second embodiment of an integrated shadow mask structure erected on the passivation layer at designated locations;

FIG. 8

depicts a blue light-emitting organic electroluminescent (EL) layer formed over each subpixel, and a common light-transmissive electrode formed over the blue light-emitting layer;

FIG. 9

shows the deposition of a fluorescent green color conversion layer by vapor deposition from an oblique angle with respect to the shadow mask and the consequent formation of a green color subpixel; and

FIG. 10

shows the deposition of a fluorescent red color conversion layer by vapor deposition from an oblique angle (in opposite direction) with respect to the shadow mask and the consequent formation of a red color subpixel;

FIGS. 11-13

show the fabrication of a full-color active matrix organic EL display panel using the integrated shadow mask structures of the second embodiment shown in

FIGS. 7-10

to provide subpixel patterns of three primary color emissive layers in accordance with the present invention, wherein

FIG. 11

shows the patterned vapor deposition of a green emissive subpixel layer;

FIG. 12

shows the patterned vapor deposition of a red emissive subpixel layer; and

FIG. 13

depicts the formation of a blue emissive subpixel layer, and of a common light-transmissive electrode over the light-emissive layers;

FIGS. 14 and 15

are schematic plan views of two different pixels configurations in accordance with the present invention, wherein

FIG. 14

shows a color pixel comprising individual primary color (RGB) subpixel areas defined by the integrated shadow mask of the first embodiment, with each individual color subpixel associated with a transistor addressing element; and

FIG. 15

depicts a color pixel comprising multiple repeating primary color (RGB) elements defined by the integrated shadow mask of the first embodiment, with color elements of the same color being electrically connected in parallel to a transistor addressing element.

Since device feature dimensions such as layer thicknesses are frequently in sub-micrometer ranges, the drawings are scaled for ease of visualization rather than dimensional accuracy, and in order to preserve clarity of presentation, vapor deposited layers formed over uppermost surfaces of the shadow masks have been omitted.

DETAILED DESCRIPTION OF THE INVENTION

The acronym EL is, in some instances, employed for the term “electroluminescent”. The acronym OLED is, in some instances, employed for the term “organic light-emitting diode”. The term “pixel” is employed in its art recognized usage to designate an area of an image display array that can be stimulated to emit light independently of other areas. The term “subpixel” is used to designate an area of a pixel which can be addressed to emit light of a particular hue in a multicolor display. The term “multicolor” is employed to describe image displays having a plurality of color pixels in which each color pixel comprises at least two color subpixels, each of which emits light of a different hue. The term “full-color” is employed to describe multicolor image displays having a plurality of color pixels, each comprised of three primary color subpixels, each capable of emitting light in one of the red, green, and blue regions of the visible spectrum. The term “hue” refers to the intensity profile of light emission within the visible spectrum, with different hues exhibiting visually discernible differences in color. The term “light-transmissive” is used to describe an electrode which transmits therethrough at least fifty percent of light throughout a spectral region having a 100 nm width. The term “reflective” is used to describe an electrode which reflects therefrom at least fifty percent of light throughout a spectral region of a 100 nm width.

FIGS. 1-6

indicate schematically the fabrication of a full-color organic light-emitting display panel in accordance with the present invention. It will be appreciated that such a display panel comprises a plurality of organic light-emitting pixels arranged in a two-dimensional array.

Referring to

FIG. 1

, first, second, and third laterally spaced subpixel electrodes

32

,

34

, and

36

, respectively, are formed over a substrate

12

for each of the light-emitting pixels. Corresponding electrical addressing elements

22

,

24

, and

26

, respectively, are provided over the substrate so that each of the subpixel electrodes can be electrically addressed with an electrical signal. The substrate

12

can be constructed of a variety of materials which provide physical integrity and electrical characteristics commensurate with the fabrication and operation of a display panel. Particularly preferred materials for the substrate

12

are crystalline silicon, glass, quartz, and ceramic materials. When the substrate

12

is constructed of crystalline silicon, the electrical addressing elements

22

,

24

, and

26

include, preferably, transistors fabricated by a CMOS process in accordance with processing steps well known in the semiconductor industry. When the substrate

12

is selected to be of glass, quartz, or ceramics, the electrical addressing elements are preferably thin film transistors (TFTs) fabricated in a manner similar to TFTs used in thin film active-matrix liquid crystal display panels. The TFTs can be made of amorphous or of polycrystalline silicon. The subpixel electrodes

32

,

34

, and

36

of each of pixel are constructed preferably of a reflective electrode material such as, for example, aluminum or an aluminum-silicon alloy.

Turning now to

FIG. 2

, an electrically insulative passivation layer

42

,

44

, and

46

is formed over each corresponding electrical addressing element and extending over portions of associated subpixel electrodes

32

,

34

, and

36

, respectively, thereby providing exposed portions

33

,

35

, and

37

of each of these laterally spaced electrodes.

Turning to

FIG. 3

, a first embodiment of an integrated shadow mask structure is now constructed by forming first, second, and third spaced deposition-controlling rib or pillar structures for each pixel. The ribs or pillars are arranged for each light-emitting pixel so that the first and second subpixel electrodes

32

and

34

are positioned between a first and a second vapor deposition-controlling pillar shadow mask structure

52

and

54

, and the third subpixel electrode

36

is positioned between the second pillar

54

and a third pillar structure shadow mask

56

. The pillar structures have a height dimension H, which is preferably in a range of 0.5 to 5 times the lateral dimensions of the color subpixel pitch, i.e. the repeat distance between color subpixels.

Following the teachings of Tang et al. in the above referenced U.S. Pat. Nos. 5,294,869 and 5,294,870, the pillars

52

,

54

, and

56

can be formed from a negative-working photoresist composition which is spin-coated and patterned by a photolithographic processing step. The simplicity and advantage of the arrangement of the pillar structure shadow masks for the vapor deposition of patterned color conversion fluorescent layers will become more readily apparent through the description of the vapor deposition sequences detailed in

FIGS. 5 and 6

.

Referring to

FIG. 4

, an organic electroluminescent layer

60

is formed at least over the exposed portion of each subpixel electrode and over the insulative passivation layers. A common light-transmissive electrode

72

is formed over the organic EL layer

60

.

The layer

60

includes an organic light-emitting material capable of emitting light in a blue (“B”) spectral region in response to an electrical addressing provided between one of the electrodes

32

,

34

, or

36

and the light-signal transmissive common electrode

72

.

The blue light-emitting organic EL layer

60

is comprised of a plurality of superimposed layers which can include a hole-injecting layer, a hole-transporting layer, a blue light-emitting layer, and an electron-transporting and injecting layer, as detailed in the Tang et al, U.S. Pat. No. 5,294,870, the disclosure of which is hereby incorporated by reference. To preserve visual clarity of the drawings, these superimposed organic layers are depicted here as single layers. It is noted that superimposed layers or multi-layers provide an internal junction between an electron-injecting and transporting zone and a hole-injecting and transporting zone so that hole-electron recombination at the junction provides light-emission therefrom and of a hue which is determined by the light-emitting materials present at the junction or within molecular distances therefrom.

Particularly preferred blue light-emitting organic EL materials are those which emit in a spectral region below 480 nm and which are capable of exciting each of the fluorescent color conversion layers.

The layer

60

(or sublayers thereof) can be formed by conventional vapor phase deposition. The light-transmissive common electrode

72

can be deposited by vapor phase deposition, by sputter deposition, or by electron beam deposition. Preferred light-transmissive electrode materials include indium oxide, zinc oxide, tin oxide, indium-tin oxide (ITO) or combinations of oxides of indium, tin, and zinc, and chromium cermat light-transmissive materials. Such common electrodes have a thickness in a preferred range of 0.01 to 0.5 micrometer, and a transparency greater than fifty percent.

Referring to

FIG. 5

, a green color conversion vapor deposition stream

81

is shown directed toward the surfaces of the common electrode

72

under an oblique angle &THgr; with respect to the shadow mask pillars

52

,

54

, and

56

such that a green (“G”) color conversion layer

82

is formed over a portion of the common electrode

72

and overlying the first subpixel electrode

32

, and delineated by the shadowing effect of the shadow mask pillar

54

. The green color conversion layer extends upwardly along the pillar

52

and the pillar

54

outside of the exposed portions of the pixel electrodes. As indicated previously, layers formed over the top portions of the pillars are not shown in the drawings to preserve clarity of presentation.

Referring to

FIG. 6

, a red color conversion vapor deposition stream

91

is now shown incident under an angle −&THgr; (i.e. in an opposing direction relative to the vapor stream

81

). A red color conversion layer

94

(“R”) is thereby formed selectively over the common electrode

72

and overlying the exposed portion of the second subpixel electrode

34

, and delineated primarily by the shadowing effect of the pillar shadow mask

52

. It will be appreciated that a thickness dimension of the color conversion layers

82

and

94

is in a range of 0.02-0.2 micrometer, while the pillar structure shadow masks

52

,

54

, and

56

have a width dimension (not shown) in a range of 2-10 micrometer. Accordingly, the color conversion layers extending upwardly along the pillars have a negligible effect on the shadow-casting performance of the masks.

Each of the third light-emitting subpixels, identified by the subpixel subelectrodes

36

, is not covered by either of the two different color conversion layers

82

and

94

, thus remaining capable of emitting blue light (“B”). The color pixel P is comprised of laterally spaced color subpixels pg, pr, and pb.

The color conversion layers

82

and

94

are formed of a single or of a composite fluorescent material capable of efficiently absorbing blue light emitted from the organic electroluminescent layer

60

and efficiently converting the absorbed blue light to provide green and red emissions, respectively. Since a thickness dimension (not shown) of the light-transmissive common electrode

72

is typically smaller than 0.2 micrometer, optical coupling with minimal divergent loss between the blue light-emitting layer

60

and the color conversion layers

82

and

94

is ensured.

Thus, the particular geometric arrangement of this embodiment of the pillar structure shadow masks

52

,

54

, and

56

with respect to the subpixel electrodes

32

,

34

, and

36

represents a simple and accurate self-alignment feature for forming a full-color organic light-emitting display which has a plurality of light-emitting pixels. As shown here, adjacent green and red subpixels are defined by and between first pillar structures

52

and second pillar structures

54

. Blue subpixels are disposed between second pillar structures

54

and third pillar structures

56

.

Referring to the sequence of

FIGS. 7-10

, there is shown schematically the fabrication of a full-color active matrix organic EL display panel using integrated shadow mask pillar structures of a second embodiment to pattern color conversion (color changing) layers. With few exceptions, numeral designations of like parts are identical to the parts or elements described in

FIGS. 1-6

, and will therefore not be further detailed.

This embodiment uses only two shadow mask pillar structures

52

and

56

to define three adjacent color subpixels therebetween.

FIG. 7

shows the subpixel electrodes

32

,

34

, and

36

, and associated active matrix electrical addressing elements

22

,

24

, and

26

as provided in FIG.

2

.

FIG. 8

depicts a blue (“B”) light-emitting organic EL layer

60

formed over each subpixel between two pillar structures

52

,

56

, and a common light-transmissive electrode

72

disposed over the EL layer

60

.

In

FIG. 9

is shown the deposition of a green (“G”) color changing layer

82

which is selectively patterned in alignment with the designated subpixel electrode

32

by the vapor stream

81

which is incident on the electrode layer

72

under an oblique angle &sgr; with respect to the pillar structures, whereby the pillar structure

56

provides the shadowing or masking effect.

FIG. 10

shows the deposition of a red (“R”) color changing layer

94

which is selectively patterned in alignment with the designated subpixel electrode

36

by the vapor stream

91

which is incident on the electrode layer

72

under an oblique angle −&sgr;, whereby the pillar structure

52

now provides the shadowing or masking effect. The centrally disposed blue (“B”) light-emitting subpixel has been shadowed or masked from receiving a color changing layer by the mask structures

56

and

52

which selectively intercept the vapor streams

81

,

91

at the designated angles &sgr; and −&sgr;.

Thus, in this embodiment of integrated shadow mask pillar structures, color pixels are comprised of three adjacent color subpixels defined and patterned by and between two pillar structures.

Both embodiments (see

FIGS. 1-6

and

FIGS. 7-10

, respectively) of the integrated shadow mask pillar structures of the invention provide a further significant advantage in the fabrication of full-color active matrix organic EL display panels in that primary color subpixels can be fabricated either by selective patterning of color changing layers (color conversion layers) as described above, or alternatively by selective patterning of organic EL layers which are capable of directly emitting red, green, or blue light from corresponding color subpixels. The fabrication of a full-color direct light-emitting organic EL display panel is shown schematically in

FIGS. 11-13

with the shadow mask pillar configuration of the second embodiment.

Turning to

FIG. 11

, a vapor stream

83

of an organic EL medium is directed at the subpixel electrode

32

under an angle &sgr; to form an emissive organic EL layer

85

thereon which is capable of directly emitting green (“G”) light.

In

FIG. 12

, a vapor stream

93

of an organic EL medium is directed at the subpixel electrode

36

under an angle −&sgr; to form an emissive organic EL layer

95

thereon which is capable of directly emitting red (“R”) light.

FIG. 13

shows an emissive organic EL layer

65

formed over the central subpixel electrode

34

and over the green and red subpixel layers

85

and

95

. A light-transmissive common electrode

72

is disposed over the organic EL layers.

The organic EL layer

65

is capable of directly emitting blue (“B”) light, but only in the location over the subpixel electrode

34

, because only in this location is the layer

65

forming a light-emitting junction in the previously described arrangement of superimposed organic layers (not shown in the drawings). The green and red emissive layers

65

,

95

are comprised of a light-emitting host material and respectively at least one green-emitting fluorescent dopant for the green color subpixels, and at least one red-emitting fluorescent dopant for the red color subpixels, wherein the fluorescent dopants are uniformly dispersed throughout the host material.

The emissive layer

65

, capable of producing a blue primary color from the subpixel electrode

34

, includes a blue light-emitting organic host material. Blue light-emitting organic host materials can be selected from among those disclosed in U.S. Pat. No. 5,130,603 to Takailin et al, U.S. Pat. No. 5,645,948 to Shi, and U.S. Pat. No. 5,141,671 to Bryan et al, the disclosures of which are herein included as references.

Referring to

FIG. 14

, it is a plan view of a tri-colored pixel P

1

having one green, red, and blue emitting subpixel pg, pr, and pb arranged laterally between shadow mask pillar structures

52

,

54

, and

56

of the first embodiment in correspondence with the schematic side view of FIG.

6

. Transistor elements T(g), T(r), and T(b) are shown schematically to correspond to electrical addressing elements

22

,

24

, and

26

(see

FIG. 1

) to provide tri-color light emission.

Turning to

FIG. 15

, a pixel P

3

is shown in schematic plan view as having a set of green, red, and blue light-emitting subpixels formed in a repeating pattern of repeat color elements between repeating shadow masks pillar structure designated here as

52

a,

54

a,

and

56

a.

Each color subpixel comprises three spatially separated color elements having repeating shadow mask pillar structures designated as

52

a,

54

a,

and

56

a.

The color elements of each color subpixel are electrically connected in parallel to an addressing transistor. Transistor elements T(g), T(r), and T(b) are indicated schematically to address the green, red, and blue color subpixels, respectively. For example, when the addressing element T(g) is actuated, all color elements of the green subpixel of the pixel P

3

will be stimulated to emit green light. This construction of full-color pixels P

3

is particularly advantageous when pillar structures of a reduced height dimension are desired.

It will be appreciated that a full-color organic light-emitting display having a plurality of light-emitting color pixels arranged in a two-dimensional array will produce an image display comprised of subpixels of tri-color light emission wherein the color subpixels have dimensions sufficiently small (for example, a subpixel dimension in a range of 5-10 micrometer) to provide a high resolution display panel having a color pixel resolution greater than about 2000 dots per inch. Such high resolution full-color displays can be fabricated in accordance with the present invention through appropriate scaling of the addressing elements, the pixel electrodes, and the integrated self-aligning pillar structure shadow masks.

In the drawings, each of the color subpixels of a color pixel has been shown with approximately equal lateral dimensions. It will be appreciated that a color pixel pitch (the lateral spacing between color pixels) can be maintained when it is desired to construct color subpixels having unequal lateral dimensions. For example, all green color subpixels can have an extended lateral dimension to achieve enhanced emission of green light. To retain a desired pitch of color pixels, the lateral dimensions of the red and/or blue subpixels will be reduced commensurately.

The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.

PARTS LIST

12

substrate

22, 24, 26

electrical addressing elements

32, 34, 36

subpixel electrodes

33, 35, 37

exposed portions of subpixel electrodes

42, 44, 46

insulative passivation

52, 54, 56

pillar structure shadow masks of a set of subpixels

forming a pixel

52a, 54a, 56a

pillar structure shadow masks of sets of subpixels

forming a pixel

60

blue light-emitting organic EL layer (“B”)

65

blue subpixel organic EL layer

72

light-transmissive common electrode

81

green color conversion vapor deposition stream

82

green color conversion layer (“G”)

83

green EL vapor stream

85

green subpixel organic EL layer

91

red color conversion vapor deposition stream

93

red EL vapor stream

94

red color conversion layer (“R”)

95

red subpixel organic EL layer

G

green

R

red

B

blue

H

height dimension of pillar structures

P

color pixel

P1

pixel having one G, R, and B subpixel

P3

pixel having three G, R, and B color elements

pb

blue color subpixel

pg

green color subpixel

pr

red color subpixel

T(g)

transistor addressing element for green subpixel(s)

T(r)

transistor addressing element for red subpixel(s)

T(b)

transistor addressing element for blue subpixel(s)

&THgr;, −&THgr;

angles of green, red vapor deposition streams

(three pillar structure embodiment)

&sgr;, −&sgr;

angles of green, red vapor deposition streams

(two pillar structure embodiment)