This application makes reference to, incorporates the same herein, and claims all benefits accruing under 35 U.S.C. §119 from an application for ELECTRON EMISSION DISPLAY DEVICE earlier filed in the Korean Intellectual Property Office on Apr. 29, 2004 and there duly assigned Serial No. 10-2004-0029879.
1. Technical Field
The present invention relates to an electron emission display device and, more particularly, to an electron emission display device which prevents a waveform distortion phenomenon and an occurrence of arcing of an output voltage, and which enables the application of a high voltage to an anode electrode.
2. Related Art
Generally, an electron emission display device is a flat display device that displays predetermined images using light generated by electrons emitted from a first substrate, which electrons collide with a fluorescent layer formed on a second substrate. The first substrate can be a hot cathode electrode or a cold cathode electrode as an electron source.
A field emission display (FED) device is an electron emission display device that uses a cold cathode electrode, and it can be a field emitter array (FEA) type, a metal-insulator-metal (MIM) type, a metal-insulator-semiconductor (MIS) type, or a surface conduction electron-emitting (SCE) type.
The FED device includes a rear panel on which a field emission device is formed, a front panel on which there is formed a fluorescent layer that generates an image using light generated by electrons emitted from the field emission device, and a sealing member that seals the front panel and the rear panel. In this case, the sealing member, an anode electrode disposed on the sealing member, and a cathode electrode-gate electrode disposed under the sealing member constitute a capacitor, and accordingly, the following formula holds:
Q=C·V [Formula 1]
where V is an electric potential difference applied to the electrodes dispose on and under the sealing member, Q is an amount of charge accumulated in each of the electrodes disposed on and under the sealing member when the electric potential difference V is applied thereto, and C is the capacitance, i.e., a constant determined by the geometrical structure of the electrodes disposed on and under the sealing member.
According to the above formula, charges are accumulated on upper and lower parts of the sealing member when voltages are applied to the electrodes disposed on and under the sealing member. In this case, there is a problem in that a desired electric potential difference cannot be applied to the field emission device until sufficient charges are accumulated on the upper and lower parts of the sealing member. Also, there is a problem in that a voltage higher than a certain value is applied to the upper and lower parts of the sealing member until a sufficient amount of accumulated charges are discharged from the upper and lower parts of the sealing member when the voltage applied to the electrodes disposed on and under the sealing member is cut off. These denote a waveform distortion of an output voltage, which eventually may result in the distortion of displayed images. Also, according to the above formula, when the higher electric potential differences are applied to the electrodes disposed on and under the sealing member, the amount of charges accumulated on the upper and lower parts of the sealing member increases. This can cause an arcing of the output voltage, thereby reducing the lifetime of the FED device.
The present invention provides an electron emission display device that can prevent a distortion of image by preventing a waveform distortion phenomenon and an arcing of an output voltage as a result of reducing charges accumulated on upper and lower parts of a sealing member that seals a front panel and a rear panel.
According to an aspect of the present invention, there is provided an electron emission display device comprising: a front panel which includes a front substrate, an anode electrode formed on a surface of the front substrate, and a fluorescent layer; a rear panel which includes a rear substrate disposed to face the front substrate at a predetermined distance, electron emitters formed on the rear substrate, and at least one driving electrode that controls the emission of electrons from the electron emitters; a sealing member that seals the front and rear panels; and at least one dielectric layer having a dielectric constant less than that of the sealing member, and included in the sealing member.
According to specific embodiments of the electron emission display, the dielectric layer may be disposed between the sealing member and the front panel, or between the sealing member and the rear panel.
The fluorescent layer may be formed to expose an end of the anode electrode, and the dielectric layer may be disposed between the sealing member and the anode electrode, or between the sealing member and the driving electrode.
The dielectric layer may be a thick film. The dielectric layer may be formed of PbO—SiO2—B2O3. The sealing member may be a sealing glass frit. The dielectric constant of the sealing glass frit may be greater than 20 F/m and less than 40 F/m, and the dielectric constant of the dielectric layer may be greater than 10 F/m and less than 20 F/m.
Another electron emission display device according to the present invention comprises: a front panel which includes a front substrate, an anode electrode formed on a surface of the front substrate, and a fluorescent layer; a rear panel which includes a rear substrate disposed facing the front substrate, cathode electrodes formed on the rear substrate, an insulating layer that covers the cathode electrodes and an entire surface of the rear substrate, gate electrodes formed to cross the cathode electrode on the insulating layer, gate holes formed through the gate electrodes and the insulating layer at a region crossing the cathode electrode and the gate electrodes, and electron emitters formed in the gate holes; a sealing member that seals the front and rear panels; and at least one dielectric layer having a dielectric constant less than that of the sealing member, and included in the sealing member.
According to a specific embodiment of the electron emission display device, the dielectric layer may be disposed between the sealing member and the front panel, or between the sealing member and the rear panel.
The fluorescent layer may be formed to expose an end of the anode electrode, and the dielectric layer may be disposed between the sealing member and the anode electrode, or between the sealing member and one of the driving electrodes and the insulating layer.
The dielectric layer may be a thick film. The dielectric layer may be formed of PbO—SiO2—B2O3. The sealing member may be a sealing glass frit. The dielectric constant of the sealing glass frit may be greater than 20 F/m and less than 40 F/m, and the dielectric constant of the dielectric layer may be greater than 10 F/m and less than 20 F/m.
Another electron emission display device according to the present invention comprises: a front panel which includes a front substrate, an anode electrode formed on a surface of the front substrate, and a fluorescent layer; a rear panel which includes a rear substrate disposed facing the front substrate, gate electrodes formed on the rear substrate, an insulating layer that covers the gate electrodes and is formed on an entire surface of the rear substrate, cathode electrodes formed to cross the gate electrodes on the insulating layer, and electron emitters electrically connected to the cathode electrodes; a sealing member used to seal the front and rear panels; and at least one dielectric layer having a dielectric constant less than that of the sealing member, and included in the sealing member.
According to specific embodiments of the electron emission display device, the dielectric layer may be disposed between the sealing member and the front panel, or between the sealing member and the rear panel.
The fluorescent layer may be formed to expose an end of the anode electrode, and the dielectric layers may be disposed between the sealing member and the anode electrode, or between the sealing member and one of the driving electrodes and the insulating layer.
The dielectric layer may be a thick film. The dielectric layer may be formed of PbO—SiO2—B2O3. The sealing member may be a sealing glass frit. The dielectric constant of the sealing glass frit may be greater than 20 F/m and less than 40 F/m, and the dielectric constant of the dielectric layer is greater than 10 F/m and less than 20 F/m.
A more complete appreciation of the invention, and many of the attendant advantages thereof, will be readily apparent as the same becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings in a which like reference symbols indicate the same or similar components, wherein:
The present invention will now be described more fully with reference to the accompanying drawings in which exemplary embodiments of the invention are shown.
Referring to
Q=C·V [Formula 1]
where V is an electric potential difference applied to the electrodes dispose on and under the sealing member 2, Q is an amount of charge accumulated in each of the electrodes disposed on and under the sealing member 2 when the electric potential difference V is applied thereto, and C is the capacitance, i.e., a constant determined by a geometrical structure of the electrodes disposed on and under the sealing member 2.
According to the above formula, charges are accumulated on upper and lower parts of the sealing member 2 when voltages are applied to the electrodes disposed on and under the sealing member 2. In this case, there is a problem in that a desired electric potential difference can not be applied to the field emission device until sufficient charges are accumulated on the upper and lower parts of the sealing member 2. Also, there is a problem in that a voltage higher than a certain value is applied to the upper and lower parts of the sealing member 2 until a sufficient amount of accumulated charges are discharged from the upper and lower parts of the sealing member 2 when the voltage applied to the electrodes disposed on and under the sealing member 2 is cut off. These denote a waveform distortion of an output voltage, which eventually may result in the distortion of displayed images. Also, according to the above formula, when the higher electric potential differences are applied to the electrodes disposed on and under the sealing member 2, the amount of charges accumulated on the upper and lower parts of the sealing member 2 increases. This can cause an arcing of the output voltage, thereby reducing the lifetime of the FED device.
As depicted in
In
Further referring to
The total capacitance C′ of the capacitors in
The capacitance of the capacitor in
On the other hand, if the capacitor in
At this time, if the thickness of the dielectric layer is d2, and dielectric layers having dielectric constant ∈1 and thickness d1 are inserted on and under the dielectric layer having the thickness d2, a modified capacitance will be as shown as Formula 3. Therefore, the capacitance C′ can have a desired value by appropriately selecting ∈1, d1 and d2. In the present invention, ∈1, d1 and d2 can be appropriately selected so that the capacitance C′ is smaller than the capacitance C since a desired effect can be obtained when the capacitance C′ is small. For example, to reduce the capacitance C′ so that C′=C×1/k, where k is a constant greater than 1, the following conditions can be obtained from Formulae 3 and 4.
Accordingly, the capacitance C′ can be reduced by 1/K times by inserting a dielectric layer having a dielectric constant smaller by 1/k times than the dielectric constant of the particular dielectric layer. The Formulae 3, 4, and 5 are derived assuming that the capacitors behave ideally.
Referring to
More specifically, a plurality of gate electrodes 12 with a predetermined pattern, such as a stripe pattern, are formed on the rear substrate 10, an insulating layer 14 that covers the gate electrodes 12 is formed on an entire surface of the rear substrate 10, and a plurality of cathode electrodes 16 with a predetermined pattern, such as a stripe pattern, are formed on the insulating layer 14 so as to vertically cross the gate electrodes 12. The pattern of the gate electrodes 12 and the cathode electrodes 16 is not limited to a stripe pattern.
Electron emitters 18a are formed on the cathode electrodes 16. The electron emitters 18a can be formed on cathode electrodes 16 in a stripe pattern identical to that of the cathode electrodes 16 as depicted in
The front substrate 20 includes a transparent anode electrode 22 and fluorescent layers 24 of red, green, and blue colors. The transparent anode electrode 22 is formed, for example, of indium tin oxide (ITO) to which a high voltage is applied in order to accelerate the electrons emitted from the electron emitters 18a or 18b. The fluorescent layers 24, which emit visible light by being excited by electrons emitted from the electron emitters 18a or 18b, can be formed in a predetermined pattern. A black matrix (not shown) for improving contrast of images can be disposed between the fluorescent layers 24.
Unlike the above description, the front panel can be formed with such a structure that the fluorescent layers of green, red, and blue color are formed with certain spaces on the front substrate 20, and an anode electrode formed of a metal thin film (such as aluminum foil) can be formed on the fluorescent layers. In this case, a black matrix for improving image contrast can be formed between the fluorescent layers. In this respect, the anode electrode formed of a metal thin film not only has a high voltage from the outside applied to it so as to accelerate the electrons, but also performs the function of securing an internal voltage of the display device and improving brightness. A transparent electrode formed of ITO can also be included on surfaces of the fluorescent layers in the above structure. The transparent electrode can cover the entire surface of the front substrate, or it can be formed in a stripe pattern. The metal thin film can be omitted, and in this case, the transparent electrode acts as the anode electrode and receives the necessary voltage for accelerating the electrons.
A predetermined gap between the rear substrate 10 and the front substrate 20 is maintained by a plurality of spacers 26.
According to the structure described above, the electron emission display device operates when a predetermined voltage is applied to the gate electrodes 12 and the cathode electrodes 16, and a high voltage required for accelerating the electrons is applied to the anode electrode 22. That is, a strong electric field is formed around the electron emitters 18a or 18b by the electric potential difference between the gate electrodes 12 and the cathode electrodes 16, and electrons are emitted from the electron emitters 18a or 18b by a quantum mechanical tunneling effect generated by the formed electric field. Then, images are displayed by light generated from the fluorescent layers 24 when electrons having high energy, induced by the voltage applied to the anode electrode 22, collide thereon.
As an operating characteristic of the electron emission display device, a space between the rear panel and the front panel must be maintained in a high vacuum state of more than 10-6 Torr. If the space is not maintained in a high vacuum state, ions are generated by collision between particles that exist in the space and the electrons emitted from the electron emitters 18a or 18b. When the ions are generated, the device can be degraded by the sputtering of the ions, and also the colliding energy of electrons (i.e., brightness of images) can be reduced since the electrons accelerated by the anode electrode 22 can lose energy by colliding with the particles existing in the space. Therefore, the space between the rear panel and the front panel is sealed with a high vacuum state using a sealing member 28, such as a sealing glass frit. At this time, dielectric layers 28a, having a dielectric constant less than that of the sealing member 28, are formed on and under the sealing member 28 to meet the conditions of Formula 5.
The rear panel of the electron emission display device having the above structure is formed using the following method.
As depicted in
Next, an insulating layer 14, composed of a silicon oxide group or a silicon nitride group, is formed by screen printing a glass paste a few times on the entire surface of the rear substrate 10 to cover the gate electrodes 12.
A plurality of cathode electrodes composed of a highly conductive metal, such as Ag, are formed in a stripe pattern perpendicular to the gate electrodes 12 on the insulating layer 14.
After forming the cathode electrodes 16, electron emitters 18a or 18b are formed on a side of the cathode electrodes 16, or on a central portion or an end of the cathode electrodes 16. The electron emitters 18a or 18b can be formed of a carbon group material having a low work function, such as carbon nanotube, graphite, diamond, DLC, or C60. After printing a thick film of a paste state carbon group material, the electron emitters 18a or 18b can be formed by patterning the thick film through processes of drying, exposing, and developing. When the electron emitters 18a or 18 are formed of carbon nanotubes, an erection process for disposing the carbon nanotube of electron emitters 18a or 18b in an upright or erect posture can be performed, if necessary.
After forming dielectric layers 28a, having an appropriate dielectric constant as described above, on an end of the rear panel and the front panel on which the anode electrode 22 and the fluorescent layers 24 are formed, the rear panel and the front panel are sealed using a sealing member 28. Sealing glass frit can be used as the sealing member 28, and in this case, a predetermined thickness of sealing glass frit in a paste state is coated on the dielectric layers 28a formed on an end of the rear panel using a dispensing method or a screen printing method. Moisture contained in the sealing glass frit 28 is removed through a drying process. Subsequently, the sealing of the rear panel and the front panel is completed by sintering the sealing glass frit 28 at a high temperature after aligning the rear panel and the front panel. After the completion of the sealing, the space between the rear panel and the front panel is exhausted to a high vacuum state through a predetermined exhaust hole (not shown).
In the embodiment described above, the dielectric layers can be formed between the sealing member and the rear panel, or between the sealing member and the front panel. Also, they can be formed in the sealing member, and more than two dielectric layers can be formed.
On the other hand, in the embodiment described above, the dielectric layers can be formed as a thin film or a thick film. The thin film can be formed by using a CVD method. The thick film can be formed by using a printing method, and in this case, manufacturing cost can be reduced since an inexpensive printing apparatus, not an expensive CVD apparatus, can be used. The thick film can be formed using a PbO—SiO2—B2O3 group material. This can also be applied to the subsequent embodiments of the present invention.
In this embodiment, the fluorescent layer 24, which is formed on the front panel, is not formed on an end of the front substrate 20, so that the dielectric layer 28a is formed on the anode electrode 22 of the front panel. The dielectric layer 28a, which is formed on the rear panel, is formed on an end of the cathode electrodes 16 or the insulating layer 14.
Since sealing glass frit is widely used as the sealing member of an electron emission display device, when the sealing member is formed using sealing glass frit having a dielectric constant of approximately 30 F/m, and the dielectric layers having a dielectric constant ∈1 of 10 F/m are formed on and under the sealing glass frit by substituting ∈2=30 F/m and k=2, ∈1=10 F/m in Formula 5, each of the thicknesses d1 of the dielectric layers on and under the sealing glass frit becomes approximately 0.25 d, and the thickness of the sealing glass frit becomes approximately 0.5 d. That is, when forming the dielectric layers on and under the sealing glass frit having a dielectric constant of ∈1=10 F/m, the overall capacitance is reduced to half, thereby reducing by half the amount of accumulated charges on and under the sealing glass frit. Therefore, a desired electron emission display device can be obtained.
The dielectric constant of the sealing glass frit, and that of the dielectric layer included in the sealing glass frit, will now be described.
As described above, in the present invention, it is desirable to lower the capacitance at a portion where the sealing member is located. Therefore, a sealing member and a dielectric layer having a low dielectric constant must be used to reduce the capacitance. However, in general, as the dielectric constant is reduced, the sintering temperature increases. Accordingly, if there is an upper limit of the sintering temperature, there must be a lower limit of the dielectric constant of the sealing member.
In general, the substrate of an electron emission display device is formed of glass, and the melting temperature of the glass substrate is approximately 600° C. Therefore, the sintering temperature of the glass substrate must be lower than 600° C. This denotes that there is a lower limit of the dielectric constant. Because of this limitation, in the case of the sealing glass frit, the lower limit of the dielectric constant is approximately 20 F/M, and in the case of the dielectric layer, the lower limit of the dielectric constant is approximately 10 F/m. Accordingly, it is preferable to use sealing glass frit having a dielectric constant greater than 20 F/m, and to use a dielectric layer having a dielectric constant greater than 10 F/m.
As described above, in the present invention, it is desirable to lower the capacitance at a portion where the sealing member is located, and this also denotes that there is an upper limit of the capacitance because a waveform distortion phenomenon of an output voltage and arcing occur due to the accumulation of charges on and under the sealing member as the capacitance increases.
When a sealing member is formed using sealing glass frit having a dielectric constant of 20 F/m, and dielectric layers having dielectric constants of 10 F/m are formed on and upper the sealing glass frit, the measured total capacitance is approximately equal to 2.17 F, and no waveform distortion occurs. Also, when the sealing member is formed using sealing glass frit having an increased dielectric constant of 40 F/m, and dielectric layers having dielectric constants of 20 F/m are formed on and upper the sealing glass frit, the measured total capacitance is approximately equal to 4.35 F, and waveform distortion of the output voltage occurs, but it is not large enough to affect the image. However, when the sealing glass frit and dielectric layers having greater dielectric constants than the above dielectric constants are formed, the total capacitance is increased and the waveform distortion is large enough to affect an image. Accordingly, it is desirable that the dielectric constant of the sealing glass frit be less than 40 F/m, and that the dielectric constant of the dielectric layers be less than 20 F/m.
Referring to
In
Referring to
More specifically, the rear panel includes: a plurality of cathode electrodes 36 formed in a predetermined pattern, such as a stripe pattern, on the rear substrate 30; an insulating layer 34 that covers the cathode electrodes 36 formed on the entire surface of the rear substrate 30; and a plurality of gate electrodes 32 formed in a predetermined pattern, such as a stripe pattern, SO as to vertically cross the cathode electrodes 36 on the insulating layer 34. Of course, the gate electrodes 32 and the cathode electrodes 36 can be formed in patterns other than described above. Gate holes 32a are formed in the gate electrodes 32 and the insulating layer 34 on a portion where the gate electrodes 32 and the cathode electrodes 36 are crossing, and electron emitters 38 are formed on the cathode electrodes 36 in the gate holes 32a. A resistance layer (not shown) can be formed between the cathode electrodes 36 and the electron emitters 38. The electron emitters 38 can be of a cone type, such as a spindt type, or can be formed using carbon nanotube.
A method of manufacturing the rear panel of the top gate type electron emission display device will now be described.
Referring again to
When using electron emitters 38 using carbon nanotube which is not a spindt type electron emitter, the rear panel can be formed such that the cathode electrodes 36 can be formed of a transparent conductive material, such as ITO, IZO, or In2O3. After forming the insulating layer 34 that covers the cathode electrodes 36 and the entire surface of the rear substrate 30 formed of an opaque material or polyimide, the gate electrodes 32 are formed on the insulating layer 34. The gate holes 32a that pass through the gate electrodes 32 and the insulating layer 34 are formed, and a thick film of a paste state of carbon nanotube is printed on an entire surface of the gate electrodes 32. After sintering the paste in the gate holes 32a through back exposure using the opaque insulating layer 34, the electron emitters 38 can be formed by removing the remaining paste.
In the fifth embodiment, after forming dielectric layers 48a having a predetermined dielectric constant on ends of the rear and front panels, the panels are sealed using a sealing member 48. The sealing member 48 can be sealing glass frit. The dielectric layers 48a can also be included in the sealing member 48, and more than two dielectric layers can be formed.
In this embodiment, fluorescent layers 44 are formed on the front panel so as not to be on an edge thereof such that the dielectric layer 48a is formed on the anodes 42 of the front panel. At this point, the dielectric layers 48a formed on the rear panel can be formed on edges of the gate electrodes 32 or the insulating layer 34 of the rear panel.
The electron emission display device manufactured according to the present invention provides the following advantages.
First, a greater high voltage can be applied to an anode electrode since capacitance of a capacitor, which is comprised of an anode electrode, a sealing member and a cathode electrode, or of an anode electrode, a sealing member and a gate electrode, can be greatly reduced. When a higher voltage is applied to the anode electrode, electrons emitted from electron emitters with high energy can collide with fluorescent layers formed on a front panel. As a result, the brightness of images displayed by the fluorescent layer is improved.
Second, the amount of charge accumulated on the electrodes is greatly reduced since capacitance of a capacitor, which is comprised of an anode electrode, a sealing member and a cathode electrode, or of an anode electrode, a sealing member and a gate electrode, can be greatly reduced. Accordingly, waveform distortion of the output voltage can be reduced since a time required to accumulate and discharge the charges can be reduced, thereby improving the reproducibility of an image and a color.
Third, since the amount of charge accumulated on the electrodes is greatly reduced, the possibility of arcing due to an applied high voltage is reduced, thereby increasing the lifetime of the electron emission display device.
While the present invention has been particularly shown and described with reference to embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention as defined by the following claims.
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