KR101285475B1 - p-n junction ZnO LED and manufacturing method for the same - Google Patents

Abstract

The present invention relates to a ZnO LED made of p-type ZnO and n-type ZnO forming a pn junction, and a method of manufacturing the same, and a nano-ink containing p-type ZnO and n-type ZnO nanopowders using Printed Electronics technology. Are printed vertically and horizontally to form pn junctions at lattice points, or a seed layer of n-type ZnO is formed on a substrate, and n-type ZnO nanorods are grown by hydrothermal method, and then p is added thereto. A pn junction ZnO LED is formed by depositing a type ZnO to form a vertical pn junction.

Description

P-n junction ZnO LED and its manufacturing method {p-n junction ZnO LED and manufacturing method for the same}

The present invention relates to a ZnO LED made of p-type ZnO and n-type ZnO forming a pn junction, and a method of manufacturing the same, and a nano-ink containing p-type ZnO and n-type ZnO nanopowders using Printed Electronics technology. Are printed vertically and horizontally to form pn junctions at lattice points, or a seed layer of n-type ZnO is formed on a substrate, and n-type ZnO nanorods are grown by hydrothermal method, and then p is added thereto. A pn junction ZnO LED is formed by depositing a type ZnO to form a vertical pn junction.

The depletion of fossil energy resources and the issue of environmental protection have emerged as the most important issues for mankind living in modern society. Accordingly, eco-friendly and energy-saving technologies are spotlighted as new growth engines for the future.

Electric energy is the most important energy in modern people's life. Especially, electric energy used as lighting is close to 20% of the total energy consumption. Therefore, energy saving in the lighting field is very important, and accordingly, the use of LEDs (Light Emitting Diodes) is rapidly increasing in recent years.

LEDs are not only more energy efficient than conventional luminaires, they are also more durable, reliable, and compact in size. In addition, since light spreads easily, it is easy to make a directional beam without a reflector, and thus it is used in many fields such as LCD-equipped electronic products, automobile lighting, and street lamps.

Due to the many advantages of LEDs, research on LEDs continues, and various materials are being developed one after another to develop not only high-visible visible light but also high-energy blue light or ultraviolet light.

Among these, LEDs that are most interested in recent years are related to next-generation LEDs made of ZnO. ZnO is a group II-VI compound semiconductor with a wurtzite crystal structure and has a wide bandgap of 3.37 eV and high exciton binding energy of 60 meV at room temperature. (ultraviolet) wavelength emission is possible.

Due to these characteristics, ZnO has been researched in the fields of semiconductor resistance device, LED, laser diode (LD), field emission display (FED), thin film transistor (TFT), sensor, etc. It is considered to be a material that can be contributed.

Accordingly, an object of the present invention is to provide a ZnO LED capable of emitting light by forming a p-n junction between p-type ZnO and n-type ZnO, and a method of manufacturing the same.

In particular, an object of the present invention is to provide a p-n junction ZnO LED and a method of manufacturing the same, which form a p-n junction using Printed Electronics technology or hydrothermal method.

The p-n junction ZnO LED according to the present invention comprises a substrate; a lower electrode formed on the substrate; n-type ZnO formed on the lower electrode; and p-type ZnO formed to form a p-n junction on the n-type ZnO; And an upper electrode formed on the p-type ZnO.

In one embodiment of the present invention, the lower electrode is formed so that the vertical and horizontal spacing is a constant lattice arrangement, the n-type ZnO and p-type ZnO as a nano strip to form an intersection point forming a pn junction on the lower electrode. The upper electrode is formed on the pn junction of the p-type ZnO and n-type ZnO nanostrips. That is, if the nano strip of n-type ZnO is formed repeatedly in the longitudinal direction to pass over the lower electrode, and the nano-type of p-type ZnO is also repeatedly formed in the transverse direction to pass over the lower electrode, n-type ZnO and p-type ZnO are formed. A contact surface of n-type ZnO and p-type ZnO is formed on the lower electrode, which is an intersection point of the nanostrip, and then a thermal diffusion process is completed to complete the pn junction.

The nano strips of n-type ZnO and p-type ZnO may be printed and formed on the substrate by an inkjet printing apparatus using a nano ink in which nanoparticles of n-type ZnO and p-type ZnO are dispersed.

At this time, the p-n junction is formed by thermal diffusion.

The lower electrode may be formed of Au / Ti (Au film, Ti film sequentially stacked, or the same below) alloy or graphene material.

In addition, the upper electrode may be formed of Au / Ni (Au film, Ni film sequentially stacked, the same) alloy or graphene material.

The upper electrode and / or the lower electrode may be printed by an inkjet printing apparatus using a nano ink in which nano powders of electrode materials are dispersed.

In another embodiment of the present invention, after forming a seed layer (n-type ZnO) of the seed layer (seed layer) on the lower electrode by growing a plurality of nano-rods of the n-type ZnO in the vertical direction by hydrothermal synthesis, the n-type ZnO The p-type ZnO is deposited on the nanorods to form a vertical pn junction.

An insulating material is filled by spin coating between the nanorods of the plurality of p-n junctions ZnO.

The seed layer is formed on the lower electrode by sol-gel spin coating.

The lower electrode may be formed of Au / Ti alloy or graphene material.

The upper electrode may be formed of Au / Ni alloy or graphene material.

The present invention is advantageous in that it is a wallpaper-type LED lighting device that can be mass-produced at a low cost and large area by using printed electronic technology, as well as detachable to a wall like a wallpaper.

In addition, the present invention has a merit that a plurality of LED elements are patterned on a plane and irradiated with a desired intensity of illumination in a desired direction, so that illumination of multiple directions can be irradiated with one illumination device.

1 illustrates an embodiment of a pn junction ZnO LED in accordance with the present invention.
Figure 2 shows another embodiment of a pn junction ZnO LED according to the present invention.
3 is a view for explaining a manufacturing process of the pn junction ZnO LED of FIG.

Hereinafter, preferred embodiments of the p-n junction ZnO LED 1 according to the present invention will be described in detail with reference to the accompanying drawings.

In describing the embodiments of the present invention, a description of well-known structures that can be understood by those skilled in the art will be omitted so as not to obscure the gist of the present invention. In addition, when referring to the drawings, it should be considered that the thickness of the lines or the size of the components shown in the drawings may be exaggerated for the sake of clarity and convenience of the description. Terms such as above and inside and outside (한다 外) is based on the state described in the accompanying drawings unless otherwise specified.

The pn junction ZnO LED 1 according to the present invention has a substrate 100, a lower electrode 200 formed on the substrate 100, an n-type ZnO 300 formed on the lower electrode 200, and an n-type ZnO 300. It includes a p-type ZnO (400) formed to form a pn junction 420 and the upper electrode 600 formed on the p-type ZnO (400).

ZnO-based LED devices have many advantages. The band gap is 3.37 eV and the exciton binding energy reaches 60 meV. It is possible to implement

In addition, it is easy to grow to nano size, and even if it does not match the lattice arrangement of the substrate, there is no influence on the growth, so the choice of substrate material is free. Therefore, it is possible to grow ZnO on a flexible plastic substrate as well as quartz or glass. In particular, using a flexible plastic substrate it is possible to make a curved light emitting surface.

In addition, zinc is a much richer material than other semiconductor materials, so it has a price advantage and can be used for a very long time in the future.

1 illustrates a p-n junction ZnO LED 1 according to one embodiment of the invention.

Referring to FIG. 1, the lower electrode 200 is formed to be discrete so that the vertical and horizontal intervals form a constant lattice array, and the n-type ZnO 300 and the p-type ZnO 400 are formed in the form of nano strips with the lower electrode ( 200) formed vertically and horizontally to form an intersection point forming the pn junction 420. That is, the nano strip of n-type ZnO 300 is repeatedly formed in the longitudinal direction to pass over the lower electrode 200, and the nano strip of p-type ZnO 400 also crosses the lower electrode 200 in the transverse direction. When formed repeatedly, a contact surface of n-type ZnO (300) and p-type ZnO (400) is formed on the lower electrode 200, which is the intersection of the n-type ZnO (300) and the p-type ZnO (400) nanostrip, and then thermal diffusion Through the process, the pn junction 420 is completed.

Of course, even if the vertical order of the n-type ZnO (300) and p-type ZnO (400) nanostrip is reversed, it should be noted that the electrode material suitable for each of the n-type ZnO (300) and p-type ZnO (400) must also be changed. do.

Thereafter, when the upper electrode 600 is formed on the p-n junction 420 of the p-type ZnO 400 and the n-type ZnO 300 nanostrips, a plurality of p-n junction ZnO LEDs 1 are collectively formed.

In this embodiment, each p-n junction ZnO LED 1 includes independent upper and lower electrodes 600 and 200, and can control driving of each p-n junction ZnO LED 1. If the individual driving control of the pn junction ZnO LED 1 is not necessary, the upper and lower electrodes 600 and 200 are also formed in the form of a nano strip to drive a series of pn junction ZnO LEDs 1 which form a row and a column, respectively. Alternatively, it is also possible to collectively drive all the pn junction ZnO LEDs 1 by forming the upper and lower electrodes 600 and 200 in a wide layer to cover all the pn junction ZnO LEDs 1.

When p-n junction ZnO nanostrips are intersected vertically and horizontally to produce multiple p-n-junction ZnO LEDs, large-area surface light emission is possible and the manufacturing process is simplified, resulting in significant cost advantages.

In particular, if the nano-strip of the n-type ZnO (300) and p-type ZnO (400) is formed by a printing method using a printed electronic technology it can further simplify the manufacturing process.

Printed electronics technology refers to a technology for producing various electronic components on a substrate using printing technology. Until now, electronic devices have been generally fabricated by using lithography, etching, and deposition techniques on silicon or sapphire substrates.However, the process is complicated and the process takes a long time, and a large amount of patterning process is required. Because of the use of chemicals, there is a problem that serious adverse effects on the health of workers as well as environmental problems.

On the other hand, the printed electronics technology directly prints the pattern of the electronic device on a substrate, particularly a flexible substrate, so that the process is simple, the manufacturing cost is low, and mass production and large area are easy. Currently, printed electronic technology is most actively used in advertising billboards, billboards, disposable displays, RFID, smart cards, and the like.

Printing technology utilized in printed electronics is using a variety of technologies that have been printed on paper until now. Representative examples include screen printing, gravure printing, gravure offset printing, flexo printing, inkjet printing, and the like. Among them, inkjet printing is regarded as the most promising printing technology that will lead printing electronic technology in the future, and Korean Patent No. 0543176 can be referred to as a patent on inkjet capable of nano patterning.

Inkjet printing used in printed electronics technology uses nano-inks with nano-powder dispersed, and nano-powders include physical methods such as gas evaporation and sputtering, co-precipitation, sol-gel method (liquid, liquid phase method) or chemical vapor deposition method (weather method). It is synthesized by a chemical method such as). Also, in order to jet the nozzle at a high shear rate and to jet the high concentration of ink at high shear speed, it is necessary to increase the fluidity of the ink, so that a polymer additive may be added to reduce the interaction of nanoparticles in the ink.

Therefore, one embodiment of the present invention is an n-type ZnO (300) and p-type ZnO (300) and p-type ZnO (400) using an inkjet print apparatus using a nano ink dispersed in the n-type ZnO (300) and p on the substrate 100 The nano-strips of the type ZnO 400 may be made using printed electronic technology, respectively.

Here, the p-type ZnO 400 is made by doping phosphorus (P) or copper (Cu) on ZnO, and the n-type ZnO 300 is made by doping aluminum phosphorus (Al) or gallium (Ga) on ZnO.

And like any other LED, ZnO LED (1) also the electrode selection affects the efficiency of the LED, the lower electrode 200 is connected to the n-type ZnO (300) is translucent Au / Ti (Au film, Ti A film sequentially stacked, the same) alloy is suitable, and the upper electrode 600 connected to the p-type ZnO (400) is preferably Au / Ni (Au film, Ni film sequentially stacked, the same below) alloy. In addition, it has been confirmed that the graphene material, which is recently spotlighted as a flexible transparent electrode, can be suitably applied to both the upper and lower electrodes 600 and 200.

The upper electrode 600 and / or the lower electrode 200 as described above may also be printed and formed by an inkjet printing apparatus using nano ink in which nano powders of an electrode material (metal alloy or graphene) are dispersed.

Yet another embodiment of the present invention is directed to a vertical p-n junction ZnO LED 1 whose structure is shown in FIG. 2.

The basic structure is the same in that the p-type ZnO 400 and the n-type ZnO 300 form a pn junction 420, but the seed layer of n-type ZnO is seeded on the lower electrode 200 formed on the substrate 100. After the layer 310 is formed, a plurality of n-type ZnO nanorods 320 are grown in the vertical direction by hydrothermal synthesis, and p-type ZnO nanorods 410 are deposited on the n-type ZnO nanorods 320 to grow vertically. The difference is that the pn junction 420 is formed in the direction.

Methods for growing ZnO nanostructures include chemical vapor deposition, thermal evaporating, hydrothermal methods, molecular beam epitaxy, sputtering, pulsed laser deposition ( There are various methods such as pulsed laser deposition, atomic layer deposition, etc. Among them, hydrothermal synthesis is simple in manufacturing process and can grow ZnO nanostructures at low temperature, enabling mass production, and controlling doping and chemical composition. Has the advantage of being easy.

In hydrothermal synthesis, a seed layer on which ZnO nanorods can be grown is grown on a substrate 100, and then a precursor of zinc nitrate hexahydrate (Zn (NO ₃ ) ₂ .6H ₂ O]) or zinc acetate ( ZnO nanorods are grown on the seed layer by placing the substrate 100 in a solution containing zinc acetate dehydrate, [Zn (CH ₃ COO) ₂ .2H ₂ O]), and storing them at a relatively low temperature of about 90 to 200. Way.

The present invention uses the hydrothermal synthesis method to grow the ZnO nanorods (320, 410) is shown in Figure 3 the flow of the overall process.

First, an n-type ZnO seed layer 310 is formed by sol-gel spin coating on the lower electrode 200 formed on the substrate 100 (steps (a) to (c)). As described above, the lower electrode 200 may be formed of an Au / Ti alloy or a graphene material, and may be deposited by sputtering, or may be printed on the substrate 100 using printed electronic technology.

Thereafter, a plurality of n-type ZnO nanorods 320 are grown in a vertical direction by hydrothermal synthesis [(d) step].

At this time, since the electrical short is likely to occur between the n-type ZnO nanorods 320 grown to a certain length or more, the insulating material 500 is filled in the space between the n-type ZnO nanorods 320 by spin coating. [Step (e)].

When the insulating material 500 is filled between the n-type ZnO nanorods 320 through the step (e), the p-type ZnO nanorods 410 are deposited and grown on the n-type ZnO nanorods 320 to form a vertical pn. Complete the junction 420 (step (f)).

When the pn junction 420 of the ZnO nanorods 320 and 410 is completed, the insulating material 500 is filled in the remaining empty space between the ZnO nanorods 320 and 410 by spin coating as in step (e). Step (g), when the upper electrode 600 is formed thereon, a plurality of pn junction ZnO LEDs 1 are collectively completed on one substrate 100 (step h). The upper electrode 600 may also be formed of Au / Ni alloy or graphene material as in the above-described embodiment, and the formation method is also the same as in the case of the lower electrode 200.

Although the present invention has been described with reference to the embodiments shown in the drawings, it is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims.

Description of the Related Art
1: pn junction ZnO LED 100: substrate
200: lower electrode 300: n-type ZnO
310: n-type ZnO seed layer 320: n-type ZnO nanorods
400: p-type ZnO 410: p-type ZnO nanorod
420: pn junction 500: insulating material
600: upper electrode

Claims (12)

A pn junction ZnO LED comprising a substrate, a lower electrode formed on the substrate, an n-type ZnO formed on the lower electrode, a p-type ZnO formed to form a pn junction on the n-type ZnO, and an upper electrode formed on the p-type ZnO.
The lower electrodes are formed to be discrete so that vertical and horizontal intervals form a constant lattice arrangement;
The n-type ZnO and the p-type ZnO are formed as a nanostrip in a longitudinal direction so as to form an intersection point forming a pn junction on the lower electrode;
The upper electrode is formed on a pn junction of the p-type ZnO and n-type ZnO nanostrips;
The nano strips of n-type ZnO and p-type ZnO are printed and formed on the substrate by an inkjet printing apparatus using a nano ink in which nanoparticles of n-type ZnO and p-type ZnO are dispersed, respectively. ZnO LED. delete delete The method of claim 1,
The pn junction is formed by thermal diffusion, pn junction ZnO LED. The method of claim 1,
The lower electrode is formed of an Au / Ti (Au film, Ti film sequentially stacked, hereinafter identical) substrate, a lower electrode formed on the substrate, an n-type ZnO formed on the lower electrode, and a p-type ZnO formed on the n-type ZnO. And a pn junction ZnO LED including an upper electrode formed on the p-type ZnO,
The lower electrodes are formed to be discrete so that vertical and horizontal intervals form a constant lattice arrangement;
The n-type ZnO and the p-type ZnO are formed as a nanostrip in a longitudinal direction so as to form an intersection point forming a pn junction on the lower electrode;
The upper electrode is formed on a pn junction of the p-type ZnO and n-type ZnO nanostrips;
The nano strips of n-type ZnO and p-type ZnO are printed and formed on the substrate by an inkjet printing apparatus using a nano ink in which nanoparticles of n-type ZnO and p-type ZnO are dispersed, respectively. ZnO LED. The method of claim 1,
The upper electrode is a pn junction ZnO LED, characterized in that formed of Au / Ni (Au film, Ni film sequentially stacked, the same) alloy or graphene material. The method according to claim 5 or 6,
The upper electrode and the lower electrode is pn junction ZnO LED, characterized in that printed by an inkjet printing apparatus using a nano ink in which the nano-powder of the electrode material is dispersed. delete delete delete delete delete

Images