Patent Application
20120161175
The present invention relates generally to a method of manufacturing a vertical structure light emitting diode (LED). More specifically, the present invention relates to a method of manufacturing a vertical structure light emitting diode (LED) having several stop layers created before formation of a n-GaN layer to restrain threading dislocation caused during epitaxy of a u-GaN layer on a sapphire substrate so that the yield rate thereof can be improved while laser lift-off (LLO) process is introduced and throughput of the LED can be raised.
Heat dissipation management is the main issue on the development for packaged high power LEDs under high current driving. For a lateral current conducting structure epitaxially formed on a sapphire substrate, there are drawbacks on the current crowding effect, high series resistance and poor heat dissipation.
The disadvantage of poor heat sink of sapphire can be resolved by other heat dissipation substrate by laser lift-off (LLO) process using a short wavelength excimer source. For example, U.S. Pat. No. 7,384,807 to Yoo disclosed a method of fabricating a vertical structure opto-electronic device which includes fabricating a plurality of vertical structure opto-electronic devices on a crystal substrate, and then removing the substrate using a laser lift-off process. However the electrical and optical properties of LEDs are dependent on crystal quality of the epitaxial layers which are subject to additional chemical process (e.g. etching), mechanical process (e.g. lapping), and laser lift-off process. It may be needed for laser beam to scan an epitaxial wafer more than one time, which decreases the throughput and increases the chance of damaging the epitaxial layers of LEDs. Also, the laser lift-off equipment is expensive.
In order to achieve a high yield of LLO process, it is necessary to separate the island of epi-GaN by chemical or physical etching process to form a heat exhaustion structure (so called “street path”). The street path has a benefit of nitrogen gas release during LLO process to achieve high yield.
However, due to an increased dimension of the epi-GaN island, it is necessary to enlarge width of the street path to avoid adjacent islands from attack by the pressure of nitrogen released from photo-induced decomposition.
Sapphire (Al2O3) is the most popular substrate for epitaxial growth of AlInGaN-based materials in light emitting diodes (LEDs) manufacturing. However, the thermal conductivity of the sapphire substrate is not so good that the blue light emitting diode is limited to a lateral conducting structure with its positive and negative metal electrodes on the same side of the substrate. Thus, the structure substantially shrinks the lighting area. Besides, due to current crowding effect and lateral path, there are inevitable increases in series resistance (Rs) and forward voltage drop (Vf) of the LED device. The huge amount of heat generated decays external quantum efficiency directly.
Substituting a traditional sapphire substrate for a heat dissipation substrate by using excimer laser lift-off (LLO) technology has been used for many years. Although it is commercialized, the manufacturing cost of such LED device is still quite expensive due to its complex processes and low yield. According to the high bandgap energy of sapphire, a short wavelength (<355 nm) excimer laser beam can penetrate the polished sapphire substrate and be absorbed in the interface between sapphire and the epitaxial buffer layer (u-GaN). The absorbed energy is accumulated on the surface of u-GaN and converted to heat energy which allows u-GaN to be gasified and nitrogen gas to be released. Subsequently, the released nitrogen gas may cause damage to neighboring insolated epitaxial elements and the heat dissipation substrate due to the pressure thus formed. Therefore, the peeling of the fragile interface formed by bonding or electroplating technology may produce the issue on reliability, for example, fast degradation of light output power, increase of forward voltage drop after package.
In order to solve the problem mentioned above and increase yield rate of the excimer laser lift-off process, the inventor has provided a vertical structure light emitting diode (LED) having a duct and a number of gaps for heat exhaustion, as described in U.S. application Ser. No. 12/634,747 filed on Dec. 10, 2009. A buffer layer is provided to form a number of air gaps between the sapphire substrate and the buffer layer. The structure can dissipate heat caused by current crowding effect via the air gaps. Furthermore, a duct between any two LED semi-products helps heat dissipation as well. The key in the previous invention is to make the buffer layer recessed to accommodate protrusions on the sapphire substrate. It takes more cost to design and get a better combination for the buffer layer and the sapphire substrate. New epitaxial layers are formed on the sapphire substrate for increasing yield rate of the excimer laser lift-off process. No special designs are required and threading dislocation is utilized which is considered as a defect for LEDs.
This paragraph extracts and compiles some features of the present invention; other features will be disclosed in the follow-up paragraphs. It is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims.
In accordance with an aspect of the present invention, a manufacturing method of a vertical structure light emitting diode (LED), includes: a) forming a chemical resistant layer, a medium layer and a spreading layer on a substrate in sequence; b) growing a plurality of luminescent layers on the spreading layer; c) removing the substrate and the chemical resistant layer; d) upturning the remaining layers enabling the medium layer as a top layer; e) roughening a surface of the medium layer; and f) setting a metal layer under the luminescent layers as an electrode.
In accordance with another aspect of the present invention, a vertical structure light emitting diode (LED) includes a metal layer as an electrode; a plurality of luminescent layers formed on the metal layer for providing light beams; a spreading layer formed on the luminescent layers; a medium layer provided on the spreading layer, having an opening formed therethrough to expose the spreading layer and a roughed surface.
In order to increase yield rate of laser lift-off (LLO), an improved vertical structure light emitting diode is desired. An embodiment of the present invention showing a method of manufacturing a vertical structure light emitting diode is described below.
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The chemical resistant layer 102 can block any chemical etching process used in producing luminescent layers. Therefore, the medium layer 103 can be preserved. It should be noticed that the sacrificial layer 101 or the chemical resistant layer 102 or the medium layer 103 or the spreading layer 104 is n type gallium nitride (n-GaN) in the present invention.
After, a number of luminescent layers 105 are formed on the medium layer 104 as shown in
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Next, in order to enhance light extraction of the vertical structure LED, a surface of the medium layer 103 is roughened, as shown in
Furthermore, an electrode 106 can be deposited in the opening 111 on the spreading layer 104, as shown in
It should be noticed that the chemical resistant layer 102 can reduce threading dislocations of the substrate 100 extended into the luminescent layers 105. The spreading layer 104 facilitates diffusion of current produced by the electrode 106. Besides, the sacrificial layer 101 and the medium layer 103 have higher threading dislocation densities. The chemical resistant layer 102 and the spreading layer 104 have lower threading dislocation densities. In other words, threading dislocation densities of the sacrificial layer 101 or the medium layer 103 is higher than that of the chemical resistant layer 102 or the spreading layer 104.
Finally, an agglutinate layer 107 is added below the luminescent layers 105 for adhering a metal layer 108 under the luminescent layers 105, as shown in
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While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiment, it is understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims, which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
