| SYNOS TECHNOLOGY, INC. Patent applications |
| Patent application number | Title | Published |
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| 20120125258 | Extended Reactor Assembly with Multiple Sections for Performing Atomic Layer Deposition on Large Substrate - An elongated reactor assembly in a deposition device for performing atomic layer deposition (ALD) on a large substrate. The elongated reactor assembly includes one or more injectors and/or radical reactors. Each injector or radical reactor injects a gas or radicals onto the substrate as the substrate passes the injector or radical reactor as part of the ALD process. Each injector or radical reactor includes a plurality of sections where at least two sections have different cross sectional configurations. By providing different sections in the injector or radical reactor, the injector or radical reactor may inject the gas or the radicals more uniformly over the substrate. Each injector or radical reactor may include more than one outlet for discharging excess gas or radicals outside the deposition device. | 05-24-2012 |
| 20120114877 | Radical Reactor with Multiple Plasma Chambers - Two or more plasma chambers are provided in a radical reactor to generate radicals of gases under different conditions for use in atomic layer deposition (ALD) process. The radical reactor has a body with multiple channels and corresponding process chambers. Each plasma chamber is surrounded by an outer electrode and has an inner electrode extending through the chamber. When voltage is applied across the outer electrode and the inner electrode with gas present in the plasma chamber, radicals of the gas is generated in the plasma chamber. The radicals generated in the plasma chamber are then injected into a mixing chamber for mixing with radicals of another gas from another plasma chamber, and injected onto the substrate. By providing two or more plasma chambers, different radicals of gases can be generated within the same radical reactor, which obviates the need for separate radical generators. | 05-10-2012 |
| 20120098146 | FORMATION OF BARRIER LAYER ON DEVICE USING ATOMIC LAYER DEPOSITION - The configuration of one or more barrier layers for encapsulating a device is controlled by setting parameters of atomic layer deposition (ALD). A substrate formed with the device is placed on a susceptor and exposed to multiple cycles of source precursor gas and reactant precursor gas injected by reactors of a deposition device. By adjusting one or more of (i) the relative speed between the susceptor and the reactors, (ii) configuration of the reactors, and (iii) flow rates of the gases injected by the reactors, the configuration of the layers deposited on the device can be controlled. By controlling the configuration of the deposited layers, defects in the deposited layers can be prevented or reduced. | 04-26-2012 |
| 20120094149 | DEPOSITION OF LAYER USING DEPOSITING APPARATUS WITH RECIPROCATING SUSCEPTOR - Atomic layer deposition is performed by reciprocating a susceptor in two directions, subjecting a substrate on the susceptor to two different sequences of processes. By subjecting the susceptor to different sequences of processes, the substrate undergoes different processes that otherwise would have required an additional set of injectors or reactors. The reduced number of injectors or reactors enables a more compact deposition device, and reduces the cost associated with the deposition device. | 04-19-2012 |
| 20120027953 | Rotating Reactor Assembly for Depositing Film on Substrate - A rotating reactor assembly includes an injector rotor comprising a channel extending in a direction parallel to a rotational axis of the injector rotor and at least one injection hole connected to the channel; and an intake port through which a material is introduced. As the injector rotor rotates, the channel is timely and/or periodically connected to the intake port such that the material is injected to a substrate through the at least one injection hole. | 02-02-2012 |
| 20120021252 | Treating Surface of Substrate Using Inert Gas Plasma in Atomic Layer Deposition - Depositing one or more layers of material on a substrate using atomic layer deposition (ALD) followed by surface treating the substrate with radicals of inert gas before subjecting the substrate to further deposition of layers. The radicals of the inert gas appear to change the surface state of the deposited layer to a state more amenable to absorb subsequent source precursor molecules. The radicals of the inert gas disconnect bonding of molecules on the surface of the substrate, and render the molecules on the surface to have dangling bonds. The dangling bonds facilitate absorption of subsequently injected source precursor molecules into the surface. Exposure to the radicals of the inert gas thereby increases the deposition rate and improves the properties of the deposited layer. | 01-26-2012 |
| 20110290551 | Protective structure enclosing device on flexible substrate - A structure for protecting a device includes a first layer, one or more first microstructures on the first layer, and a second layer disposed on the first layer. The second layer is disposed on a surface of the first layer on which one or more microstructures are provided. The microstructure may have a hemispheric shape or other random shapes having a curved surface. Since the area of the interface surface between layers is increased due to the at least one microstructure, the stress per unit area of the interface surface is reduced. Further, the microstructure increases the length of the path that ambient species need to travel in order to reach a device or other active components, thereby reducing the amount of infiltrating ambient species. | 12-01-2011 |
| 20110262650 | VAPORIZING OR ATOMIZING OF ELECTRICALLY CHARGED DROPLETS - A vaporizing apparatus includes a chamber, a nozzle for dispersing a liquid into droplets, an electrode electrically isolated from the nozzle, and a heater for generating a vapor by applying heat to the droplets. The voltage source applies charges to the droplets by applying a voltage between the nozzle and the electrode. The vaporizing apparatus may be used to devices that deposit organic or inorganic thin films by chemical vapor deposition and/or atomic layer deposition processes, devices for supplying precursor materials that are deposited to form a thin film in organic light emitting diodes, devices that supply organic or inorganic precursor materials for encapsulation, and devices for supplying organic or inorganic polymer. | 10-27-2011 |
| 20110076421 | VAPOR DEPOSITION REACTOR FOR FORMING THIN FILM ON CURVED SURFACE - A vapor deposition reactor and a method for forming a thin film. The vapor deposition reactor includes first to third portions arranged along an arc of a circle. The first portion includes at least one first injection portion for injecting a material to a recess in the first portion. The second portion is adjacent to the first portion and has a recess communicatively connected to the recess of the first portion. The third portion is adjacent to the second portion and has a recess communicatively connected to the recess of the second portion and an exhaust portion for discharging the material from the vapor deposition reactor. | 03-31-2011 |
| 20100310771 | VAPOR DEPOSITION REACTOR AND METHOD FOR FORMING THIN FILM - A vapor deposition reactor and a method for forming a thin film. The vapor deposition reactor includes at least one first injection portion for injecting a reacting material to a recess in a first portion of the vapor deposition reactor. A second portion is connected to the first space and has a recess connected to the recess of the first portion. The recess of the second portion is maintained to have pressure lower than the pressure in the first space. A third portion is connected to the second space, and an exhaust portion is connected to the third space. | 12-09-2010 |
| 20100215871 | METHOD FOR FORMING THIN FILM USING RADICALS GENERATED BY PLASMA - A method for forming a thin film using radicals generated by plasma may include generating radicals of a reactant precursor using plasma; forming a first thin film on a substrate by exposing the substrate to a mixture of the radicals of the reactant precursor and a source precursor; exposing the substrate to the source precursor; and forming a second thin film on the substrate by exposing the substrate to the mixture of the radicals of the reactant precursor and the source precursor. Since the substrate is exposed to the source precursor between the formation of the first thin film and the formation of the second thin film, the rate of deposition may be improved. | 08-26-2010 |
| 20100181566 | Electrode Structure, Device Comprising the Same and Method for Forming Electrode Structure - An electrode structure comprises a semiconductor junction comprising an n-type semiconductor layer and a p-type semiconductor layer; a hole exnihilation layer on the p-type semiconductor layer; and a transparent electrode layer on the hole exnihilation layer. The electrode structure further comprises a conductive layer between the hole exnihilation layer and the transparent electrode layer. In the electrode structure, one or more of the hole exnihilation layer, the conductive layer and the transparent electrode layer may be formed by an atomic layer deposition. In the electrode structure, a transparent electrode formed of a degenerated n-type oxide semiconductor does not come in direct contact with a p-type semiconductor, and thus, annihilation or recombination of holes generated in the p-type semiconductor can be reduced, which increases the carrier generation efficiency. Further, the electric conductivity of the transparent electrode is increased by the conductive layer, which improves electrical characteristics of a device. | 07-22-2010 |
| 20100068413 | VAPOR DEPOSITION REACTOR USING PLASMA AND METHOD FOR FORMING THIN FILM USING THE SAME - A vapor deposition reactor may include a first electrode including a first channel and at least one first injection hole connected to the first channel. a second electrode electrically separated from the first electrode, and a power source for applying power between the first electrode and the second electrode to generate plasma from a reactant gas between the first electrode and the second electrode. Also provided is a method for forming thin film using the vapor deposition reactor. | 03-18-2010 |
| 20100064971 | Electrode for Generating Plasma and Plasma Generator - A plasma generator may include a first electrode extending in one direction, and a second electrode spaced apart from the first electrode. Facing surfaces of the first electrode and the second electrode may have spiral shapes along the one direction. A cross-section of the first electrode and a cross-section of the second electrode, which are perpendicular to the one direction, may have at least partially concentric shapes. An electrode for generating plasma may include a platform extending in one direction, and at least one protruding thread spirally formed on a surface of the platform along the one direction. | 03-18-2010 |
| 20100041213 | Vapor Deposition Reactor For Forming Thin Film - A vapor deposition reactor includes a chamber filled with a first material, and at least one reaction module in the chamber. The reaction module may be configured to make a substrate pass the reaction module through a relative motion between the substrate and the reaction module. The reaction module may include an injection unit for injecting a second material to the substrate. A method for forming thin film includes positioning a substrate in a chamber, filling a first material in the chamber, moving the substrate relative to a reaction module in the chamber, and injecting a second material to the substrate while the substrate passes the reaction module. | 02-18-2010 |
| 20100041179 | Forming Substrate Structure by Filling Recesses with Deposition Material - A substrate structure is produced by forming a first material layer on a substrate having a recess, removing the first material layer from the portion of the substrate except for the recess using a second material that reacts with the first material, and forming a deposition film from the first material layer using a third material that reacts with the first material. A method of manufacturing a device may include the method of forming a substrate structure. | 02-18-2010 |
| 20100037824 | Plasma Reactor Having Injector - A plasma reactor includes a plasma generator configured to spray plasma, and an injector located adjacent to the plasma generator and configured to inject a precursor to the plasma sprayed from the plasma injector. The injector includes a platform having an opening, at least one injection hole formed in the platform to inject the precursor to the opening, and a channel formed in the platform to connect with the at least one injection hole to carry the precursor. The plasma reactor may allow supply of the plasma together with the precursor. In case corona plasma is used where a vacuum state is not needed, a wider process window may be ensured. | 02-18-2010 |
| 20100037820 | Vapor Deposition Reactor - A vapor deposition reactor includes a reaction module includes a first injection unit for injecting a first material onto a substrate. At least one second injection unit is placed within the first injection unit for injecting a second material onto the substrate. The substrate passes the reaction module through a relative motion between the substrate and the reaction module. The vapor deposition reactor advantageously injects a plurality of materials onto the substrate while the substrate passes the reaction module without exposing the substrate to the atmosphere in a chamber. | 02-18-2010 |
| 20100006145 | SOLAR CELL AND FABRICATING METHOD FOR THE SAME - Example embodiments relate to a solar cell and a method for fabricating the same, and more particularly, to a solar cell in which a substrate capable of functioning as electrode is used and a method for fabricating the same. The solar cell may include a substrate and a semiconductor layer laminated on the substrate. The solar cell may include a conductive substrate. The substrate may be a flexible substrate having a coefficient of thermal expansion comparable to that of the semiconductor layer. The semiconductor layer may be formed on the substrate. The solar cell may include a front electrode formed on the semiconductor layer. | 01-14-2010 |
