Abstract: In a symmetric crossover structure of two lines formed of a lower conductor layer and a higher conductor layer above a substrate, each of the two lines is branched to two routes at where they are crossed over to each other. The first route of the first line uses the higher layer to cross the first route of the second line and the lower layer to cross over the second route of the second line. The second route of the first line uses the lower layer to cross over the first route of the second line and the higher layer to cross over the second route of the second line. The two lines therefore have symmetric coupling effects to the substrate.

Abstract: A semiconductor method for a liquid crystal display that includes providing a substrate, providing a layer of insulating material over the substrate, depositing a layer of amorphous silicon over the layer of insulating material, crystallizing the layer of amorphous silicon to form a layer of polysilicon, treating the layer of polysilicon to change the properties of a surface of the layer of polysilicon, and smoothing the surface of the layer of polysilicon.

Abstract: A method of fabricating a polysilicon film by an excimer laser annealing process is introduced. First, an amorphous silicon film is deposited on a substrate composed of glass. The amorphous silicon film includes a first region, which is located in the center, with a first thickness, and a second region, which is located in the periphery, with a slant sidewall. The thickness of the amorphous silicon film is measured so as to obtain the profile of the sidewall in the second region. According to the profile of the sidewall, a pre-cursor region is determined for performing an excimer laser annealing process wherein a second thickness in the boundary of the pre-curser regionis smaller than the first thickness so as to increase area of produced polysilicon film.

Abstract: The present invention provides a method of forming a liquid crystal display (LCD). Active layers of N-type and P-type low temperature polysilicon thin film transistors and a bottom electrode of a storage capacitor are formed first. Then a N-type source/drain is formed and the bottom electrode is doped with dopants. A gate insulator, a gate electrode, a capacitor dielectric, and a top electrode are thereafter formed. After that, a P-type source/drain is formed. Finally, a source interconnect, a drain interconnect, and a pixel electrode of the liquid crystal display are formed.

Abstract: A six mask-steps method for fabricating liquid crystal display is described. A driving area and a pixel area are defined by a first mask step. Gates on the driving/pixel area and upper electrodes of capacitors on the pixel area are defined by a second mask step. Then, using the gates and the upper electrodes as a mask, a source/drain, channel region and lower electrode are formed in the driving/pixel area by an ion-doping process. A second insulation layer is formed and covers the insulation substrate. A plurality of first openings is formed by the third mask step and the gate and the source/drain are exposed. A second conductive layer is formed and covers the second insulation layer and the first opening is filled. Then, the second conductive layer is patterned, and a source/drain line is formed and contacts electrically with the source/drain by the fourth mask step. A dielectric layer is formed and covers the second insulation layer and the second conductive layer; the dielectric layer has a planar surface.

Abstract: A liquid crystal display device that includes a pixel electrode, a liquid crystal layer, a first dielectric layer formed between the pixel electrode and the liquid crystal layer having a first index of refraction and a first optical thickness, and a second dielectric layer formed between the first dielectric layer and the liquid crystal layer having a second index of refraction and a second optical thickness, wherein the second index of refraction is larger than the first index of refraction and the second optical thickness is larger than the first optical thickness.

Abstract: A method for fabricating a thin film transistor array and driving circuit comprising the steps of: providing a substrate; patterning a polysilicon layer and an N+ thin film over the substrate to form a plurality of islands; patterning the islands to form P+ doped regions; patterning out source/drain terminals and the lower electrode of a storage capacitor; etching back the N+ thin film; patterning out a gate and the upper electrode of the storage capacitor and patterning a passivation layer and a conductive layer to form pixel electrodes and a wiring layout.

Abstract: A method of silicon crystallization that includes providing an insulated substrate, depositing a layer of amorphous silicon over the substrate, crystallizing the layer of amorphous silicon in an oxygen environment for a reduced surface roughness on the layer of crystallized silicon, and oxidizing the layer of amorphous silicon simultaneously with crystallizing the layer of amorphous silicon to form a layer of gate insulator.

Abstract: A method of fabricating a polysilicon film by an excimer laser annealing process is introduced. First, an amorphous silicon film is deposited on a substrate composed of glass. The amorphous silicon film includes a first region, which is located in the center, with a first thickness, and a second region, which is located in the periphery, with a slant sidewall. The thickness of the amorphous silicon film is measured so as to obtain the profile of the sidewall in the second region. According to the profile of the sidewall, a pre-curser region is determined for performing an excimer laser annealing process wherein a second thickness in the boundary of the pre-curser region is smaller than the first thickness so as to increase area of produced polysilicon film.

Abstract: A liquid crystal display includes a reflective pixel electrode, a transparent electrode, a liquid crystal layer and a transparent conductive layer. The transparent electrode cooperates with the reflective pixel electrode to provide a driving voltage. The liquid crystal layer includes a plurality of liquid crystal molecules and is sandwiched between the reflective pixel electrode and the transparent electrode to align in a predetermined manner in response to the driving voltage. The transparent conductive layer is disposed between the reflective pixel electrode and the liquid crystal layer for protecting the reflective pixel electrode and enhancing the reflectivity of the pixel electrode without undesirably consuming the driving voltage.

Abstract: A six mask-steps method for fabricating liquid crystal display is described. A driving area and a pixel area are defined by a first mask step. Gates on the driving/pixel area and upper electrodes of capacitors on the pixel area are defined by a second mask step. Then, using the gates and the upper electrodes as a mask, a source/drain, channel region and lower electrode are formed in the driving/pixel area by an ion-doping process. A second insulation layer is formed and covers the insulation substrate. A plurality of first openings is formed by the third mask step and the gate and the source/drain are exposed. A second conductive layer is formed and covers the second insulation layer and the first opening is filled. Then, the second conductive layer is patterned, and a source/drain line is formed and contacts electrically with the source/drain by the fourth mask step. A dielectric layer is formed and covers the second insulation layer and the second conductive layer; the dielectric layer has a planar surface.

Abstract: An organic backlight device for liquid crystal display application is provided. The organic backlight device has organic light emitting layers, which are arranged in such as linear arrangement and controlled by a driving circuit, to emit light at least three different bandwidths by turns, for example, in red, green and blue bandwidths. By emitting light with a high frequency by turns, persistence of color vision is produced to a viewer. A thin and light backlight source with high brightness and uniformity is therefore obtained.

Abstract: A laser scanning system suitable for annealing applications is described. The problem of keeping the window (through which the laser shines into the system) clean, even though the laser ejects a considerable amount of debris, has been solved by inserting a moveable shutter close to the window between it and the substrate. The center portion of the shutter is an insert of optical quality quartz that is just large enough to allow the laser beam to pass through unimpeded and undiverted. By moving the beam and the shutter in concert it is ensured that the beam always passes through the insert. Most of the debris ejected by the laser as a side effect of its operation is trapped on the shutter. Relatively little material ends up on the quartz insert but when sufficient has accumulated there, the insert can be replaced at much lower cost than replacing the window. By moving the beam back and forth together with movement of the substrate, the entire area of the film on the substrate may be scanned by the beam.

Abstract: A laser scanning system suitable for annealing applications is described. The problem of keeping the window (through which the laser shines into the system) clean, even though the laser ejects a considerable amount of debris, has been solved by inserting a moveable shutter close to the window between it and the substrate. The center portion of the shutter is an insert of optical quality quartz that is just large enough to allow the laser beam to pass through unimpeded and undiverted. By moving the beam and the shutter in concert it is ensured that the beam always passes through the insert. Most of the debris ejected by the laser as a side effect of its operation is trapped on the shutter. Relatively little material ends up on the quartz insert but when sufficient has accumulated there, the insert can be replaced at much lower cost than replacing the window. By moving the beam back and forth together with movement of the substrate, the entire area of the film on the substrate may be scanned by the beam.

Abstract: This invention relates to a method of directing a therapeutic agent to selected cells, wherein a complex is formed between a polysaccharide capable of interacting with a cell receptor and a therapeutic agent. The resulting complex is administered to a subject, and permitted to be internalized into the selected cells through a process known as receptor mediated endocytosis (RME). The polysaccharide may be, for example, arabinogalactan, gum arabic, mannan or hydrolysis products thereof; the therapeutic agent may be, for example, an antiviral agent, a nucleic acid, hormone, steroid, antibody, chemoprotective or radioprotective agent. The cell receptor may be for example, the asialoglycoprotein receptor or the mannose receptor.

Abstract: A substantially purified arabinogalactan, its degradative products and selected modifications thereof have been found to act as carriers for delivering therapeutic agent to cell receptors capable of receptor mediated endocytosis (RME). The arabinogalactan and its degrative products once derivatived are capable of forming a complex between the therapeutic agent and the polysaccharide such that the complex retains the ability to recognize and bind to the RME receptor.

Abstract: The invention relates to a method for the targeting of a therapeutic agent to a specific population of cells, wherein a complex is formed between the therapeutic agent and a polysaccharide capable of interacting with a cell receptor, and wherein the resulting complex is internalized into the cell by receptor mediated endocytosis (RME). In one embodiment of the invention, a complex of a therapeutic agent containing iron and the polysaccharide arabinogalactan may be formed and used to deliver iron specifically to hepatocytes by RME.

Abstract: The invention provides a method of targeting an x-ray contrast agent to a specific population of cells or organ. Targeting may be accomplished by forming a complex of a radiopaque label with a saccharide capable of interacting with a cell receptor. The resulting complex may then be internalized into the specific population of cells or organ by receptor mediated endocytosis. In one embodiment of the invention, the radiopaque label may include a compound containing iodine and the saccharide may include arabinogalactan, galactan, or derivatives thereof. The invention provides a method for determining the metabolic viability or disease state of the target cells or organ by visualizing the extent, mode of uptake and excretion of the targeted x-ray contrast agent by x-ray or computer tomography.