Abstract: The present invention provides a microfluidic chip for culturing microorganism and a method of operating the same. The microfluidic chip includes a first input unit, a second input unit, a connection unit connected to the first and second input units, a plurality of control valves, and a ring-shaped storage structure connected to the connection unit and having first and second growth chambers that store a microbial solution. The first and second input units provide first and second solutions, respectively. The first solution is transferred into the first or second growth chamber through the connection unit to treat and discharge a portion of the microbial solution. The second solution is transferred into the first or second growth chamber to discharge the first solution. The control valves are actuated to mix the second solution and remainder of the microbial solution in the ring-shaped storage structure.

Abstract: Methods for forming a film stack suitable for transistor fabrication using a low temperature plasma enhanced chemical vapor deposition (PECVD) process are provided. In one embodiment, the method includes providing a substrate in a PECVD chamber, depositing a dual layer SiNx film on the substrate, depositing a dual layer amorphous silicon film on the SiNx film, and depositing a n-doped silicon film on the dual layer amorphous silicon film. The aforementioned films are deposited at a temperature less than about 300 degrees Celsius in the same PECVD chamber.

Abstract: A method and apparatus for forming a thin film transistor is provided. A gate dielectric layer is formed, which may be a bilayer, the first layer deposited at a low rate and the second deposited at a high rate. In some embodiments, the first dielectric layer is a silicon rich silicon nitride layer. An active layer is formed, which may also be a bilayer, the first active layer deposited at a low rate and the second at a high rate. The thin film transistors described herein have superior mobility and stability under stress.

Abstract: A method and apparatus for forming a thin film transistor is provided. A gate dielectric layer is formed, which may be a bilayer, the first layer deposited at a low rate and the second deposited at a high rate. In some embodiments, the first dielectric layer is a silicon rich silicon nitride layer. An active layer is formed, which may also be a bilayer, the first active layer deposited at a low rate and the second at a high rate. The thin film transistors described herein have superior mobility and stability under stress.

Abstract: The present invention generally comprises a low cost TFT and a method of manufacturing a TFT. For TFTs, soda lime glass would be an attractive alternative to non-alkali glass, but a soda lime glass substrate will permit sodium to diffuse into the active layer and degrade the performance of the TFT. Substrates comprising a polyimide, because they are flexible, would also be attractive to utilize instead of non-alkali glass substrates, but the plastic substrates permit carbon to diffuse into the active layer. By depositing a silicon oxynitride adhesion layer over the soda lime glass substrate and a silicon rich barrier layer over the adhesion layer, diffusion may be reduced and deposition may occur at high temperatures. Thus, a lower cost TFT may be produced with a soda lime glass substrate or a substrate comprising a polyimide as compared to a non-alkali glass substrate.

Abstract: The present invention generally comprises a low cost TFT and a method of manufacturing a TFT. For TFTs, soda lime glass would be an attractive alternative to non-alkali glass, but a soda lime glass substrate will permit sodium to diffuse into the active layer and degrade the performance of the TFT. Substrates comprising a polyimide, because they are flexible, would also be attractive to utilize instead of non-alkali glass substrates, but the plastic substrates permit carbon to diffuse into the active layer. By depositing a silicon rich barrier layer over the soda lime glass substrate or substrate comprising a polyimide, both sodium and carbon diffusion may be reduced. Thus, a lower cost TFT may be produced with a soda lime glass substrate or a substrate comprising a polyimide as compared to a non-alkali glass substrate.

Abstract: Methods for forming a film stack suitable for transistor fabrication using a low temperature plasma enhanced chemical vapor deposition (PECVD) process are provided. In one embodiment, the method includes providing a substrate in a PECVD chamber, depositing a dual layer SiNx film on the substrate, depositing a dual layer amorphous silicon film on the SiNx film, and depositing a n-doped silicon film on the dual layer amorphous silicon film.

Abstract: Methods for depositing a gate insulator layer and a semiconductor layer onto a large area substrate with improved film uniformity, device mobility and stability are provided. The film properties of the gate insulator layer and the semiconductor layer are selected so that higher electron mobility (greater than 0.7 centimeters squared per voltage per second) is obtained, thereby efficiently enhancing the performance and stability of TFT devices. Improvements in film uniformity may also be realized.