A method for manufacturing an organic light-emitting diode(OLED) backplane is provided. The method includes sequentially depositing a first oxide semiconductor layer, a second oxide semiconductor layer and a third oxide semiconductor layer to obtain an active layer of a thin film transistor. The flow ratio of an argon gas and an oxygen gas introduced during the deposition of the first and third oxide semiconductor layers is greater than the flow ratio of the argon gas and the oxygen gas introduced during the deposition of the second oxide semiconductor layer. As a result, the oxygen content of the first and third oxide semiconductor layers is greater than the oxygen content of the second oxide semiconductor layer. Therefore, the conductivity of the active layer of the thin film transistor device is enhanced. The interface defects are reduced. The stability of the thin film transistor device is improved.

The purpose of the invention is to form the TFT of the oxide semiconductor, in which influence of variation in mask alignment is suppressed, thus, manufacturing a display device having a TFT of stable characteristics. The concrete measure is as follows. A display device including plural pixels, each of the plural pixels having a thin film transistor (TFT) of an oxide semiconductor comprising: a width of the oxide semiconductor in the channel width direction is wider than a width of the gate electrode in the channel width direction.

The purpose of the invention is to form the TFT of the oxide semiconductor, in which influence of variation in mask alignment is suppressed, thus, manufacturing a display device having a TFT of stable characteristics. The concrete measure is as follows. A display device including plural pixels, each of the plural pixels having a thin film transistor (TFT) of an oxide semiconductor comprising: a width of the oxide semiconductor in the channel width direction is wider than a width of the gate electrode in the channel width direction.

A semiconductor device with high reliability is provided. The present invention relates to a method for manufacturing a transistor including an oxide semiconductor. A stacked-layer structure of an oxide semiconductor and an insulator functioning as a gate insulator is subjected to microwave-excited plasma treatment, whereby the carrier concentration of the oxide semiconductor is reduced and the barrier property of the gate insulator is improved. In addition, a conductor functioning as an electrode and the insulator functioning as a gate insulator are formed in contact with the oxide semiconductor and then the microwave-excited plasma treatment is performed, whereby a high-resistance region and a low-resistance region can be formed in the oxide semiconductor in a self-aligned manner. Moreover, the microwave-excited plasma treatment is performed under an atmosphere containing oxygen with a high pressure, whereby a transistor having favorable electrical characteristics can be provided.

A semiconductor device with high reliability is provided. The present invention relates to a method for manufacturing a transistor including an oxide semiconductor. A stacked-layer structure of an oxide semiconductor and an insulator functioning as a gate insulator is subjected to microwave-excited plasma treatment, whereby the carrier concentration of the oxide semiconductor is reduced and the barrier property of the gate insulator is improved. In addition, a conductor functioning as an electrode and the insulator functioning as a gate insulator are formed in contact with the oxide semiconductor and then the microwave-excited plasma treatment is performed, whereby a high-resistance region and a low-resistance region can be formed in the oxide semiconductor in a self-aligned manner. Moreover, the microwave-excited plasma treatment is performed under an atmosphere containing oxygen with a high pressure, whereby a transistor having favorable electrical characteristics can be provided.

Described herein are apparatuses, systems, and methods associated with a voltage regulator circuit that includes one or more thin-film transistors (TFTs). The TFTs may be formed in the back-end of an integrated circuit. Additionally, the TFTs may include one or more unique features, such as a channel layer treated with a gas or plasma, and/or a gate oxide layer that is thicker than in prior TFTs. The one or more TFTs of the voltage regulator circuit may improve the operation of the voltage regulator circuit and free up front-end substrate area for other devices. Other embodiments may be described and claimed.

Described herein are apparatuses, systems, and methods associated with a voltage regulator circuit that includes one or more thin-film transistors (TFTs). The TFTs may be formed in the back-end of an integrated circuit. Additionally, the TFTs may include one or more unique features, such as a channel layer treated with a gas or plasma, and/or a gate oxide layer that is thicker than in prior TFTs. The one or more TFTs of the voltage regulator circuit may improve the operation of the voltage regulator circuit and free up front-end substrate area for other devices. Other embodiments may be described and claimed.

In some embodiments of the present disclosure, a method for forming a semiconductor device is described. A semiconductor layer is formed and a dielectric layer is formed. A pressurized treatment is performed to transform the semiconductor layer into a low-doping semiconductor layer and transform the dielectric layer into a crystalline ferroelectric layer. A gate layer is formed. An insulating layer is formed over the gate layer, the crystalline ferroelectric layer and the low-doping semiconductor layer. Contact openings are formed in the insulating layer exposing portions of the low-doping semiconductor layer. Source and drain terminals are formed on the low-doping semiconductor layer.

In some embodiments of the present disclosure, a method for forming a semiconductor device is described. A semiconductor layer is formed and a dielectric layer is formed. A pressurized treatment is performed to transform the semiconductor layer into a low-doping semiconductor layer and transform the dielectric layer into a crystalline ferroelectric layer. A gate layer is formed. An insulating layer is formed over the gate layer, the crystalline ferroelectric layer and the low-doping semiconductor layer. Contact openings are formed in the insulating layer exposing portions of the low-doping semiconductor layer. Source and drain terminals are formed on the low-doping semiconductor layer.

A memory cell includes a transistor over a semiconductor substrate. The transistor includes a ferroelectric layer arranged along a sidewall of a word line. The ferroelectric layer includes a species with valence of 5, valence of 7, or a combination thereof. An oxide semiconductor layer is electrically coupled to a source line and a bit line. The ferroelectric layer is disposed between the oxide semiconductor layer and the word line.