Abstract: A thin film transistor includes a gate electrode, a first insulating layer disposed to cover the gate electrode, a semiconductor layer disposed on the first insulating layer that includes a first side surface portion, a source electrode disposed on the semiconductor layer, and a drain electrode disposed on the first insulating layer that includes a second side surface portion. The first side surface portion makes contact with the second side surface portion.

Abstract: An organic light emitting diode display device includes a substrate, a driving transistor, and a sub-pixel structure. The substrate has a first trench. The driving transistor is inside the first trench of the substrate. The sub-pixel structure is on the driving transistor.

Abstract: The oxide of the present invention for thin-film transistors is an In—Zn—Sn-based oxide containing In, Zn, and Sn, wherein when the respective contents (atomic %) of metal elements contained in the In—Zn—Sn-based oxide are expressed by [Zn], [Sn], and [In], the In—Zn—Sn-based oxide fulfills the following expressions (2) and (4) when [In]/([In]+[Sn])?0.5; or the following expressions (1), (3), and (4) when [In]/([In]+[Sn])>0.5. [In]/([In]+[Zn]+[Sn])?0.3??(1), [In]/([In]+[Zn]+[Sn])?1.4×{[Zn]/([Zn]+[Sn])}?0.5??(2), [Zn]/([In]+[Zn]+[Sn])?0.83??(3), and 0.1?[In]/([In]+[Zn]+[Sn])??(4). According to the present invention, oxide thin films for thin-film transistors can be obtained, which provide TFTs with excellent switching characteristics, and which have high sputtering rate in the sputtering and properly controlled etching rate in the wet etching.

Abstract: Provided is a common-path optical fiber-based handheld parallel optical coherence tomography (OCT) apparatus, including a probe configured to receive the light from a broadband light source and illuminate a measurement target, wherein the probe may include an inner space through which the light passes, a collimator configured to collimate the light incident to the inner space, a diffraction grating configured to diffract the light having passed through the collimator, a galvanometer scanner configured to reflect the light having passed through the diffraction grating, an objective lens configured to concentrate the reflected light on a focal point, and an interferer configured to acquire an interfered light by reflecting at least a portion of the light having passed through the objective lens.

Abstract: Provided is a common-path optical fiber-based handheld parallel optical coherence tomography (OCT) apparatus

Abstract: In an oxide for a semiconductor layer of a thin film transistor according to the present invention, wherein metal elements constituting the oxide are In, Zn, and Sn, an oxygen partial pressure is 15% by volume or more when depositing the oxide in the semiconductor layer of the thin film transistor, and a defect density of the oxide satisfies 7.5×1015cm?3 or less, and a mobility satisfies 15 cm2/Vs or more.

Abstract: The oxide of the present invention for thin-film transistors is an In—Zn—Sn-based oxide containing In, Zn, and Sn, wherein when the respective contents (atomic %) of metal elements contained in the In—Zn—Sn-based oxide are expressed by [Zn], [Sn], and [In], the In—Zn—Sn-based oxide fulfills the following expressions (2) and (4) when [In]/([In]+[Sn])?0.5; or the following expressions (1), (3), and (4) when [In]/([In]+[Sn])>0.5. [In]/([In]+[Zn]+[Sn])?0.3 - - - (1), [In]/([In]+[Zn]+[Sn])?1.4×{[Zn]/([Zn]+[Sn])}?0.5 - - - (2), [Zn]/([In]+[Zn]+[Sn])?0.83 - - - (3), and 0.1?[In]/([In]+[Zn]+[Sn]) - - - (4). According to the present invention, oxide thin films for thin-film transistors can be obtained, which provide TFTs with excellent switching characteristics, and which have high sputtering rate in the sputtering and properly controlled etching rate in the wet etching.

Abstract: The inventive concept relates to a thin film transistor and a thin film transistor array panel and, in detail, relates to a thin film transistor including an oxide semiconductor. A thin film transistor according to an exemplary embodiment of the inventive concept includes: a gate electrode; a gate insulating layer positioned on or under the gate electrode; a first semiconductor and a second semiconductor that overlap the gate electrode with the gate insulating layer interposed therebetween, the first semiconductor and the second semiconductor contacting each other; a source electrode connected to the second semiconductor; and a drain electrode connected to the second semiconductor and facing the source electrode, wherein the second semiconductor includes gallium (Ga) that is not included in the first semiconductor, and a content of gallium (Ga) in the second semiconductor is greater than 0 at. % and less than or equal to about 33 at. %.

Abstract: Provided is a thin film transistor wherein the shape of a protrusion formed on the interface between an oxide semiconductor layer and a protection film is suitably controlled, and stable characteristics are achieved. This thin film transistor is characterized in that: the thin film transistor has an oxide semiconductor layer formed of an oxide containing at least In, Zn and Sn as metal elements, and a protection film directly in contact with the oxide semiconductor layer; and the maximum height of a protrusion formed on the oxide semiconductor layer surface directly in contact with the protection film is less than 5 nm.

Abstract: Provided is a thin film transistor which is provided with an oxide semiconductor thin film layer and has a threshold voltage that does not change much due to light, a bias stress or the like, thereby exhibiting excellent stress stability. A thin film transistor of the present invention is provided with a gate electrode, an oxide semiconductor layer composed of a single layer which is used as a channel layer, an etch stopper layer to protect a surface of the oxide semiconductor layer, a source-drain electrode, and a gate insulator layer arranged between the gate electrode and the channel layer. The metal elements constituting the oxide semiconductor layer comprise In, Zn and Sn. The hydrogen concentration in the gate insulator layer in direct contact with the oxide semiconductor layer is controlled to 4 atomic % or lower.

Abstract: In an oxide for a semiconductor layer of a thin film transistor according to the present invention, wherein metal elements constituting the oxide are In, Zn, and Sn, an oxygen partial pressure is 15% by volume or more when depositing the oxide in the semiconductor layer of the thin film transistor, and a defect density of the oxide satisfies 7.5×1015cm?3 or less, and a mobility satisfies 15 cm2/Vs or more.

Abstract: Exemplary embodiments provide compositions for a solution process, electronic devices fabricated using the same, and fabrication methods thereof. An oxide nano-structure is formed using a sol-gel process. An oxide thin film transistor is formed using the oxide nano-structure.

Abstract: A method of fabricating a liquid for an oxide thin film is provided, which includes mixing at least two kinds of dispersoids selected from the group consisting of a Zinc compound, an Indium compound, a Gallium compound, a Tin compound and a Thallium compound, with dispersion media corresponding to the selected dispersoids to form a dispersion system, and stirring and aging the dispersion system at a predetermined temperature for a predetermined time, wherein a molar ratio of the Zinc compound to each of the Indium compound, Gallium compound, Tin compound and Thallium compound is 1:0.1 to 1:2. According to the present invention, the liquid for the oxide thin film may be fabricated by a sol-gel method making it capable of being implemented in mass production in a simple and low-cost manner as opposed to the conventional vacuum deposition method.

Abstract: A thin film transistor containing at least, a gate electrode, a gate insulating film, an oxide semiconductor layer, source-drain electrode and a passivation film, in this order on a substrate. The oxide semiconductor layer is a laminate containing a first oxide semiconductor layer (IGZTO) and a second oxide semiconductor layer (IZTO). The second oxide semiconductor layer is formed on the gate insulating film, and the first oxide semiconductor layer is formed between the second oxide semiconductor layer and the passivation film. The contents of respective metal elements relative to the total amount of all the metal elements other than oxygen in the first oxide semiconductor layer are as follows; Ga: 8% or more and 30% or less; In: 25% or less, excluding 0%; Zn: 35% or more to 65% or less; and Sn: 5% or more to 30% or less.

Abstract: A sputtering target includes: a first crystal comprising In2O3 in a bixbyite structure and SnO2 of a tetragonal structure; and a second crystal comprising In4Sn3O12 in an orthorhombic structure, wherein the second crystal accounts for 8 to 16% of a total size of the first and second crystals.

Abstract: Exemplary embodiments provide compositions for a solution process, electronic devices fabricated using the same, and fabrication methods thereof. An oxide nano-structure is formed using a sol-gel process. An oxide thin film transistor is formed using the oxide nano-structure.

Abstract: An oxide semiconductor includes a first material including at least one selected from the group consisting of zinc (Zn) and tin (Sn), and a second material, where a value acquired by subtracting an electronegativity difference value between the second material and oxygen (O) from the electronegativity difference value between the first material and oxygen (O) is less than about 1.3.

Abstract: This oxide for a semiconductor layer of a thin-film transistor contains Zn, Sn and In, and the content (at %) of the metal elements contained in the oxide satisfies formulas (1) to (3) when denoted as [Zn], [Sn] and [In], respectively. [In]/([In]+[Zn]+[Sn])??0.53×[Zn]/([Zn]+[Sn])+0.36 (1) [In]/([In]+[Zn]+[Sn])?2.28×[Zn]/([Zn]+[Sn])?2.01 (2) [In]/([In]+[Zn]+[Sn])?1.1×[Zn]/([Zn]+[Sn])?0.32 (3) The present invention enables a thin-film transistor oxide that achieves high mobility and has excellent stress resistance (negligible threshold voltage shift before and after applying stress) to be provided.

Abstract: A thin film transistor array panel includes: a gate electrode disposed on a substrate, an insulating layer disposed on the gate electrode, an oxide semiconductor disposed on the gate insulating layer, source electrode overlapping a portion of the oxide semiconductor, a drain electrode overlapping another portion of the oxide semiconductor; and a buffer layer disposed between the oxide semiconductor and the source electrode and between the oxide semiconductor and the drain electrode. The buffer layer comprises tin as a doping material. A weight percent of the doping material is greater than approximately 0% and less than or equal to approximately 20%.

Abstract: Provided is a thin film transistor wherein the shape of a protrusion formed on the interface between an oxide semiconductor layer and a protection film is suitably controlled, and stable characteristics are achieved. This thin film transistor is characterized in that: the thin film transistor has an oxide semiconductor layer formed of an oxide containing at least In, Zn and Sn as metal elements, and a protection film directly in contact with the oxide semiconductor layer; and the maximum height of a protrusion formed on the oxide semiconductor layer surface directly in contact with the protection film is less than 5 nm.