Systems, methods, and apparatus for an improved body tie construction that produces all the benefits of conventional body tie (H-gate, T-gate), without the limitations and degradations associated with those constructions are described. The improved body tie construction is configured to have a lower resistance body tie when the transistor is off (Vg approximately 0 volts). When the transistor is on (Vg>Vt), the resistance to the body tie is much higher, reducing the loss of performance associated with presence of body tie.

An active matrix substrate in a liquid crystal panel of an FFS mode has a data line 24 including an amorphous Si film 122, an n+amorphous Si film 123, a main conductor part 133, and an IZO film 141. The main conductor part 133 and the IZO film 141 are etched at a portion close to the end of a covered region of a photoresist 142, to form the n+amorphous Si film 123 larger than the main conductor part 133 and the IZO film 141. A pattern of a photomask for a source layer is made larger than a pattern of a photomask for a pixel electrode layer, to form the amorphous Si film 122 larger than the n+amorphous Si film 123. The main conductor part 133 is formed of a molybdenum-based material, and in a layer over the data line 24, two-layered protective insulating films are formed such that a compressive stress is generated in one film and a tensile stress is generated in the other film. Accordingly, a high-yield active matrix substrate having a common electrode is provided.

A thin film transistor, a manufacturing method thereof and an array substrate are provided. The thin film transistor comprises: a gate electrode (11), a source electrode (15) and a drain electrode (16), and the thin film transistor further comprises a buffer layer (11) which is directly provided at one side or both sides of at least one of the gate electrode (11), the source electrode (15) and the drain electrode (16), wherein, the buffer layer (11) and at least one of the gate electrode (11), the source electrode (15) and the drain electrode (16) directly contacting the buffer layer (11) are conformal. Therefore, the adhesion between an electrode of the thin film transistor and a film layer contacting it is improved and at the same time an atom in the electrode of the thin film transistor is effectively prevented from diffusing to the film layer connected with it, and the reliability of the thin film transistor is improved and the production cost is reduced.

A thin film transistor (TFT) includes a semiconductive layer, a first inter-layer drain (ILD) layer, a second ILD layer, and at least one contact hole passing through the first ILD layer and the second ILD layer. The semiconductive layer includes a channel region, a first lightly doped drain (LDD) region, a second LDD region, a first heavily doped drain (HDD) region, and a second HDD region. The at least one contact hole includes a first portion passing through the second ILD layer and a second portion passing through the first ILD layer. The second portion gradually narrows along a direction from a top to a bottom of the first ILD layer.

A low temperature poly-silicon thin film transistor and a manufacturing method thereof are disclosed. The method includes forming an active layer on a base substrate, forming an ohmic contact layer on the active layer through an atomic layer deposition process, and forming a source electrode and a drain electrode on the ohmic contact layer. The ohmic contact layer includes a plurality of conductive ionic layers and a plurality of monocrystalline silicon layers/poly-silicon layers. The source electrode and the drain electrode are in contact with the active layer through the ohmic contact layer.

A TFT and manufacturing method thereof, an array substrate and manufacturing method thereof, an X-ray detector and a display device are disclosed. The manufacturing method includes: forming a gate-insulating-layer thin film (3), a semiconductor-layer thin film (4) and a passivation-shielding-layer thin film (5) successively; forming a pattern (5) that includes a passivation shielding layer through one patterning process, so that a portion, sheltered by the passivation shielding layer, of the semiconductor-layer thin film forms a pattern of an active layer (4a); and performing an ion doping process to a portion, not sheltered by the passivation shielding layer, of the semiconductor-layer thin film to form a pattern comprising a source electrode (4c) and a drain electrode (4b). The source electrode (4c) and the drain electrode (4b) are disposed on two sides of the active layer (4a) respectively and in a same layer as the active layer (4a). The manufacturing method can reduce the number of patterning processes and improve the performance of the thin film transistor in the array substrate.

An organic light emitting display device is discussed. The organic light emitting display device according to an embodiment includes a base substrate, a buffer layer disposed on the base substrate, and a thin film transistor disposed on the buffer layer. The organic light emitting display device further includes an organic light emitting diode connected to the thin film transistor and disposed on the thin film transistor. The thin film transistor includes a gate electrode, a source electrode, and a drain electrode. At least one of the gate, source, and drain electrodes of the thin film transistor includes a semi-transmissive metal layer, a transparent metal layer, and a reflective metal layer to improve outdoor visibility of a display panel by reducing reflectance of the electrodes even though a polarizer is removed.

It is an object to manufacture a highly reliable display device using a thin film transistor having favorable electric characteristics and high reliability as a switching element. In a bottom gate thin film transistor including an amorphous oxide semiconductor, an oxide conductive layer having a crystal region is formed between an oxide semiconductor layer which has been dehydrated or dehydrogenated by heat treatment and each of a source electrode layer and a drain electrode layer which are formed using a metal material. Accordingly, contact resistance between the oxide semiconductor layer and each of the source electrode layer and the drain electrode layer can be reduced; thus, a thin film transistor having favorable electric characteristics and a highly reliable display device using the thin film transistor can be provided.

The disclosure relates to a method for manufacturing an Au-free ohmic contact for an III-nitride (III-N) device on a semiconductor substrate and to a III-N device obtainable therefrom. The III-N device includes a buffer layer, a channel layer, a barrier layer, and a passivation layer. A 2DEG layer is formed at an interface between the channel layer and the barrier layer. The method includes forming a recess in the passivation layer and in the barrier layer up to the 2DEG layer, and forming an Au-free metal stack in the recess. The metal stack comprises a Ti/Al bi-layer, with a Ti layer overlying and in contact with a bottom of the recess, and a Al layer overlying and in contact with the Ti layer. A thickness ratio of the Ti layer to the Al layer is between 0.01 to 0.1. After forming the metal stack, a rapid thermal anneal is performed. Optionally, prior to forming the Ti/Al bi-layer, a silicon layer may be formed in contact with the recess.

After forming a buried nanowire segment surrounded by a gate structure located on a substrate, an epitaxial source region is grown on a first end of the buried nanowire segment while covering a second end of the buried nanowire segment and the gate structure followed by growing an epitaxial drain region on the second end of the buried nanowire segment while covering the epitaxial source region and the gate structure. The epitaxial source region includes a first semiconductor material and dopants of a first conductivity type, while the epitaxial drain region includes a first semiconductor material different from the first semiconductor material and dopants of a second conductivity type opposite the first conductivity type.