Provided are a method of manufacturing a thin film transistor, a dehydrogenating apparatus for performing the method, and an organic light emitting display device including a thin film transistor manufactured by the same. A method of manufacturing a thin film transistor includes reducing a content of oxygen in a chamber for performing a dehydrogenation process of an amorphous silicon layer from a first value to a second value, inserting a substrate on which the amorphous silicon layer is formed into the chamber, heating the inside of the chamber to perform the dehydrogenation process on the amorphous silicon layer, and forming a polysilicon layer by crystallizing the amorphous silicon layer using a laser.

Provided are a method of manufacturing a thin film transistor, a dehydrogenating apparatus for performing the method, and an organic light emitting display device including a thin film transistor manufactured by the same. A method of manufacturing a thin film transistor includes reducing a content of oxygen in a chamber for performing a dehydrogenation process of an amorphous silicon layer from a first value to a second value, inserting a substrate on which the amorphous silicon layer is formed into the chamber, heating the inside of the chamber to perform the dehydrogenation process on the amorphous silicon layer, and forming a polysilicon layer by crystallizing the amorphous silicon layer using a laser.

An integrated circuit packaging is described and includes a plurality of electrical circuits developed using a first patterned conductive layer on a base, wherein the electrical circuit is formed by using a masking material, and a stud conductive layer disposed on at least one side of the first patterned conductive layer developed by a second layer photo-resist material on the masking material, in which the second layer photo-resist material includes a first line layer with a smaller exposed area than the surface of the conductive layer disposed on one side of the first patterned conductive layer and a second line layer with a larger exposed area than the first line layer disposed on the first layer, such that the exposed area forms an “I” shaped connection of the conductive layer and the stud conductive layer.

An integrated circuit packaging is described and includes a plurality of electrical circuits developed using a first patterned conductive layer on a base, wherein the electrical circuit is formed by using a masking material, and a stud conductive layer disposed on at least one side of the first patterned conductive layer developed by a second layer photo-resist material on the masking material, in which the second layer photo-resist material includes a first line layer with a smaller exposed area than the surface of the conductive layer disposed on one side of the first patterned conductive layer and a second line layer with a larger exposed area than the first line layer disposed on the first layer, such that the exposed area forms an “I” shaped connection of the conductive layer and the stud conductive layer.

A method for fabricating an integrated circuit device is disclosed. A substrate is provided and an integrated circuit area is formed on the substrate. The integrated circuit area includes a dielectric stack. A seal ring is formed in the dielectric stack and around a periphery of the integrated circuit area. A trench is formed around the seal ring and exposing a sidewall of the dielectric stack. The trench is formed within a scribe line. A moisture blocking layer is formed on the sidewall of the dielectric stack, thereby sealing a boundary between two adjacent dielectric films in the dielectric stack.

A method for manufacturing an electronic device is provided. The method includes the following steps: providing a first mother substrate including a plurality of first substrate areas; performing a first half-cutting step on the first mother substrate to produce a first crack to define the plurality of first substrate areas; disposing a first optical film on the first mother substrate having the first crack, wherein the first optical film has a first cutting region corresponding to the first crack; performing a first cutting step in the first cutting region of the first optical film; and separating the plurality of first substrate areas to form a plurality of first substrates.

A volatile memory device can include a bit line structure having a vertical side wall. A lower spacer can be on a lower portion of the vertical side wall, where the lower spacer can be defined by a first thickness from the vertical side wall to an outer side wall of the lower spacer. An upper spacer can be on an upper portion of the vertical side wall above the lower portion, where the upper spacer can be defined by a second thickness that is less than the first thickness, the upper spacer exposing an uppermost portion of the outer side wall of the lower spacer.

A volatile memory device can include a bit line structure having a vertical side wall. A lower spacer can be on a lower portion of the vertical side wall, where the lower spacer can be defined by a first thickness from the vertical side wall to an outer side wall of the lower spacer. An upper spacer can be on an upper portion of the vertical side wall above the lower portion, where the upper spacer can be defined by a second thickness that is less than the first thickness, the upper spacer exposing an uppermost portion of the outer side wall of the lower spacer.

A stressed substrate for transient electronic systems (i.e., electronic systems that visually disappear when triggered to do so) that includes one or more stress-engineered layers that store potential energy in the form of a significant internal stress. An associated trigger mechanism is also provided that, when triggered, causes an initial fracture in the stressed substrate, whereby the fracture energy nearly instantaneously travels throughout the stressed substrate, causing the stressed substrate to shatter into multiple small (e.g., micron-sized) pieces that are difficult to detect. The internal stress is incorporated into the stressed substrate through strategies similar to glass tempering (for example through heat or chemical treatment), or by depositing thin-film layers with large amounts of stress. Patterned fracture features are optionally provided to control the final fractured particle size. Electronic systems built on the substrate are entirely destroyed and dispersed during the transience event.

A stressed substrate for transient electronic systems (i.e., electronic systems that visually disappear when triggered to do so) that includes one or more stress-engineered layers that store potential energy in the form of a significant internal stress. An associated trigger mechanism is also provided that, when triggered, causes an initial fracture in the stressed substrate, whereby the fracture energy nearly instantaneously travels throughout the stressed substrate, causing the stressed substrate to shatter into multiple small (e.g., micron-sized) pieces that are difficult to detect. The internal stress is incorporated into the stressed substrate through strategies similar to glass tempering (for example through heat or chemical treatment), or by depositing thin-film layers with large amounts of stress. Patterned fracture features are optionally provided to control the final fractured particle size. Electronic systems built on the substrate are entirely destroyed and dispersed during the transience event.