Abstract: A display device includes a display panel and a switch panel. The switch panel includes a first substrate disposed on the display panel, a shielding pattern layer, a light transmitting layer, pixel electrodes disposed on the light transmitting layer, a second substrate disposed on the pixel electrodes, and the liquid crystal layer disposed between the first substrate and the second substrate. The shielding pattern layer is disposed on the first substrate and includes opening parts and light shielding parts arranged alternately with the opening parts. Each of the light shielding parts has a first thickness. The light transmitting layer is disposed on the shielding pattern layer and includes filling parts filling the opening parts and extending parts arranged alternately with the filling parts. Each of the filling parts has a second thickness greater than the first thickness.

Abstract: Embodiments of present disclosure relates to forming isolation structures in gate structures to prevent current leakage through source/drain regions (EPI), transistors, and silicon substrate. The isolation structures are arranged in a pattern with a long isolation structure adjacent a short isolation structure. The isolation structures may be formed in the gate structure prior to or after the replacement gate sequence.

Abstract: A structure includes a plurality of semiconductor regions, a first gate stack and a second gate stack immediately neighboring each other, a first fin isolation region in the first gate stack, and a second fin isolation region in the second gate stack. The first fin isolation region and the second fin isolation region have a sideway overlap having an overlap distance being equal to or greater than a pitch of the plurality of semiconductor regions. The overlap distance is measured in a direction parallel to lengthwise directions of the first gate stack and the second gate stack. A plurality of source/drain regions are on opposing sides of the first gate stack and the second gate stack to form a plurality of transistors.

Abstract: A semiconductor device includes a first wafer comprising a first portion of a seal ring structure within a body of the first wafer. The semiconductor device includes a second wafer comprising a second portion of the seal ring structure within a body of the second wafer. The second wafer is affixed to the first wafer such that the second portion of the seal ring structure is on the first portion of the seal ring structure. The semiconductor device includes a trench structure comprising a first trench in the first wafer and a second trench in the second wafer, where the first trench and the second trench are on a same side of the seal ring structure.

Abstract: An embodiment of the present disclosure provides a semiconductor device. The semiconductor device has a first semiconductor structure; a second semiconductor structure on the first semiconductor structure and having a first aluminum content; a plurality of voids in the second semiconductor structure; an active structure between the first semiconductor structure and the second semiconductor structure; and a third semiconductor structure between the active structure and the second semiconductor structure, and having a second aluminum content. The first aluminum content is greater than the second aluminum content.

Abstract: A high electron mobility transistor includes a substrate, a mesa structure disposed on the substrate, a passivation layer disposed on the mesa structure, and at least a contact structure disposed in the passivation layer and the mesa structure. The mesa structure includes a channel layer, a barrier layer on the channel layer, two opposite first edges extending along a first direction, and two opposite second edges extending along a second direction. The contact structure includes a body portion and a plurality of protruding portions. The body portion penetrates through the passivation layer. The protruding portions penetrate through the barrier layer and a portion of the channel layer. In a top view, the body portion overlaps the two opposite first edges of the mesa structure without overlapping the two opposite second edges of the mesa structure.

Abstract: According to an embodiment of the invention, a backlight driver of driving a light-emitting diode (LED) string via a driving transistor in a load path is provided. The LED string, the driving transistor, and an electrical load are coupled to form the load path. The backlight driver includes a current regulator and a headroom detection circuit. The current regulator is coupled to the driving transistor and the first terminal of the electrical load to control a driving current flowing through the load path according to at least a feedback voltage from a first terminal of the electrical load. The headroom detection circuit is coupled to the first terminal of the electrical load and a voltage regulator to control the voltage regulator to regulate a supply voltage to a first terminal of the LED string according to at least the feedback voltage.

Abstract: Methods for isolating two adjacent transistors are disclosed. A substrate has a first semiconducting fin on a first region and a second semiconducting fin on a second region, and the first semiconducting fin and the second semiconducting fin contact each other at a jog region. A dummy gate within or adjacent the jog region is removed to expose a portion of the first semiconducting fin and form an isolation volume. Etching is performed to remove the exposed portion of the first semiconducting fin and create a trench in the substrate. The trench and the isolation volume are filled with at least one dielectric material to form an electrically isolating structure between the first region and the second region. Additional dummy gates in each region can be removed and replaced with an electrically conductive material to form two adjacent transistors electrically isolated from each other.

Abstract: A semiconductor device, including a base and a semiconductor stack. The semiconductor stack includes a first semiconductor structure located on the base, a second semiconductor structure located on the first semiconductor structure, and an active structure located between the first semiconductor structure and the second semiconductor structure. The active structure includes two confinement layers and a well layer located between the two confinement layers. One of the confinement layers includes Alx1Ga1-x1As, and x1 is equal to or larger than 0.25 and equal to or smaller than 0.4. The well layer includes Inx2Ga1-x2As, and x2 is equal to or larger than 0.25 and equal to or smaller than 0.3. The one of the confinement layers and the well layer respectively have a first thickness in a range of 200 nm to 400 nm and a second thickness in a range of 3 nm to 6 nm.

Abstract: A continuous metal on diffusion edge (CMODE) may be used to form a CMODE structure in a semiconductor device after a replacement gate process that is performed to replace the polysilicon dummy gate structures of the semiconductor device with metal gate structures. The CMODE process described herein includes removing a portion of a metal gate structure (as opposed to removing a portion of a polysilicon dummy gate structure) to enable formation of the CMODE structure in a recess left behind by removal of the portion of the metal gate structure.

Abstract: A semiconductor device includes a first wafer and a second wafer. The semiconductor device includes a seal ring structure comprising a first metal structure in a body of the first wafer, a second metal structure in the body of the first wafer, a third metal structure in a body of the second wafer, and a metal bonding structure including a first set of metal elements coupling the first metal structure and the third metal structure through an interface between the first wafer and the second wafer, and a second set of metal elements coupling the second metal structure and the third metal structure through the interface between the first wafer and the second wafer.

Abstract: Using a large language model to comply with a user request. The large language model receives tool documentation for each of one or more tools, and analyzes the tool documentation for each of the one or more tools to determine, for each tool, one or more tasks that the tool is operable to perform. Upon receiving a request from a user, the large language model generates a plan for complying with the request by using one or more of the tools, the plan including performance of one or more of the tasks.

Abstract: A semiconductor device includes a first wafer comprising a first portion of a seal ring structure within a body of the first wafer. The semiconductor device includes a second wafer comprising a second portion of the seal ring structure within a body of the second wafer. The second wafer is affixed to the first wafer such that the second portion of the seal ring structure is on the first portion of the seal ring structure. The semiconductor device includes a trench structure comprising a first trench in the first wafer and a second trench in the second wafer, where the first trench and the second trench are on a same side of the seal ring structure.

Abstract: A method for forming a high electron mobility transistor is disclosed. A mesa structure having a channel layer and a barrier layer is formed on a substrate. The mesa structure has two first edges extending along a first direction and two second edges extending along a second direction. A passivation layer is formed on the substrate and the mesa structure. A first opening and a plurality of second openings connected to a bottom surface of the first opening are formed and through the passivation layer, the barrier layer and a portion of the channel layer. In a top view, the first opening exposes the two first edges of the mesa structure without exposing the two second edges of the mesa structure. A metal layer is formed in the first opening and the second openings thereby forming a contact structure.

Abstract: The present disclosure relates to a method and an associated process tool. The method includes generating electromagnetic radiation that is directed toward a perimeter of a pair of bonded workpieces and toward a radiation sensor that is arranged behind the perimeter of the pair of bonded workpieces. The electromagnetic radiation is scanned along a vertical axis. An intensity of the electromagnetic radiation that impinges on the radiation sensor is measured throughout the scanning. Measuring the intensity includes recording a plurality of intensity values of the electromagnetic radiation at a plurality of different positions along the vertical axis extending past top and bottom surfaces of the pair of bonded workpieces. A position of an interface between the pair of bonded workpieces is determined based on a maximum measured intensity value of the plurality of intensity values.

Abstract: Methods for fabricating semiconductor devices are provided. An exemplary method includes forming fins in a dense region and in an isolated region of a semiconductor substrate; performing a plasma dry etch process to remove a portion of at least one selected fin to form a first trench in the dense region and to remove a portion of at least one selected fin in the isolated region to form a second trench in the isolated region, wherein the plasma dry etch process includes: performing a passivation-oriented process and an etchant-oriented process; and controlling the passivation-oriented process and the etchant-oriented process to form the first trench with a desired first critical dimension and first depth and to form the second trench with a desired second critical dimension and second depth.

Abstract: A method is disclosed that includes performing a directional ion implantation process on a developed resist pattern to reduce roughness. A substrate can be tilted at a tilt angle with respect to the direction of an incoming ion beam. Ions can be directionally implanted at the tilt angle, along sidewall surfaces of the developed resist pattern to trim roughness from the sidewall surfaces. After implanting, the substrate can be rotated along the axis normal to a surface, and ions can then be directionally implanted at the tilt angle along the sidewall surfaces to further trim roughness from the sidewall surfaces of the developed resist pattern. The directional ion implantation process can be performed over a number of iterations, and during each iteration of the directional ion implantation process, the tilt angle can be adjusted so that the tilt angle is different than during previous iterations.

Abstract: A method for fabricating high electron mobility transistor (HEMT) includes the steps of: forming a buffer layer on a substrate; forming a barrier layer on the buffer layer; forming a hard mask on the barrier layer; performing an implantation process through the hard mask to form a doped region in the barrier layer and the buffer layer; removing the hard mask and the barrier layer to form a first trench; forming a gate dielectric layer on the hard mask and into the first trench; forming a gate electrode on the gate dielectric layer; and forming a source electrode and a drain electrode adjacent to two sides of the gate electrode.

Abstract: In an embodiment, a pattern transfer processing chamber includes a pattern transfer processing chamber and a loading area external to the pattern transfer processing chamber. The loading area is configured to transfer a wafer to or from the pattern transfer processing chamber. The loading area comprises a first region including a loadport, a second region including a load-lock between the first region and the pattern transfer processing chamber, and an embedded baking chamber configured to heat a patterned photoresist on the wafer.