A method of fabricating a gate with a mini field plate includes forming a dielectric passivation layer over an epitaxy layer on a substrate, coating the dielectric passivation layer with a first resist layer, etching the first resist layer and the dielectric passivation layer to form a first opening in the dielectric passivation layer, removing the first resist layer, and forming a tri-layer gate having a gate foot in the first opening, a gate neck extending from the gate foot, and a gate head extending from the gate neck. The gate foot has a first width, and the gate neck has a second width that is wider than the first width. The gate neck extends for a length over the dielectric passivation layer on both sides of the first opening. The gate head has a third width wider than the second width of the gate neck.

Provided is a manufacturing method of a semiconductor structure, including: providing a substrate; forming a first mask layer having a first mask pattern on the substrate, and etching the substrate by using the first mask layer as a mask to form active regions; forming several discrete bitlines on the active regions; forming a sacrificial layer between adjacent bitlines; forming a second mask layer having a second mask pattern on the sacrificial layer, the first mask pattern and the second mask pattern being complementary to each other; and etching the sacrificial layer by using the second mask layer and the bitlines as masks to form a plurality of contact structures. The embodiment of the present disclosure is beneficial to reducing the manufacturing cost of the semiconductor structure.

Methods and related apparatus for depositing an ashable hard mask (AHM) on a substrate include pulsing a low frequency radio frequency component at a high power. Pulsing low frequency power may be used to increase the selectivity or reduce the stress of an AHM. The AHM may then be used to etch features into underlying layers of the substrate.

A resist underlayer film-forming composition contains: (A) a compound having a partial structure represented by Formula (1). In Formula (1), R.sub.1 and R.sub.2 each denote a hydrogen atom, an alkyl group having 1-10 carbon atoms or an aryl group having 6-40 carbon atoms, X denotes an alkyl group having 1-10 carbon atoms, a hydroxyl group, an alkoxy group having 1-10 carbon atoms, an alkoxycarbonyl group having 1-10 carbon atoms, a halogen atom, a cyano group, a nitro group or a combination of these, Y denotes a direct bond, an ether bond, a thioether bond or an ester bond, n is an integer between 0 and 4, and * denotes a site of bonding to a residue of compound (A)); and a solvent.

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A field effect transistor includes: a semiconductor region including a first inactive region, an active region, and a second inactive region arranged side by side in a first direction; a gate electrode, a source electrode, and a drain electrode on the active region; a gate pad on the first inactive region; a gate guard on and in contact with the semiconductor region, the gate guard being apart from the gate pad and located between an edge on the first inactive region side of the semiconductor region and the gate pad; a drain pad on the second inactive region; a drain guard on and in contact with the semiconductor region, the drain guard being apart from the drain pad and located between an edge on the second inactive region side of the semiconductor region and the drain pad; and a metal film electrically connected to the gate guard.

A method for forming openings in an underlayer includes: forming a photoresist layer on an underlayer formed on a substrate; exposing the photoresist layer; forming photoresist patterns by developing the exposed photoresist layer, the photoresist patterns covering regions of the underlayer in which the openings are to be formed; forming a liquid layer over the photoresist patterns; after forming the liquid layer, performing a baking process so as to convert the liquid layer to an organic layer in a solid form; performing an etching back process to remove a portion of the organic layer on a level above the photoresist patterns; removing the photoresist patterns, so as to expose portions of the underlayer by the remaining portion of the organic layer; forming the openings in the underlayer by using the remaining portion of the organic layer as an etching mask; and removing the remaining portion of the organic layer.

A method for forming a semiconductor substrate arrangement includes: forming a mask on a semiconductor substrate, the semiconductor substrate including and a metallization layer arranged on an insulation layer, the metallization layer arranged between the mask and insulation layer; forming a layer of electrically conductive coating on the metallization layer, the electrically conductive coating formed in at least one opening of the mask on regions of the metallization layer that are not covered by the mask; and after forming the electrically conductive coating, removing the mask. Forming the mask includes either applying an even layer of material on the metallization layer, or applying the material of the mask on the metallization layer such that the thickness of the mask in a region adjacent to edges of the mask is greater than the thickness of the regions of the mask further away from the edges.

A thin film transistor is provided and includes an active layer, a source electrode, a drain electrode, a gate electrode and a gate electrode insulating layer, the active layer includes a source electrode region, a drain electrode region and a channel region, the source electrode region and the drain electrode region include a first metal material, and the channel region includes a semiconductor material made from oxidation of the first metal material.

Methods for selective deposition, and structures thereof, are provided. Material is selectively deposited on a first surface of a substrate relative to a second surface of a different material composition. A passivation layer is selectively formed from vapor phase reactants on the first surface while leaving the second surface without the passivation layer. A layer of interest is selectively deposited from vapor phase reactants on the second surface relative to the passivation layer. The first surface can be metallic while the second surface is dielectric, or the second surface is dielectric while the second surface is metallic. Accordingly, material, such as a dielectric, can be selectively deposited on either metallic or dielectric surfaces relative to the other type of surface using techniques described herein. Techniques and resultant structures are also disclosed for control of positioning and shape of layer edges relative to boundaries between underlying disparate materials.

A method for manufacturing a semiconductor device includes steps of forming a protective film on a semiconductor substrate, forming a resist film on the protective film such that the resist film includes a region where the resist film becomes thicker from a drain electrode to a source electrode, forming a first opening in the resist film by irradiating the resist film in the region with an electron beam and developing the resist film, forming a second opening that exposes an upper surface of semiconductor substrate by removing the protective film using the resist film on which the first opening is formed as a mask, forming a third opening in the resist film by further developing the resist film after forming the second opening, the third opening being formed by expanding the first opening toward the drain electrode, and forming a gate electrode in the second and the third openings.