An etching method according to one embodiment of the present disclosure includes step (a), step (b), step (c), step (d), and step (e). Step (a) provides a substrate that has a silicon-containing film which does not include oxygen and nitrogen, and a mask formed on the silicon-containing film. Step (b) etches the silicon-containing film with plasma generated from a first processing gas that includes a halogen-containing gas to form a recess portion. Step (c) forms an oxide film in the recess portion with plasma generated from a second processing gas that includes an oxygen-containing gas and a gas including carbon, hydrogen, and fluorine. Step (d) further etches the silicon-containing film with the plasma generated from the first processing gas after step (c). Step (e) repeatedly executes step (c) and step (d) a preset number of times.

A semiconductor device has a substrate and semiconductor layer formed over the substrate. A trench is formed through the semiconductor layer. An insulating material is disposed in the trench. A first column of semiconductor material having a first conductivity type extends through the semiconductor layer adjacent to the trench. A second column of semiconductor material having a second conductivity type extends through the semiconductor layer adjacent to the first column of semiconductor material. A first insulating layer is formed between the insulating material and a side surface of the trench. A source region is formed within the semiconductor layer. A gate region is formed adjacent to the insulating layer. A second insulating layer is formed between the gate region and source region. A conductive layer is formed over the semiconductor layer. The source region is coupled to the conductive layer.

Methods of singulating semiconductor die. Specific implementations may include: providing a semiconductor wafer including a plurality of die located on a first side of the semiconductor wafer where the plurality of die include a desired thickness. The method may include etching a plurality of trenches into the semiconductor wafer from the first side of the semiconductor wafer where the plurality of trenches is located adjacent to a perimeter of the plurality of die. A depth of the plurality of trenches may be greater than the desired thickness of the plurality of die. The method may also include mounting the first side of the semiconductor wafer to a tape, thinning a second side of the semiconductor wafer, exposing the plurality of trenches while thinning the second side, and singulating the plurality of die through exposing the plurality of trenches.

An element chip manufacturing method including: attaching a substrate via a die attach film (DAF) to a holding sheet; forming a protective film that covers the substrate; forming an opening in the protective film with a laser beam, to expose the substrate in the dicing region therefrom; exposing the substrate to a first plasma to etch the substrate exposed from the opening, so that a plurality of element chips are formed from the substrate and so that the DAF is exposed from the opening; exposing the substrate to a second plasma to etch the die attach film exposed from the opening, so that the DAF is split so as to correspond to the element chips; and detaching the element chips from the holding sheet, together with the split DAF. The DAF is larger than the substrate. The method includes irradiating the laser beam to the DAF protruding from the substrate.

Tin oxide films are used as spacers and hardmasks in semiconductor device manufacturing. In one method, tin oxide layer (e.g., spacer footing) needs to be selectively etched in a presence of an exposed silicon-containing layer, such as SiOC, SiON, SiONC, amorphous silicon, SiC, or SiN. In order to reduce damage to the silicon-containing layer the process involves passivating the silicon-containing layer towards a tin oxide etch chemistry, etching the tin oxide, and repeating passivation and etch in an alternating fashion. For example, passivation and etch can be each performed between 2-50 times. In one implementation, passivation is performed by treating the substrate with an oxygen-containing reactant, activated in a plasma, and the tin oxide etching is performed by a chlorine-based chemistry, such as using a mixture of Cl.sub.2 and BCl.sub.3.

Implementations of a semiconductor package may include a die; a first pad and a second pad, the first pad and the second pad each including a first layer and a second layer where the second layer may be thicker than the first layer. At least a first conductor may be directly coupled to the second layer of the first pad; at least a second conductor may be directly coupled to the second layer of the second pad; and an organic material may cover at least the first side of the die. The at least first conductor and the at least second conductor extend through openings in the organic material where a spacing between the at least first conductor and the at least second conductor may be wider than a spacing between the second layer of the first pad and the second layer of the second pad.

Embodiments disclosed herein generally relate to methods for controlling substrate outgassing such that hazardous gasses are eliminated from a surface of a substrate after a III-V epitaxial growth process or an etch clean process, and prior to additional processing. An oxygen containing gas is flowed to a substrate in a load lock chamber, and subsequently a non-reactive gas is flowed to the substrate in the load lock chamber. As such, hazardous gases and outgassing residuals are decreased and/or removed from the substrate such that further processing may be performed.

An element chip manufacturing method includes a preparation process of preparing a substrate which includes a first surface having an exposed bump and a second surface opposite to the first surface and includes a plurality of element regions defined by dividing regions, a bump embedding process of embedding at least a head top part of the bump into the adhesive layer, a mask forming process of forming a mask in the second surface. The method for manufacturing the element chip includes a holding process of arranging the first surface to oppose a holding tape supported on a frame and holding the substrate on the holding tape, a placement process of placing the substrate on a stage provided inside of a plasma processing apparatus through the holding tape, after the mask forming process and the holding process.

A method of plasma etching one or more features in a silicon substrate includes performing a main etch using a cyclical etch process in which a deposition step and an etch step are alternately repeated, and performing an over etch to complete the plasma etching of the features. The over etch includes one or more etch steps of a first kind and one or more etch steps of a second kind, each of the etch steps of the first and second kind include etching by ion bombardment of the silicon substrate. The ion bombardment during the one or more etch steps of the second kind has an inward inclination with respect to ion bombardment during the one or more etch steps of the first kind.

An etching method is provided for selectively etching a first region of silicon oxide with respect to a second region of silicon nitride by performing plasma processing on a target object including the first region and the second region. In the etch method, first, a plasma of a processing gas including a fluorocarbon gas is generated in a processing chamber where the target object is accommodated. Next, the plasma of the processing gas including the fluorocarbon gas is further generated in the processing chamber where the target object is accommodated. Next, the first region is etched by radicals of fluorocarbon contained in a deposit which is formed on the target object by the generation and the further generation of the plasma of the processing gas containing the fluorocarbon gas. A high frequency powers used for the plasma generation is smaller than a high frequency power used for plasma further generation.