The present disclosure provides systems and methods for processing channel structures of substrates that include positioning the substrate in a first processing chamber having a first processing volume. The substrate includes a channel structure with high aspect ratio features having aspect ratios greater than about 20:1. The method includes forming a silicon-containing layer over the channel structure to a hydrogen-or-deuterium plasma in the first processing volume at a flow rate of about 10 sccm to about 5000 sccm. The substrate is maintained at a temperature of about 100° C. to about 1100° C. during the exposing, the exposing forming a nucleated substrate. Subsequent to the exposing a thermal anneal operation is performed on the substrate.

A method of selectively transferring micro devices from a donor substrate to contact pads on a receiver substrate. Micro devices being attached to a donor substrate with a donor force. The donor substrate and receiver substrate are aligned and brought together so that selected micro devices meet corresponding contact pads. A receiver force is generated to hold selected micro devices to the contact pads on the receiver substrate. The donor force is weakened and the substrates are moved apart leaving selected micro devices on the receiver substrate. Several methods of generating the receiver force are disclosed, including adhesive, mechanical and electrostatic techniques.

A method for fabricating a semiconductor device includes: forming a transistor in a semiconductor substrate; forming a capacitor including a hydrogen-containing top electrode over the transistor; and performing an annealing process for hydrogen passivation after the capacitor is formed.

A mask material for plasma dicing, which is used in a plasma step, whose surface roughness Rz at the surface side that does not touch with an adherend is from 0.1 μm to 1.5 μm; a mask-integrated surface protective tape; and a method of producing a semiconductor chip.

A method for forming semiconductor devices includes attaching a glass structure to a wide band-gap semiconductor wafer having a plurality of semiconductor devices. The method further includes forming at least one pad structure electrically connected to at least one doping region of a semiconductor substrate of the wide band-gap semiconductor wafer, by forming electrically conductive material within at least one opening extending through the glass structure.

Methods of doping a semiconductor material are disclosed. Some embodiments provide for conformal doping of three dimensional structures. Some embodiments provide for doping with high concentrations of boron for p-type doping.

Methods of doping a semiconductor material are disclosed. Some embodiments provide for conformal doping of three dimensional structures. Some embodiments provide for doping with high concentrations of boron for p-type doping.

The present application provides a method of fabricating a light-emitting diode (LED) display panel, including the following steps: forming an LED substrate including a first substrate, an LED chip disposed on the first substrate, and a first electrode disposed on the LED chip; forming a driving substrate including a second substrate and a second electrode disposed on the second substrate; activating surfaces of the first electrode and the second electrode; aligning and pre-bonding the first electrode with the second electrode; and bonding the first electrode and the second electrode.

A plasma processing apparatus, including a processing; a first radio frequency power source; a sample stage on which the sample is placed; a second radio frequency power; and a control device configured to control, when the second radio frequency power source is controlled based on a change in a plasma impedance, which is generated when a first gas that is a gas for a first step is switched to a second gas that is a gas for a second step, such that the second radio frequency power is changed from a value of the second radio frequency power in the first step to a value of the second radio frequency power in the second step, and a supply time of the first gas such that a supply time of the second radio frequency power in the first step is substantially equal to a time of the first step.

A p-n diode includes a first electrode, a n-GaN layer on the first electrode, a p-GaN layer on the n-GaN layer, and a second electrode on a first portion of the p-GaN layer. A region of the p-GaN layer surrounding the electrode is a passivated region. Treating a GaN power device having a p-GaN layer includes covering a portion of the p-GaN layer with a metal layer, exposing the p-GaN layer to a hydrogen plasma, and thermally annealing the p-GaN layer, thereby passivating a region of the p-GaN layer proximate the metal layer.