A method for etching a dielectric layer covering a top and a flank of a three-dimensional structure, this method including a first etching of the dielectric layer, including a first fluorine based compound, a second compound taken from SiwCl(2w+2) and SiwF(2w+2), oxygen, this first etching being carried out to form a first protective layer on the top and form a second protective layer on the dielectric layer, a second etching configured to remove the second protective layer while retaining a portion of the first protective layer, the first and second etchings being repeated until removing the dielectric layer located on the flank of the structure. The second etching can be carried out by hydrogen-based plasma.

According to the invention there is provided a method of filling one or more gaps created during manufacturing of a feature on a substrate by providing a deposition method comprising; introducing a first reactant to the substrate with a first dose, thereby forming no more than about one monolayer by the first reactant; introducing a second reactant to the substrate with a second dose. The first reactant is introduced with a sub saturating first dose reaching only a top area of the surface of the one or more gaps and the second reactant is introduced with a saturating second dose reaching a bottom area of the surface of the one or more gaps. A third reactant may be provided to the substrate in the reaction chamber with a third dose, the third reactant reacting with at least one of the first and second reactant.

A method of processing a substrate that includes: loading the substrate having a raised feature with at least two sidewalls exposed in a processing chamber; depositing a first layer over the substrate to cover a first portion of the two sidewalls; depositing a second layer over the first layer to cover a second portion of the two sidewalls; depositing a third layer over the second layer and the raised feature to cover a third portion of the sidewalls and a top surface of the raised feature; performing an anisotropic dry etching that removes portions of the second layer and the third layer, a remainder of the second layer forming a second sidewall spacer and a remainder of the third layer forming a third sidewall spacer; and performing an isotropic etching that selectively removes the second sidewall spacer to expose portions of the sidewalls of the raised feature.

There is provided a configuration that includes: a first gas supply line configured to be capable of controlling a flow rate of a first precursor gas, which is generated by a first raw material, by a flow rate controller, and supplying the first precursor gas into the process chamber; and a second gas supply line configured to be capable of supplying a second precursor gas, which is generated by a second raw material, into the process chamber, wherein a flow rate of the second precursor gas is determined based on a pressure difference between a primary-side pressure of the flow rate controller installed at the first gas supply line and a supply pressure of the second precursor gas from the second gas supply line into the process chamber.

Capacitive couplings in a direct-bonded interface for microelectronic devices are provided. In an implementation, a microelectronic device includes a first die and a second die direct-bonded together at a bonding interface, a conductive interconnect between the first die and the second die formed at the bonding interface by a metal-to-metal direct bond, and a capacitive interconnect between the first die and the second die formed at the bonding interface. A direct bonding process creates a direct bond between dielectric surfaces of two dies, a direct bond between respective conductive interconnects of the two dies, and a capacitive coupling between the two dies at the bonding interface. In an implementation, a capacitive coupling of each signal line at the bonding interface comprises a dielectric material forming a capacitor at the bonding interface for each signal line. The capacitive couplings result from the same direct bonding process that creates the conductive interconnects direct-bonded together at the same bonding interface.

The present disclosure generally provides methods. The methods include exposing a substrate in a processing chamber to a deposition precursor to form a first film. The first film having a first dielectric constant, a first leakage current, a first breakdown voltage, and a first hardness. The first film is exposed to a reactive precursor to form a second film. The second film having a second dielectric constant, a second leakage current, a second breakdown voltage, and a second hardness, wherein the reactive precursor comprises an oxygenated precursor. The second film is exposed to a UV light source to form a third film. The third film having a third dielectric constant, a third leakage current, a third breakdown voltage, and a third hardness.

A substrate processing method according to the present invention incudes: a preparation step of preparing a substrate in which at least a first surface containing silicon oxide and a second surface containing silicon or a silicon compound other than silicon oxide are exposed; a surface modification step of forming an etching selectivity imparting film on at least a part of the first surface and at least a part of the second surface by a silylation treatment of bringing a silylating agent into contact with the first surface and the second surface; and an etching step of selectively carrying out an etching treatment on the second surface with respect to the first surface using an etching agent after the surface modification step.

A film forming method of forming an oxide film, which contains at least a predetermined element and oxygen, on a substrate, includes: (a) supplying a first raw material gas, which contains the predetermined element, to the substrate; (b) supplying a second raw material gas, which contains the predetermined element, contains a bond between the predetermined element and oxygen and a bond between the predetermined element and a hydroxyl group, and is different from the first raw material gas, to the substrate; and (c) repeating one cycle a plurality of times, the one cycle including (a) and (b).

There is provided a technique that includes forming a film on at least one substrate by performing a cycle a predetermined number of times, the cycle including non-simultaneously performing: (a) performing a first set a number of times, the first set including non-simultaneously performing: supplying a precursor to the at least one substrate from at least one first ejecting hole of a first nozzle arranged along a substrate arrangement direction of a substrate arrangement region where the at least one substrate is arranged; and supplying a reactant to the at least one substrate; and (b) performing a second set a number of times, the second set including non-simultaneously performing: supplying the precursor to the at least one substrate from at least one second ejecting hole of a second nozzle arranged along the substrate arrangement direction of the substrate arrangement region; and supplying the reactant to the at least one substrate.

A method of processing a substrate is provided. The substrate includes an etching target region and a patterned region. The patterned region is provided on the etching target region. In the method, an organic film is formed on a surface of the substrate. Subsequently, the etching target region is etched by plasma generated from a processing gas. The organic film is formed in a state that the substrate is placed in a processing space within a chamber. When the organic film is formed, a first gas containing a first organic compound is supplied toward the substrate, and then, a second gas containing a second organic compound is supplied toward the substrate. An organic compound constituting the organic film is generated by polymerization of the first organic compound and the second organic compound.