Embodiments of the present invention provide an apparatus and methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications. In one embodiment, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

Embodiments of the present invention provide an apparatus and methods for depositing a dielectric material using RF bias pulses along with remote plasma source deposition for manufacturing semiconductor devices, particularly for filling openings with high aspect ratios in semiconductor applications. In one embodiment, a method of depositing a dielectric material includes providing a gas mixture into a processing chamber having a substrate disposed therein, forming a remote plasma in a remote plasma source and delivering the remote plasma to an interior processing region defined in the processing chamber, applying a RF bias power to the processing chamber in pulsed mode, and forming a dielectric material in an opening defined in a material layer disposed on the substrate in the presence of the gas mixture and the remote plasma.

A coating apparatus includes a chamber body having a reaction chamber, a supporting rack, a monomer discharge source and a plasma generation source. The supporting rack has a supporting area for supporting the substrate. The monomer discharge source has a discharge inlet for introducing a coating forming material into the reaction chamber. The plasma generation source is arranged for exciting the coating forming material, wherein the supporting area of the supporting rack is located at a position between the monomer discharge source and the plasma generation source, so that the coating is evenly formed on the surface of the substrate, and the deposition velocity is increased.

A coating apparatus includes a chamber body having a reaction chamber, a supporting rack, a monomer discharge source and a plasma generation source. The supporting rack has a supporting area for supporting the substrate. The monomer discharge source has a discharge inlet for introducing a coating forming material into the reaction chamber. The plasma generation source is arranged for exciting the coating forming material, wherein the supporting area of the supporting rack is located at a position between the monomer discharge source and the plasma generation source, so that the coating is evenly formed on the surface of the substrate, and the deposition velocity is increased.

A method and a device for forming a highly dielectric metal oxide layer. The method includes repeatedly causing a plasma-off period and a plasma-on period while an organic metal compound and an oxidizing agent are continuously injected into a chamber. One cycle includes one plasma-off period and one plasma-on period. During the plasma-off period, a physical and chemical adsorption layer including an organic metal compound and a plurality of atomic layers is formed on a substrate. During the plasma-on period, a metal oxide layer that is thicker than two atomic layers is formed by a chemical reaction of metal atoms in the physical and chemical adsorption layer and oxygen atoms in the oxidizing agent.

A method and a device for forming a highly dielectric metal oxide layer. The method includes repeatedly causing a plasma-off period and a plasma-on period while an organic metal compound and an oxidizing agent are continuously injected into a chamber. One cycle includes one plasma-off period and one plasma-on period. During the plasma-off period, a physical and chemical adsorption layer including an organic metal compound and a plurality of atomic layers is formed on a substrate. During the plasma-on period, a metal oxide layer that is thicker than two atomic layers is formed by a chemical reaction of metal atoms in the physical and chemical adsorption layer and oxygen atoms in the oxidizing agent.

A plasma processing apparatus is provided including a radio frequency power source; a direct current power source; a chamber enclosing a process volume; and a substrate support assembly disposed in the process volume. The substrate support assembly includes a substrate support having a substrate supporting surface; an electrode disposed in the substrate support; and an interconnect assembly coupling the radio frequency power source and the direct current power source with the electrode.

A plasma processing apparatus is provided including a radio frequency power source; a direct current power source; a chamber enclosing a process volume; and a substrate support assembly disposed in the process volume. The substrate support assembly includes a substrate support having a substrate supporting surface; an electrode disposed in the substrate support; and an interconnect assembly coupling the radio frequency power source and the direct current power source with the electrode.

A method of plasma processing includes generating a first sequence of source power pulses, generating a second sequence of bias power pulses, combining the bias power pulses of the second sequence with the source power pulses of the first sequence to form a combined sequence of alternating source power pulses and bias power pulses, and, using the combined sequence, generating a plasma comprising ions and processing a substrate by delivering the ions to a major surface of the substrate.

The present invention resides in the unifying idea of synchronizing a positive voltage pulse supplied to an electrically conductive or ferromagnetic tube and a exciting negative voltage pulse on a hollow cathode induced on the background of a high-frequency capacitive discharge.

In one embodiment, the invention relates to a method of generating low-temperature plasma in a vacuum chamber comprising a hollow cathode and an electrode, the method comprising the step of igniting the pulsed DC discharge in the hollow cathode wherein the positive voltage pulse at least partially overlaps with the negative voltage pulse, and the positive voltage pulse at least partially overlaps with the negative voltage pulse on the hollow cathode.

In another embodiment, the present invention relates to a method of coating the inner walls of hollow tubes which utilizes the above-mentioned low-temperature plasma generation process.

In another embodiment, the invention relates to a low-temperature plasma generating device comprising a hollow cathode located in the vacuum chamber, a RF plasma source, a pulse DC burst source, and a bipolar pulse source.

In another embodiment, an object of the invention is an apparatus adapted to coat the inner sides of hollow tubes comprising a low-temperature plasma generating device.