The present disclosure provides a DNA-targeting RNA that comprises a targeting sequence and, together with a modifying polypeptide, provides for site-specific modification of a target DNA and/or a polypeptide associated with the target DNA. The present disclosure further provides site-specific modifying polypeptides. The present disclosure further provides methods of site-specific modification of a target DNA and/or a polypeptide associated with the target DNA The present disclosure provides methods of modulating transcription of a target nucleic acid in a target cell, generally involving contacting the target nucleic acid with an enzymatically inactive Cas9 polypeptide and a DNA-targeting RNA. Kits and compositions for carrying out the methods are also provided. The present disclosure provides genetically modified cells that produce Cas9; and Cas9 transgenic non-human multicellular organisms.

A treatment, structure and system are provided that modify the deposition process of a material that can occur over two differing materials. In an embodiment the deposition rates may be adjusted by the treatment to change the deposition rate of one of the materials to be more in line with the deposition rate of a second one of the materials. Also, the deposition rates may be modified to be different from each other, to allow for a more selective deposition over the first one of the materials than over the second one of the materials.

Methods and apparatuses for selective deposition of metal oxides on metal surfaces relative to dielectric surfaces are provided. Selective deposition is achieved by exposing metal and dielectric surfaces to a blocking reagent capable of forming a hydrolyzable bond with metal while forming a non-hydrolyzable bond with the dielectric, and dipping the surfaces in water to cleave the hydrolyzable bond and leave a blocked surface on the dielectric surface, followed by depositing metal oxide selectively on the metal surface relative to the dielectric surface. Blocking reagents are deposited by wet or dry techniques and may include an alkylaminosilane or alkylchlorosilane as examples.

The present disclosure provides a DNA-targeting RNA that comprises a targeting sequence and, together with a modifying polypeptide, provides for site-specific modification of a target DNA and/or a polypeptide associated with the target DNA. The present disclosure further provides site-specific modifying polypeptides. The present disclosure further provides methods of site-specific modification of a target DNA and/or a polypeptide associated with the target DNA The present disclosure provides methods of modulating transcription of a target nucleic acid in a target cell, generally involving contacting the target nucleic acid with an enzymatically inactive Cas9 polypeptide and a DNA-targeting RNA. Kits and compositions for carrying out the methods are also provided. The present disclosure provides genetically modified cells that produce Cas9; and Cas9 transgenic non-human multicellular organisms.

Methods and apparatuses for selective deposition of metal oxides on metal surfaces relative to dielectric surfaces are provided. Selective deposition is achieved by exposing metal and dielectric surfaces to a blocking reagent capable of forming a hydrolyzable bond with metal while forming a non hydrolyzable bond with the dielectric, and dipping the surfaces in water to cleave the hydrolyzable bond and leave a blocked surface on the dielectric surface, followed by depositing metal oxide selectively on the metal surface relative to the dielectric surface. Blocking reagents are deposited by wet or dry techniques and may include an alkylaminosilane or alkylchlorosilane as examples.

There is included (a) forming a protective film on a surface of a third base by supplying a processing gas to a substrate in which a first base containing no oxygen, a second base containing oxygen, and the third base containing no oxygen and no nitrogen are exposed on a surface of the substrate; (b) modifying a surface of the second base to be fluorine-terminated by supplying a fluorine-containing gas to the substrate after the protective film is formed on the surface of the third base; and (c) selectively forming a film on a surface of the first base by supplying a film-forming gas to the substrate after the surface of the second base is modified.

A method of forming a high-K dielectric cap layer on a semiconductor structure formed on a substrate includes depositing the high-K dielectric cap layer on the semiconductor structure, depositing a sacrificial silicon cap layer on the high-K dielectric cap layer, performing a post cap anneal process to harden and densify the as-deposited high-K dielectric cap layer, and removing the sacrificial silicon cap layer.

There is method of processing a substrate comprising: (a) providing the substrate with a first base containing no oxygen, a second base containing oxygen, and a third base containing no oxygen and no nitrogen on its surface, wherein a protective film is formed on a surface of the third base; (b) modifying a surface of the second base to be fluorine-terminated by supplying a fluorine-containing gas to the substrate in a state where the protective film is formed on the surface of the third base; and (c) forming a film on a surface of the first base by supplying a film-forming gas to the substrate in a state where the surface of the second base is modified.

A method of forming a high-κ dielectric cap layer on a semiconductor structure formed on a substrate includes depositing the high-κ dielectric cap layer on the semiconductor structure, depositing a sacrificial silicon cap layer on the high-κ dielectric cap layer, performing a post cap anneal process to harden and densify the as-deposited high-κ dielectric cap layer, and removing the sacrificial silicon cap layer.

Processing methods may be performed to produce semiconductor structures. The methods may include forming a silicon layer over a semiconductor substrate. The forming may include forming a silicon layer incorporating a dopant. The methods may include oxidizing a portion of the silicon layer while maintaining a portion of the silicon layer in contact with the semiconductor substrate. The oxidizing may drive a portion of the dopant through the silicon layer and into the semiconductor substrate.