A semiconductor device having favorable electrical characteristics is provided. The semiconductor device includes a first oxide; a first conductor and a second conductor over the first oxide; a first insulator over the first conductor; a second insulator over the second conductor; a third insulator over the first insulator and the second insulator; a second oxide positioned over the first oxide and between the first conductor and the second conductor; a fourth insulator over the second oxide; a third conductor over the fourth insulator; a fifth insulator in contact with a top surface of the third insulator, a top surface of the second oxide, a top surface of the fourth insulator, and a top surface of the third conductor; a fourth conductor embedded in an opening formed in the first insulator, the third insulator, and the fifth insulator and in contact with the first conductor; and a fifth conductor embedded in an opening formed in the second insulator, the third insulator, and the fifth insulator and in contact with the second conductor. The third insulator includes, in the vicinity of an interface with the fourth conductor and in the vicinity of an interface with the fifth conductor, a region having a higher nitrogen concentration than a different region of the third insulator.

A magnetic device for magnetic random access memory (MRAM), spin torque MRAM, or spin torque oscillator technology is disclosed wherein a magnetic tunnel junction (MTJ) with a sidewall is formed between a bottom electrode and a top electrode. A passivation layer that is a single layer or multilayer comprising one of B, C, or Ge, or an alloy thereof wherein the B, C, and Ge content, respectively, is at least 10 atomic % is formed on the MTJ sidewall to protect the MTJ from reactive species during subsequent processing including deposition of a dielectric layer that electrically isolates the MTJ from adjacent MTJs, and during annealing steps around 400? C. in CMOS fabrication. The single layer is about 3 to 10 Angstroms thick and may be an oxide or nitride of B, C, or Ge. The passivation layer is preferably amorphous to prevent diffusion of reactive oxygen or nitrogen species.

According to one embodiment, a semiconductor device includes a first semiconductor layer including a nitride semiconductor, a first electrode separated from the first semiconductor layer in a first direction, and a first insulating film including silicon and oxygen and being provided between the first semiconductor layer and the first electrode. The first insulating film has a first thickness in the first direction. The first insulating film includes a first position, and a distance between the first position and the first semiconductor layer is of the first thickness. A first hydrogen concentration of hydrogen at the first position is 2.510.sup.19 atoms/cm.sup.3 or less.

Oxide growth of a gate dielectric layer that occurs between processes used in the fabrication of a gate dielectric structure can be reduced. The reduction in oxide growth can be achieved by maintaining the gate dielectric layer in an ambient effective to mitigate oxide growth of the gate dielectric layer between at least two sequential process steps used in the fabrication the gate dielectric structure. Maintaining the gate dielectric layer in an ambient effective to mitigate oxide growth also improves the uniformity of nitrogen implanted in the gate dielectric.

A pattern is defined in a dielectric layer. The dielectric layer includes a low-k dielectric region and a high-k dielectric region. The high-k dielectric region includes a phase change material which is an alloy of tantalum and nitrogen and is a high-k insulator in a deposited state. The pattern includes a first set of features in the low-k dielectric region and a second set of features in the high-k dielectric region. A surface treatment process is performed on the phase change layer to produce a top surface layer having electrically conductive properties. A metal layer is deposited in the first and second set of features. Thus, a set of conductive lines is formed in the low-k dielectric region and a metal insulator metal capacitor in the high-k dielectric region.

A protective film forming method is provided. In the method, substantially an entire surface of a silicon-containing underfilm is terminated with fluorine by supplying a fluorine-containing gas to the silicon-containing underfilm formed on a substrate having a surface including a plurality of recesses and a flat surface provided between the adjacent recesses. A surface of the silicon-containing underfilm formed on the flat surface of the substrate is nitrided by supplying a nitriding gas converted to plasma to the silicon-containing underfilm terminated with fluorine such that a silicon adsorption site is formed on the surface of the silicon-containing underfilm formed on the flat surface of the substrate. A silicon-containing gas is adsorbed on the silicon adsorption site by supplying the silicon-containing gas to the silicon-containing underfilm.

Dipole engineering techniques are disclosed that incorporate dipole dopant and/or nitrogen into gate dielectrics (e.g., high-k dielectric layers thereof) to realize multi-threshold voltage transistor tuning of transistors. The dipole engineering techniques include (1) forming a dipole dopant source layer over gate dielectrics of some transistors, but not other transistors, (2) forming a mask over gate dielectrics of some transistors, but not other transistors, (3) performing a nitrogen-containing thermal drive-in process, and (4) removing the dipole dopant source layer and the mask after the nitrogen-containing thermal drive-in process. The nitrogen-containing thermal drive-in process diffuses nitrogen and dipole dopant (n-dipole dopant and/or p-dipole dopant) into unmasked gate dielectrics having the dipole dopant source layer formed thereon, nitrogen into unmasked gate dielectrics, and dipole dopant into masked gate dielectrics having the dipole dopant source layer formed thereon. Masked gate dielectrics without the dipole dopant source layer formed thereon remain undoped.

Methods and systems for selective silicon anti-reflective coating (SiARC) removal are described. An embodiment of a method includes providing a substrate in a process chamber, the substrate comprising: a resist layer, a SiARC layer, a pattern transfer layer, and an underlying layer. Such a method may also include performing a pattern transfer process configured to remove the resist layer and create a structure on the substrate, the structure comprising portions of the SiARC layer and the pattern transfer layer. The method may additionally include performing a modification process on the SiARC layer of the structure, the modification converting the SiARC layer into a porous SiARC layer. Further, the method may include performing a removal process of the porous SiARC layer of the structure, wherein the modification and removal processes of the SiARC layer are configured to meet target integration objectives.

A pattern is defined in a dielectric layer. The dielectric layer includes a low-k dielectric region and a high-k dielectric region. The high-k dielectric region includes a phase change material which is an alloy of tantalum and nitrogen and is a high-k insulator in a deposited state. The pattern includes a first set of features in the low-k dielectric region and a second set of features in the high-k dielectric region. A surface treatment process is performed on the phase change layer to produce a top surface layer having electrically conductive properties. A metal layer is deposited in the first and second set of features. Thus, a set of conductive lines is formed in the low-k dielectric region and a metal insulator metal capacitor in the high-k dielectric region.

A pattern is defined in a dielectric layer. The dielectric layer includes a low-k dielectric region and a high-k dielectric region. The high-k dielectric region includes a phase change material which is an alloy of tantalum and nitrogen and is a high-k insulator in a deposited state. The pattern includes a first set of features in the low-k dielectric region and a second set of features in the high-k dielectric region. A surface treatment process is performed on the phase change layer to produce a top surface layer having electrically conductive properties. A metal layer is deposited in the first and second set of features. Thus, a set of conductive lines is formed in the low-k dielectric region and a metal insulator metal capacitor in the high-k dielectric region.