Abstract: The present invention pertains to a semiconductor device microstructure, and to a method of forming that microstructure, which reduces or prevents junction spiking and to a method of forming that microstructure. In particular, a semiconductor contact microstructure comprises a feature which includes a silicon base and at least one sidewall extending upward from the silicon base. The sidewall includes a silicon portion in contact with the silicon base, where the height of the silicon portion of the sidewall above the silicon base is typically less than about 0.5 &mgr;m. The sidewall also includes at least one portion which comprises a first dielectric material which is in contact with (and typically extends upward from) the silicon portion of the sidewall. Overlying at least the silicon portion of the sidewall is a layer of a second dielectric material, preferably silicon oxide.

Abstract: The present invention pertains to a semiconductor device microstructure, and to a method of forming that microstructure, which reduces or prevents junction spiking and to a method of forming that microstructure. In particular, a semiconductor contact microstructure comprises a feature which includes a silicon base and at least one sidewall extending upward from the silicon base. The sidewall includes a silicon portion in contact with the silicon base, where the height of the silicon portion of the sidewall above the silicon base is typically less than about 0.5 &mgr;m. The sidewall also includes at least one portion which comprises a first dielectric material which is in contact with (and typically extends upward from) the silicon portion of the sidewall. Overlying at least the silicon portion of the sidewall is a layer of a second dielectric material, preferably silicon oxide.

Abstract: The present disclosure pertains to our discovery that depositing various film layers in a particular order using a combination of Ion Metal Plasma (IMP) and traditional sputter deposition techniques with specific process conditions results in a barrier layer structure which provides excellent barrier properties and allows for metal/conductor filling of contact sizes down to 0.25 micron and smaller without junction spiking. Specifically, the film layers are deposited on a substrate in the following order: (a) a first layer of a barrier metal (M), deposited by IMP sputter deposition; (b) a second layer of an oxygen-stuffed barrier metal (MOx), an oxygen-stuffed nitride of a barrier metal (MNOx), or a combination thereof; (c) a third layer of a nitride of a barrier metal (MNx), deposited by IMP sputter deposition of the barrier metal in the presence of nitrogen; and (d) a fourth, wetting layer of a barrier metal, deposited by traditional sputter deposition.

Abstract: The present disclosure pertains to our discovery that depositing various film layers in a particular order using a combination of Ion Metal Plasma (IMP) and traditional sputter deposition techniques with specific process conditions results in a barrier layer structure which provides excellent barrier properties and allows for metal/conductor filling of contact sizes down to 0.25 micron and smaller without junction spiking. Specifically, the film layers are deposited on a substrate in the following order: (a) a first layer of a barrier metal (M), deposited by IMP sputter deposition; (b) a second layer of an oxygen-stuffed barrier metal (MOx), an oxygen-stuffed nitride of a barrier metal (MNOx), or a combination thereof; (c) a third layer of a nitride of a barrier metal (MN.sub.x), deposited by IMP sputter deposition of the barrier metal in the presence of nitrogen; and (d) a fourth, wetting layer of a barrier metal, deposited by traditional sputter deposition.

Abstract: A coil shield assembly for an RF field coil in a plasma processing system includes a first shield positioned inside the coil. The first shield has a central opening substantially surrounding a central space of a processing chamber in which the plasma is maintained. At least one slot is formed in the first shield and extends therethrough. A barrier is positioned between the first shield and the coil and spaced apart from the first shield near the at least one slot. The slot permits an RF signal from the coil to couple with the plasma, and the first shield and the barrier are structured and arranged to prevent plasma ions or sputtered material from bombarding the coil by a direct path from the central space and through the at least one slot.

Abstract: The disadvantages heretofore associated with the prior art are overcome by the present invention of an improved target for a physical deposition (PVD) system. The improved target has a portion of the target side wall the overhangs and shadows the side wall of the target thus preventing material from depositing on the edge. To further reduce contaminant generation, the improved target is combined with an improved dark space shield having a first end and a second end, where the second end conventionally supports a collimator and the first end has an inner surface that is substantially vertical.

Abstract: The present invention is directed to a unique silicon based MOS transistor having an inverse-T refractory metal gate structure. The gate fabricated according to this invention comprises a main CVD tungsten portion and a lower sputtered tungsten portion outwardly extending from the bottom of the CVD portion such that a cross section of the gate appears as an inverted "T". A Cl.sub.2 /O.sub.2 plasma etch is used to etch the CVD tungsten layer and a chemical etch is used to etch the sputtered tungsten layer to form the gate electrode. It has been discovered that sputtered tungsten is more resistant to Cl.sub.2 /O.sub.2 reactive ion etch than is CVD tungsten. The sputtered tungsten layer acts as a shield to protect the underlying gate oxide layer from ion damage throughout the fabrication process.

Abstract: The present invention is directed to a unique method for fabricating a silicon based MOS transistor having an inverse-T refractory metal gate structure. The gate fabricated according to this invention comprises a main CVD tungsten portion and a lower sputtered tungsten portion outwardly extending from the bottom of the CVD portion such that a cross section of the gate appears as an inverted "T". A Cl.sub.2 /O.sub.2 plasma etch is used to etch the CVD tungsten layer and a chemical etch is used to etch the sputtered tungsten layer to form the gate electrode. It has been discovered that sputtered tungsten is more resistant to Cl.sub.2 /O.sub.2 reactive ion etch than is CVD tungsten. The sputtered tungsten layer acts as a shield to protect the underlying gate oxide layer from ion damage throughout the fabrication process.