Abstract: A semiconductor fabrication process includes forming a transistor gate overlying an SOI wafer having a semiconductor top layer over a buried oxide layer (BOX) over a semiconductor substrate. Source/drain trenches, disposed on either side of the gate, are etched into the BOX layer. Source/drain structures are formed within the trenches. A depth of the source/drain structures is greater than the thickness of the top silicon layer and an upper surface of the source/drain structures coincides approximately with the transistor channel whereby vertical overlap between the source/drain structures and the gate is negligible. The trenches preferably extend through the BOX layer to expose a portion of the silicon substrate. The source/drain structures are preferably formed epitaxially and possibly in two stages including an oxygen rich stage and an oxygen free stage. A thermally anneal between the two epitaxial stages will form an isolation dielectric between the source/drain structure and the substrate.

Abstract: One embodiment forms a gate dielectric layer over a substrate and then selectively deposits a first metal layer over portions of the gate dielectric layer in which a first device type will be formed. A second metal layer, different from the first metal layer, is formed over exposed portions of the gate dielectric layer in which a second device type will be formed. Each of the first and second device types will have different work functions because each will include a different metal in direct contact with the gate dielectric. In one embodiment, the selective deposition of the first metal layer is performed by ALD and with the use of an inhibitor layer which is selectively formed over the gate dielectric layer such that the first metal layer may be selectively deposited on only those portions of the gate dielectric layer which are not covered by the inhibitor layer.

Abstract: A method for forming at least a portion of a semiconductor device includes providing a semiconductor substrate, flowing a first precursor gas over the substrate to form a first metal-containing layer overlying the semiconductor substrate, and after completing said step of flowing the first precursor gas, flowing a first deuterium-containing purging gas over the first metal-containing layer to incorporate deuterium into the first metal-containing layer and to also purge the first precursor gas. The method may further include flowing a second precursor gas over the first metal-containing layer to react with the first metal-containing layer to form a metal compound-containing layer, and flowing a second deuterium-containing purging gas over the metal compound-containing layer to incorporate deuterium into the metal compound-containing layer and to also purge the second precursor gas.

Abstract: A method of making a high quality thin dielectric layer includes annealing a substrate and a base oxide layer overlying a top surface of the substrate at a first temperature in a first ambient and annealing the substrate and base oxide layer at a second temperature in a second ambient subsequent to the first anneal. The first ambient includes an inert gas ambient selected from the group consisting of a nitrogen, argon, and helium ambient. Prior to the first anneal, the base oxide layer has an initial thickness and an initial density. The first anneal causes a first density and thickness change in the base oxide layer from the initial thickness and density to a first thickness and density, with no incorporation of nitrogen, argon, or helium of the ambient within the base oxide layer. The first thickness is less than the initial thickness and the first density is greater than the initial density.

Abstract: A metal-containing semiconductor layer having a high dielectric constant is formed with a method that avoids inclusion of contaminant elements that reduce dielectric constant of metals. The metal-containing semiconductor layer is formed overlying a substrate in a chamber. A precursor is introduced to deposit at least a portion of the metal-containing semiconductor layer. The precursor contains one or more elements that, if allowed to deposit in the metal-containing layer, would become impurity elements. A reactant gas is used to purify the metal-containing layer by removing impurity elements from the metal-containing layer which were introduced into the chamber by the precursor.

Abstract: A process for forming a semiconductor structure includes forming a gate dielectric overlying a substrate, a conductive gate electrode overlying the gate dielectric, a barrier layer overlying and in physical contact with the conductive gate electrode, and an organic anti-reflective coating (ARC) layer overlying and in physical contact with the barrier layer.

Abstract: An antireflective coating (ARC) layer for use in the manufacture of a semiconductor device. The ARC layer has a bottom portion that has a lower percentage of silicon than a portion of the ARC layer located above it. The ARC layer is formed on a metal layer, wherein the lower percentage of silicon of the ARC layer inhibits the unwanted formation of suicides at the metal layer/ARC layer interface. In some embodiments, the top portion of the ARC layer has a lower percentage of silicon than the middle portion of the ARC layer, wherein the lower percentage of silicon at the top portion may inhibit the poisoning of a photo resist layer on the ARC layer. In one embodiment, the percentage of silicon can be increased or decreased by decreasing or increasing the ratio of the flow rate of a nitrogen containing gas with respect to the flow rate of a silicon containing gas during a deposition process.

Abstract: A semiconductor device has a P channel gate stack comprising a first metal type and a second metal type over the first metal type and an N channel gate stack comprising the second metal type in direct contact with a gate dielectric/etch stop layer stack. The N channel gate stack and the P channel gate stack are etched by a dry etch. Either the gate dielectric or etch stop can be in contact with the substrate. The etch stop layer prevents the dry etch of the first and second metal layers from etching through the gate dielectric and gouging the underlying substrate.

Abstract: A semiconductor fabrication process includes forming first and second transistors over first and second well regions, respectively where the first transistor has a first gate dielectric and the second transistor has a second gate dielectric different from the first gate dielectric. The first transistor has a first gate electrode and the second transistor has a second gate electrode. The first and second gate electrodes are the same in composition. The first gate dielectric and the second gate dielectric may both include high-K dielectrics such as Hafnium oxide and Aluminum oxide. The first and second gate electrodes both include a gate electrode layer overlying the respective gate dielectrics. The gate electrode layer is preferably either TaSiN and TaC. The first and second gate electrodes may both include a conductive layer overlying the gate electrode layer. In one such embodiment, the conductive layer may include polysilicon and tungsten.

Abstract: Heating a reaction chamber or other apparatus in the absence of product wafers to a “curing” temperature above a deposition temperature between the deposition of a film on a first set of semiconductor product wafers and the deposition of a film on a second set of semiconductor product wafers. In some embodiments, a boat with filler wafers is in the reaction chamber when the reaction chamber is heated to the curing temperature. In some examples, the films are deposited by a low pressure chemical vapor deposition (LPCVD) process. With some processes, if the deposition of a film on product wafers is at a temperature below a certain temperature, the film deposited with the product wafer on a boat, filler wafers, and/or other structures in the reaction chamber can cause contamination of product wafers subsequently deposited with a film in the presence of the boat and filler wafers.

Abstract: A method of forming a conductive structure having a length that is less than the length define by photolithographic patterning. A silicon layer (12) is formed in a MeOx dielectric layer (11) is photolithographically patterned to a predetermined first length. A metal layer (31) is formed conformally to at least the sidewalls of the silicon layer and then is reacted with the silicon to form a metal silicide (41). In particular, metal silicide abutments (411,412) are formed contiguous to sidewalls (421,422) of a reduced conductor (42). The remaining metal layer and the metal silicide are etched away, resulting in a conductor having predetermined second length that is less than the predetermined first length.

Abstract: A method of forming a conductive structure having a length that is less than the length defined by photolithographic patterning. A silicon layer (12) is formed in a MeOx dielectric layer (11). The silicon layer is photolithographically patterned to a predetermined first length. A metal layer (31) is formed conformally to at least the sidewalls of the silicon layer and then is reacted with the silicon to form a metal silicide (41). In particular, metal silicide abutments (411,412) are formed contiguous to sidewalls (421,422) of a reduced conductor (42). The remaining metal layer and the metal silicide are etched away, resulting in a conductor having predetermined second length that is less than the predetermined first length.

Abstract: A semiconductor wafer processing apparatus (10) includes a front-end robot (28), a wafer scrubber/dryer (30), a moisture detector (34) and a load/lock chamber (38, 40). The front-end robot (28) moves a wafer to be processed between the wafer cassette (21-24), the wafer scrubber (30), the moisture detector (34) and the load/lock chamber (38, 40). Optionally, the load/lock chamber (38, 40) may include an additional moisture detector. The load/lock chamber (38, 40) functions as an interface to a vacuum processing chamber (50, 52, 54) for performing various deposition processing steps where introduction of moisture would be destructive to the wafer.

Abstract: A semiconductor device has a P channel gate stack comprising a first metal type and a second metal type over the first metal type and an N channel gate stack comprising the second metal type in direct contact with the a gate dielectric. The N channel gate stack and a portion of the P channel gate stack are etched by a dry etch. The etch of P channel gate stack is completed with a wet etch. The wet etch is very selective to the gate dielectric and to the second metal type so that the N channel transistor is not adversely effected by completing the etch of the P channel gate stack.

Abstract: An antireflective coating (ARC) layer for use in the manufacture of a semiconductor device. The ARC layer has a bottom portion that has a lower percentage of silicon than a portion of the ARC layer located above it. The ARC layer is formed on a metal layer, wherein the lower percentage of silicon of the ARC layer inhibits the unwanted formation of suicides at the metal layer/ARC layer interface. In some embodiments, the top portion of the ARC layer has a lower percentage of silicon than the middle portion of the ARC layer, wherein the lower percentage of silicon at the top portion may inhibit the poisoning of a photo resist layer on the ARC layer. In one embodiment, the percentage of silicon can be increased or decreased by decreasing or increasing the ratio of the flow rate of a nitrogen containing gas with respect to the flow rate of a silicon containing gas during a deposition process.

Abstract: Heating a reaction chamber or other apparatus in the absence of product wafers to a “curing” temperature above a deposition temperature between the deposition of a film on a first set of semiconductor product wafers and the deposition of a film on a second set of semiconductor product wafers. In some embodiments, a boat with filler wafers is in the reaction chamber when the reaction chamber is heated to the curing temperature. In some examples, the films are deposited by a low pressure chemical vapor deposition (LPCVD) process. With some processes, if the deposition of a film on product wafers is at a temperature below a certain temperature, the film deposited with the product wafer on a boat, filler wafers, and/or other structures in the reaction chamber can cause contamination of product wafers subsequently deposited with a film in the presence of the boat and filler wafers.

Abstract: Using plating, metal gates for N channel and P channel transistors are formed of different materials to achieve the appropriate work function for these N and P channel transistors. The plating is achieved with a seed layer consistent with the growth of the desired layer. The preferred materials are selected from the platinum metals, which comprise ruthenium, ruthenium oxide, iridium, palladium, platinum, nickel, osmium, and cobalt. These are attractive metals because they are relatively high conductivity, can be plated, and provide a good choice of work functions for forming P and N channel transistors.

Abstract: A metal gate structure is formed by depositing a gate dielectric, a gate electrode, a stop layer, and a metal layer within a gate trench and removing the portions of the layers that lie outside the gate trench. A first polish or etch process is used to remove a portion of the metal layer selective to the stop layer. A second polish or etch process is used to remove portions of the gate dielectric, the gate electrode, the stop layer and the metal layer which lie outside the gate trench after the first polish or etch process. The resulting structure increases the uniformity and non-planarity of the top surface of the metal gate structure.

Abstract: Insulating layers between transistors that are very close together may have voids. When contacts are formed in these areas between these close transistors, the contact hole is formed at the void location. These voids may extend between the contact locations that are close together so that the deposition of the conductive material into these contact holes may extend sufficiently into the void to short two such contacts. This is prevented by placing a liner in the contact hole, which constricts the void size in the contact hole, prior to depositing the conductive material. This restricts ingress of conductive material into the void. This prevents the void from being an unwanted conduction path between two contacts that are in close proximity. The bottoms of the contact holes are etched to remove the liner prior to depositing the conductive material.

Abstract: A first metal-containing material (22) is formed over a semiconductor device substrate (10). A second metal-containing material (32) is formed over the first metal containing material (22). The combination of the second metal-containing material (32) formed over the first metal-containing material (22) forms a metal stack (34). The metal stack (34) is annealed and a post-anneal stress of the metal stack (34) is less than an individual post-anneal stress of either one of the first conductive film (22) or the second conductive film (32).