Abstract: The present disclosure provides a semiconductor device that includes a semiconductor substrate having a first region and a second region, a pMOS transistor formed over the first region and an nMOS formed over the second region. The pMOS transistor has a gate structure that includes: an interfacial layer formed over the substrate; a AlOx layer formed over the interfacial layer; and a metal layer including Mo or W formed over the AlOx layer. The nMOS transistor has a gate structure that includes: the interfacial layer formed over the substrate; a DyOx layer formed over the interfacial layer; and the metal layer including Mo or W formed over the DyOx layer.

Abstract: The present disclosure provides a semiconductor device that includes a semiconductor substrate having a first region and a second region, a pMOS transistor formed over the first region and an nMOS formed over the second region. The pMOS transistor has a gate structure that includes: an interfacial layer formed over the substrate; a AlOx layer formed over the interfacial layer; and a metal layer including Mo or W formed over the AlOx layer. The nMOS transistor has a gate structure that includes: the interfacial layer formed over the substrate; a DyOx layer formed over the interfacial layer; and the metal layer including Mo or W formed over the DyOx layer.

Abstract: In the method for manufacturing a semiconductor device (100), which comprises a semiconducting body (1) having a surface (2) with a source region (3) and a drain region (4) defining a channel direction (102) and a channel region (101), a first stack (6) of layers on top of the channel region (101), the first stack (6) comprising, in this order, a tunnel dielectric layer (11), a charge storage layer (10) for storing an electric charge and a control gate layer (9), and a second stack (7) of layers on top of the channel region (101) directly adjacent to the first stack (6) in the channel direction (102), the second stack (7) comprising an access gate layer (14) electrically insulated from the semiconducting body (1) and from the first stack (6), initially a first sacrificial layer (90) is used, which is later replaced by the control gate layer (9).

Abstract: Consistent with an example embodiment, a method of manufacturing a semiconductor device comprises MOS transistors having gate electrodes formed in a number of metal layers deposited upon one another. Active silicon regions having a layer of a gate dielectric and field-isolation regions insulating these regions from each other are formed in a silicon body. Then, a layer of a first metal is deposited in which locally, in a part of the active regions, nitrogen is introduced. On the layer of the first metal, a layer of a second metal is then deposited, after which the gate electrodes are etched in the metal layers. Before nitrogen is introduced into the first metal layer, an auxiliary layer of a third metal permeable to nitrogen is deposited an the first metal layer. Thus, the first metal layer can be nitrided locally without the risk of damaging the underlying gate dielectric.

Abstract: A semiconductor device, fabricated by a method, having a semiconductor structure with a silicon region which forms at least one connection region in and/or on a surface of a substrate is disclosed. In one embodiment, the method includes i) forming, at least at the silicon region, a metal cluster layer from a first metal, such that, in the metal cluster layer, metal clusters alternate with sites where there are no metal clusters, the first metal being a non-siliciding metal at predetermined conditions, ii) depositing a metal layer of a second metal on top of the metal cluster layer, the second metal being a siliciding metal and iii) carrying out at least one heat treatment at the predetermined conditions on the second metal layer so as to form metal silicide through reaction of the second metal with the silicon region, wherein atoms of the first metal are displaced in a direction substantially perpendicular to the surface of the substrate.

Abstract: The invention relates to a method for fabricating a semiconductor device having a semiconductor body that comprises a first semiconductor structure having a dielectric layer and a first conductor, and a second semiconductor structure having a dielectric layer and a second conductor, that part of the first conductor which adjoins the dielectric layer having a work function different from the work function of the corresponding part of the second conductor. In one embodiment of the invention, after the dielectric layer has been applied to the semiconductor body, a metal layer is applied to the said dielectric layer, and then a silicon layer is deposited on the metal layer and is brought into reaction with the metal layer at the location of the first semiconductor structure, forming a metal silicide.

Abstract: One embodiment of the invention relates to a method for fabricating a semiconductor device having a semiconductor structure with a silicon region which forms at least one connection region in and/or on a surface of a substrate. The method comprises forming a metal cluster layer from a first, non-siliciding metal, followed by the deposition of a metal layer consisting of a second, siliciding metal. A subsequent heat treatment is responsible for forming a metal silicide from the second metal, the atoms of the first metal being displaced in a direction substantially perpendicular to the surface of the substrate. According to one embodiment of the invention, the atoms of the first metal are displaced by the Kirkendall effect to beneath the metal silicide. If an MOST, for example, is being fabricated, this has advantages both at the location of the source and drain region and at the location of the gate electrode.