A fabrication process and an integrated MOS device having multi-crystal silicon resisters are described. The process includes depositing a multi-crystal silicon layer on top of a single-crystal silicon body; forming silicon oxide regions on top of the multi-crystal silicon layer in zones where resistors are to be produced; depositing a metal silicide layer on top of and in contact with the multi-crystal silicon layer so as to form a double conductive layer; and shaping the conductive layer to form gate regions, of MOS transistors. During etching of the double conductive layer, the metal silicide layer on top of the silicon oxide regions is removed and the silicon oxide regions form masking regions for the multi-crystal silicon underneath, so as to form resistive regions having a greater resistivity than the gate regions.
A fabrication process and an integrated MOS device having multi-crystal silicon resisters are described. The process includes depositing a multi-crystal silicon layer on top of a single-crystal silicon body; forming silicon oxide regions on top of the multi-crystal silicon layer in zones where resistors are to be produced; depositing a metal silicide layer on top of and in contact with the multi-crystal silicon layer so as to form a double conductive layer; and shaping the conductive layer to form gate regions, of MOS transistors. During etching of the double conductive layer, the metal silicide layer on top of the silicon oxide regions is removed and the silicon oxide regions form masking regions for the multi-crystal silicon underneath, so as to form resistive regions having a greater resistivity than the gate regions.
A fabrication process and an integrated MOS device having multi-crystal silicon resisters are described. The process includes depositing a multi-crystal silicon layer on top of a single-crystal silicon body; forming silicon oxide regions on top of the multi-crystal silicon layer in zones where resistors are to be produced; depositing a metal silicide layer on top of and in contact with the multi-crystal silicon layer so as to form a double conductive layer; and shaping the conductive layer to form gate regions, of MOS transistors. During etching of the double conductive layer, the metal silicide layer on top of the silicon oxide regions is removed and the silicon oxide regions form masking regions for the multi-crystal silicon underneath, so as to form resistive regions having a greater resistivity than the gate regions.
A fabrication process and an integrated MOS device having multi-crystal silicon resisters are described. The process includes depositing a multi-crystal silicon layer on top of a single-crystal silicon body; forming silicon oxide regions on top of the multi-crystal silicon layer in zones where resistors are to be produced; depositing a metal silicide layer on top of and in contact with the multi-crystal silicon layer so as to form a double conductive layer; and shaping the conductive layer to form gate regions, of MOS transistors. During etching of the double conductive layer, the metal silicide layer on top of the silicon oxide regions is removed and the silicon oxide regions form masking regions for the multi-crystal silicon underneath, so as to form resistive regions having a greater resistivity than the gate regions.
A process for manufacturing integrated capacitors in CMOS technology, comprising the steps of: producing, in a substrate of semiconductor material having a first type of conductivity, at least one well with the opposite type of conductivity, defining the active areas, producing insulation regions, depositing a first conducting layer of polycrystalline silicon adapted to form the gate regions and the lower plates of the capacitors, depositing a layer of silicon oxide at low temperature, to form the dielectric of the capacitors, depositing a second layer of polycrystalline silicon to form the second plate of the capacitors, shaping the polycrystalline silicon and silicon oxide layers, implanting and diffusing the source and drain regions of the CMOS transistors, providing the insulation layer, the metallic connecting layer, and final covering with a layer of protective insulation.