Abstract: For constituting a pre-metal interlayer insulating film, such a method is considered as forming a CVD silicon oxide-based insulating film having good filling properties by ozone TEOS, reflowing the film to planarize it, stacking a silicon oxide film having good CMP scratch resistance by plasma TEOS, and further planarizing by CMP. However, in forming a contact hole, crack in the pre-metal interlayer insulating film is exposed in the contact hole, into which barrier metal intrudes to cause short-circuit defects. In the present invention, in the pre-metal process, after forming the ozone TEOS film over an etch stop film, the ozone TEOS film is once etched back so as to expose the etch stop film over a gate structure, a plasma TEOS film is formed over the remaining ozone TEOS film, and the plasma TEOS film is planarized by CMP.

Abstract: As a method for constituting a pre-metal interlayer insulating film, such method is considered as forming a CVD silicon oxide-based insulating film having good filling properties of a silicon oxide film by ozone TEOS, reflowing the film at high temperatures to planarize it, then stacking a silicon oxide film having good CMP scratch resistance by plasma TEOS, and, further, planarizing it by CMP. However, it was made clear that, in a process for forming a contact hole, crack in the pre-metal interlayer insulating film is exposed in the contact hole, into which barrier metal intrudes to cause short-circuit defects. In the present invention, in the pre-metal process, after forming the ozone TEOS film over an etch stop film, the ozone TEOS film is once etched back so as to expose the etch stop film over a gate structure, and, after that, a plasma TEOS film is formed over the remaining ozone TEOS film, and then the plasma TEOS film is planarized by CMP.

Abstract: As a method for constituting a pre-metal interlayer insulating film, such method is considered as forming a CVD silicon oxide-based insulating film having good filling properties of a silicon oxide film by ozone TEOS, reflowing the film at high temperatures to planarize it, then stacking a silicon oxide film having good CMP scratch resistance by plasma TEOS, and, further, planarizing it by CMP. However, it was made clear that, in a process for forming a contact hole, crack in the pre-metal interlayer insulating film is exposed in the contact hole, into which barrier metal intrudes to cause short-circuit defects. In the present invention, in the pre-metal process, after forming the ozone TEOS film over an etch stop film, the ozone TEOS film is once etched back so as to expose the etch stop film over a gate structure, and, after that, a plasma TEOS film is formed over the remaining ozone TEOS film, and then the plasma TEOS film is planarized by CMP.

Abstract: The semiconductor device is formed according to the following steps. A TiN film 71 and a W film 72 are deposited on a silicon oxide film 64 including the inside of a via-hole 66 by the CVD method and thereafter, the W film 72 and TiN film 71 on the silicon oxide film 64 are etched back to leave only the inside of the via-hole 66 and form a plug 73. Then, a TiN film 74, Al-alloy film 75, and Ti film 76 are deposited on the silicon oxide film 64 including the surface of the plug 73 by the sputtering method and thereafter, the Ti film 76, Al-alloy film 75, and TiN film 74 are patterned to form second-layer wirings 77 and 78.

Abstract: The semiconductor device is formed according to the following steps. A TiN film 71 and a W film 72 are deposited on a silicon oxide film 64 including the inside of a via-hole 66 by the CVD method and thereafter, the W film 72 and TiN film 71 on the silicon oxide film 64 are etched back to leave only the inside of the via-hole 66 and form a plug 73. Then, a TiN film 74, Al-alloy film 75, and Ti film 76 are deposited on the silicon oxide film 64 including the surface of the plug 73 by the sputtering method and thereafter, the Ti film 76, Al-alloy film 75, and TiN film 74 are patterned to form second-layer wirings 77 and 78.

Abstract: The semiconductor device is formed according to the following steps. A TiN film 71 and a W film 72 are deposited on a silicon oxide film 64 including the inside of a via-hole 66 by the CVD method and thereafter, the W film 72 and TiN film 71 on the silicon oxide film 64 are etched back to leave only the inside of the via-hole 66 and form a plug 73. Then, a TiN film 74, Al-alloy film 75, and Ti film 76 are deposited on the silicon oxide film 64 including the surface of the plug 73 by the sputtering method and thereafter, the Ti film 76, Al-alloy film 75, and TiN film 74 are patterned to form second-layer wirings 77 and 78.

Abstract: An SOG film 16 obtained by heat-treating a polysilazan type SOG film at high temperature of about 800° C. is used as a planarized insulating film to be formed on the gate electrode (9; see FIGS. 31 and 32) of a MISFET (Qs, Qn, Qp) A polysilazan SOG film (57) not subjected to such a heat treatment is used as interlayer insulating film arranged among upper wiring layers (54, 55, 56, 62, 63).

Abstract: Conduction reliability between a capacitor upper electrode and a plug connected to an upper layer wire is kept high to prevent connection defects and to reduce the resistance of the capacitor upper electrode. In a capacitor of a DRAM comprising a lower electrode 45 made of ruthenium, a capacitor insulating film 50 made of BST and an upper electrode 49, the upper electrode 49 has a laminate structure comprising a ruthenium film 47 formed on the side of the capacitor insulating film 50 and a tungsten film 48 formed over the former.

Abstract: To prevent Al wiring formed on a via-hole in which a CVD-TiN film is embedded from corroding.

Abstract: In a DRAM having a capacitor-over-bitline structure in which the capacitive insulating film of an information storing capacitive element C is formed of a high dielectric material such as Ta2O5 (tantalum oxide) film 46, the portions of bit lines BL and first-layer interconnect lines 23 to 26 of a peripheral circuit which are in contact with at least an underlying silicon oxide film 28 are formed of a W film, the bit lines BL and the interconnect lines 23 to 26 being arranged below the information storing capacitive element C, whereby the adhesion at the interface between the bit lines BL and the interconnect lines 23 to 26 and the silicon oxide film is improved in terms of high-temperature heat treatment to be performed when the capacitive insulating film is being formed.

Abstract: The semiconductor device is formed according to the following steps. A TiN film 71 and a W film 72 are deposited on a silicon oxide film 64 including the inside of a via-hole 66 by the CVD method and thereafter, the W film 72 and TiN film 71 on the silicon oxide film 64 are etched back to leave only the inside of the via-hole 66 and form a plug 73. Then, a TiN film 74, Al-alloy film 75, and Ti film 76 are deposited on the silicon oxide film 64 including the surface of the plug 73 by the sputtering method and thereafter, the Ti film 76, Al-alloy film 75, and TiN film 74 are patterned to form second-layer wirings 77 and 78.

Abstract: In order to improve connection reliability of a feeding interconnection connected to an electrode of each of the information storage capacitive elements of a DRAM, the formation of a through hole for connecting the information storage capacitive element formed over each memory cell selection MISFET and a feeding interconnection is performed in a process different from that for the formation of a through hole for connecting an interconnection of a second wiring layer in a peripheral circuit, which is formed over the information storage capacitive element and an interconnection corresponding to a first wiring layer.

Abstract: An SOG film 16 obtained by heat-treating a polysilazan type SOG film at high temperature of about 800° C. is used as a planarized insulating film to be formed on the gate electrode 9 of a MISFET (Qs, Qn, Qp) A polysilazan SOG film 57 not subjected to such a heat treatment is used as interlayer insulating film arranged among upper wiring layers (54, 55, 56, 63).

Abstract: [Object] To prevent Al wiring formed on a via-hole in which a CVD-TiN film is embedded from corroding.

Abstract: An SOG film 16 obtained by heat-treating a polysilazan type SOG film at high temperature of about 800° C. is used as a planarized insulating film to be formed on the gate electrode 9 of a MISFET (Qs, Qn, Qp). A polysilazan SOG film 57 not subjected to such a heat treatment is used as interlayer insulating film arranged among upper wiring layers (54, 55, 56, 62, 63).

Abstract: The semiconductor device is formed according to the following steps. A TiN film 71 and a W film 72 are deposited on a silicon oxide film 64 including the inside of a via-hole 66 by the CVD method and thereafter, the W film 72 and TiN film 71 on the silicon oxide film 64 are etched back to leave only the inside of the via-hole 66 and form a plug 73. Then, a TiN film 74, Al-alloy film 75, and Ti film 76 are deposited on the silicon oxide film 64 including the surface of the plug 73 by the sputtering method and thereafter, the Ti film 76, Al-alloy film 75, and TiN film 74 are patterned to form second-layer wirings 77 and 78.

Abstract: In a DRAM having a capacitor-over-bitline structure in which the capacitive insulating film of an information storing capacitive element C is formed of a high dielectric material such as Ta2O5 (tantalum oxide) film 46, the portions of bit lines BL and first-layer interconnect lines 23 to 26 of a peripheral circuit which are in contact with at least an underlying silicon oxide film 28 are formed of a W film, the bit lines BL and the interconnect lines 23 to 26 being arranged below the information storing capacitive element C, whereby the adhesion at the interface between the bit lines BL and the interconnect lines 23 to 26 and the silicon oxide film is improved in terms of high-temperature heat treatment to be performed when the capacitive insulating film is being formed.

Abstract: In a DRAM having a capacitor-over-bitline structure in which the capacitive insulating film of an information storing capacitive element C is formed of a high dielectric material such as Ta2O5 (tantalum oxide) film 46, the portions of bit lines BL and first-layer interconnect lines 23 to 26 of a peripheral circuit which are in contact with at least an underlying silicon oxide film 28 are formed of a W film, the bit lines BL and the interconnect lines 23 to 26 being arranged below the information storing capacitive element C, whereby the adhesion at the interface between the bit lines BL and the interconnect lines 23 to 26 and the silicon oxide film is improved in terms of high-temperature heat treatment to be performed when the capacitive insulating film is being formed.

Abstract: In order to improve connection reliability of a feeding interconnection connected to an electrode of each of the information storage capacitive elements of a DRAM, the formation of a through hole for connecting the information storage capacitive element formed over each memory cell selection MISFET and a feeding interconnection is performed in a process different from that for the formation of a through hole for connecting an interconnection of a second wiring layer in a peripheral circuit, which is formed over the information storage capacitive element and an interconnection corresponding to a first wiring layer.

Abstract: In a DRAM having a capacitor-over-bitline structure in which the capacitive insulating film of an information storing capacitive element C is formed of a high dielectric material such as Ta2O5 (tantalum oxide) film 46, the portions of bit lines BL and first-layer interconnect lines 23 to 26 of a peripheral circuit which are in contact with at least an underlying silicon oxide film 28 are formed of a W film, the bit lines BL and the interconnect lines 23 to 26 being arranged below the information storing capacitive element C, whereby the adhesion at the interface between the bit lines BL and the interconnect lines 23 to 26 and the silicon oxide film is improved in terms of high-temperature heat treatment to be performed when the capacitive insulating film is being formed.