Abstract: Device and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first, second and third regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the first and second regions. A MRAM cell which includes a MTJ element sandwiched between top and bottom electrodes is formed in the second region. The bottom electrode is in direct contact with the metal line in the first upper interconnect level of the second region. A dielectric layer which includes a second upper interconnect level with a dual damascene interconnect in the first region and a damascene interconnect in the second region is provided over the first upper dielectric layer. The dual damascene interconnect in the first region is coupled to the metal line in the first region and the damascene interconnect in the second region is coupled to the MTJ element.

Abstract: Device and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first, second and third regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the first and second regions. A MRAM cell which includes a MTJ element sandwiched between top and bottom electrodes is formed in the second region. The bottom electrode is in direct contact with the metal line in the first upper interconnect level of the second region. A dielectric layer which includes a second upper interconnect level with a dual damascene interconnect in the first region and a damascene interconnect in the second region is provided over the first upper dielectric layer. The dual damascene interconnect in the first region is coupled to the metal line in the first region and the damascene interconnect in the second region is coupled to the MTJ element.

Abstract: Device and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first, second and third regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the first and second regions. A MRAM cell which includes a MTJ element sandwiched between top and bottom electrodes is formed in the second region. The bottom electrode is in direct contact with the metal line in the first upper interconnect level of the second region. A dielectric layer which includes a second upper interconnect level with a dual damascene interconnect in the first region and a damascene interconnect in the second region is provided over the first upper dielectric layer. The dual damascene interconnect in the first region is coupled to the metal line in the first region and the damascene interconnect in the second region is coupled to the MTJ element.

Abstract: Device and methods of forming a device are disclosed. The method includes providing a substrate and a first upper dielectric layer over first, second and third regions of the substrate. The first upper dielectric layer includes a first upper interconnect level with a plurality of metal lines in the first and second regions. A MRAM cell which includes a MTJ element sandwiched between top and bottom electrodes is formed in the second region. The bottom electrode is in direct contact with the metal line in the first upper interconnect level of the second region. A dielectric layer which includes a second upper interconnect level with a dual damascene interconnect in the first region and a damascene interconnect in the second region is provided over the first upper dielectric layer. The dual damascene interconnect in the first region is coupled to the metal line in the first region and the damascene interconnect in the second region is coupled to the MTJ element.

Abstract: A method for forming a self-aligned, recessed channel, MOSFET device that alleviates the problems due to short channel and hot carrier effects while reducing inter-electrode capacitance is described. A substrate with an active area encompassed by a shallow trench isolation (STI) region is provided. A mask oxide layer is then patterned and etched to expose the substrate and a portion of the STI region. The surface is etched and the mask oxide layer is eroded away while creating a gate recess in the unmasked area. A thin pad oxide layer is then grown overlying the surface followed by a deposition of a thick silicon nitride layer covering the surface and filling the gate recess. The top surface is planarized exposing the pad oxide layer. An additional oxide layer is grown causing the pad oxide layer to thicken. A portion of the silicon nitride layer is etched away and additional oxide layer is again grown causing the pad oxide layer to further thicken.