Abstract: A process sequence is provided to provide an ultra-smooth (0.2 nm or less) bottom electrode surface for depositing magnetic tunnel junctions thereon. In one embodiment, the sequence includes forming a bottom electrode pad through bulk layer deposition followed by patterning and etching. Oxide is then deposited over the formed bottom electrode pads and polished back to expose the bottom electrode pads. A bottom electrode buff layer is then deposited thereover following a pre-clean operation. The bottom electrode buff layer is then exposed to a chemical mechanical polishing process to improve surface roughness. An magnetic tunnel junction deposition is then performed over the bottom electrode buff layer.

Abstract: Embodiments described herein relate to substrate processing methods. More specifically, embodiments of the disclosure provide for an MRAM back end of the line integration process which utilizes a zero mark for improved patterning alignment. In one embodiment, the method includes fabricating a substrate having at least a bottom contact and a via extending from the bottom contact in a first region and etching a zero mark in the substrate in a second region apart from the first region. The method also includes depositing a touch layer over the substrate in the first region and the second region, depositing a memory stack over the touch layer in the first region and the second region, and depositing a hardmask over the memory stack layer in the first region and the second region.

Abstract: A process sequence is provided to provide an ultra-smooth (0.2 nm or less) bottom electrode surface for depositing magnetic tunnel junctions thereon. In one embodiment, the sequence includes forming a bottom electrode pad through bulk layer deposition followed by patterning and etching. Oxide is then deposited over the formed bottom electrode pads and polished back to expose the bottom electrode pads. A bottom electrode buff layer is then deposited thereover following a pre-clean operation. The bottom electrode buff layer is then exposed to a chemical mechanical polishing process to improve surface roughness. An magnetic tunnel junction deposition is then performed over the bottom electrode buff layer.

Abstract: A process sequence is provided to provide an ultra-smooth (0.2 nm or less) bottom electrode surface for depositing magnetic tunnel junctions thereon. In one embodiment, the sequence includes forming a bottom electrode pad through bulk layer deposition followed by patterning and etching. Oxide is then deposited over the formed bottom electrode pads and polished back to expose the bottom electrode pads. A bottom electrode buff layer is then deposited thereover following a pre-clean operation. The bottom electrode buff layer is then exposed to a CMP process to improve surface roughness. An MTJ deposition is then performed over the bottom electrode buff layer.

Abstract: Embodiments described herein relate to substrate processing methods. More specifically, embodiments of the disclosure provide for an MRAM back end of the line integration process which utilizes a zero mark for improved patterning alignment. In one embodiment, the method includes fabricating a substrate having at least a bottom contact and a via extending from the bottom contact in a first region and etching a zero mark in the substrate in a second region apart from the first region. The method also includes depositing a touch layer over the substrate in the first region and the second region, depositing a memory stack over the touch layer in the first region and the second region, and depositing a hardmask over the memory stack layer in the first region and the second region.

Abstract: A process sequence is provided to provide an ultra-smooth (0.2 nm or less) bottom electrode surface for depositing magnetic tunnel junctions thereon. In one embodiment, the sequence includes forming a bottom electrode pad through bulk layer deposition followed by patterning and etching. Oxide is then deposited over the formed bottom electrode pads and polished back to expose the bottom electrode pads. A bottom electrode buff layer is then deposited thereover following a pre-clean operation. The bottom electrode buff layer is then exposed to a CMP process to improve surface roughness. An MTJ deposition is then performed over the bottom electrode buff layer.

Abstract: A substrate comprising an oxide layer covering a nitride layer, is etched in a process zone of a substrate processing chamber. A process gas comprising H2 gas is introduced into the process zone, and the process gas is energized to etch through the oxide layer to at least partially expose the nitride layer. The energized process gas has a selectivity of etching the oxide layer to the nitride layer of at least about 25:1.

Abstract: This invention relates to a filter and a method of making a filter. The filter is made of randomly orientated fibers made from an interpenetrating network formed from at least two polymers which are substantially water soluble in their salt form and which ionically interact in an aqueous solution to form the interpenetrating network. The filter is made without organic solvents, particularly, volatile organic compounds, and the filter is sufficiently water soluble to biodegrade upon disposal. A desired use of the filter is a cigarette filter.

Abstract: This invention relates to a filter and a method of making a filter. The filter is made of randomly orientated fibers made from an interpenetrating network formed from at least two polymers which are substantially water soluble in their salt form and which ionically interact in an aqueous solution to form the interpenetrating network. The filter is made without organic solvents, particularly, volatile organic compound, and the filter is sufficiently water soluble to biodegrade upon disposal. A desired use of the filter is a cigarette filter.