Atomic Hydrogen Exposure to Enable High-Quality Low-Temperature SiO 2 with Excellent pMOS NBTI Reliability Compatible with 3D Sequential Tier Stacking

integration requires development of low thermal budget process modules. High-quality SiO 2 interfacial layer (IL), obtained up to now only by high-temperature (≥850°C) oxidation or exposure, is crucial for pMOS NBTI reliability. In unannealed IL’s grown at reduced temperatures, we show that unrelaxed interface strain induces high defect densities, with physics-based NBTI modeling suggesting excessive hydroxyl-E’ defect formation due to Si-O bond stretch. Based on ab-initio theoretical insights, we demonstrate an atomic hydrogen treatment to passivate SiO 2 defects at low temperatures (100-300°C), which is shown to be vastly more effective than high pressure molecular hydrogen exposure, and to yield an SiO 2 quality and reliability surpassing a 900°C oxide.