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The reliability properties of BE-SONOS (Lue et al., 2005) are extensively studied. BE-SONOS employs a multi-layer O1/N1/O2/N2/O3 stack, where O1/N1/O2 serves as a bandgap engineered tunneling barrier that provides an efficient hole tunneling erase but eliminates the direct tunneling leakage. BE-SONOS can overcome the fundamental limitation of the conventional SONOS, for which fast erase speed and...
Reliability properties of bandgap engineered SONOS (BE-SONOS) (Lue et al., 2005) are extensively studied. First, the erase mechanism of BE-SONOS is confirmed as substrate hole tunneling through the ultra-thin ONO tunneling dielectric. Next, very long-term (>3,000 hours) high-temperature baking data (from 150 to 250degC) for various programmed/erased states and cycling history are collected and...
A double-layer TFT NAND-type flash memory is demonstrated, ushering into the era of three-dimensional (3D) flash memory. A TFT device using bandgap engineered SONOS (BE-SONOS) (Lue et al., 2005, Lai et al., 2006) with fully-depleted (FD) poly silicon (60 nm) channel and tri-gate P+-poly gate is integrated into a NAND array. Small devices (L/W=0.2/0.09 mum) with excellent performance and reliability...
A bandgap engineered SONOS with greatly improved reliability properties is proposed. This concept is demonstrated by a multilayer structure of O1/N1/O2/N2/O3, where the ultra-thin "O1/N1/O2" serves as a non-trapping tunneling dielectric, N2 the high-trapping-rate charge storage layer, and O3 the blocking oxide. The ultra-thin "O1/N1/O2" provides a "modulated tunneling barrier"...
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