Title :
Operational Voltage Reduction of Flash Memory Using High-κ Composite Tunnel Barriers
Author :
Verma, Sarves ; Pop, Eric ; Kapur, Pawan ; Parat, Krishna ; Saraswat, Krishna C.
Author_Institution :
Stanford Univ., Stanford
fDate :
3/1/2008 12:00:00 AM
Abstract :
We explore the performance of symmetric (low-k/high-k/low-k) and asymmetric (low-k/high-k) composite tunnel barriers with conventional Flash constraints of retention, erase, read and program disturbs. Simulations, including five different high-k materials, were performed under these criteria to minimize the programming voltage Vprog. Among all constraints, we find read disturb to be the most restrictive both in terms of lowering Vprog and choosing the high-k materials for such stacks. Furthermore, the symmetric barrier stack is found to be more promising versus the asymmetric barrier stack. For the common read disturb voltages of 2.5 and 3.6 V, the lowest Vprog of ~ 4 and 5 V, respectively (relative to the floating gate), are obtained. In addition, the maximum required operating Flash voltage is found to be 30% -40% lower than the prevalent voltages.
Keywords :
composite materials; flash memories; asymmetric barrier stack; flash memory; high-K composite tunnel barrier; high-k materials; operational voltage reduction; symmetric barrier stack; voltage 2.5 V; voltage 3.6 V; voltage 4 V; voltage 5 V; Composite materials; Design optimization; Dielectric materials; Electrons; Flash memory; Helium; Materials science and technology; Memory management; Nonvolatile memory; Voltage; Flash memory; Flash operating constraints; high- $kappa$ dielectrics; program disturb; read disturb; retention; tunnel barrier engineering;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2007.915376
