Multilayer Layer Graphene Nanoribbon Flash Memory: Analysis of Programming and Erasing Operation

TL;DR

This paper analyzes the tunneling current mechanism in a novel multilayer graphene nanoribbon and carbon nanotube based floating gate transistor, focusing on Fowler-Nordheim tunneling during programming and erasing operations.

Contribution

It introduces a new graphene-CNT based floating gate transistor design and investigates its tunneling current behavior and influencing factors.

Findings

FN tunneling depends on high electric field and oxide thickness.

The proposed design could improve nanoscale flash memory performance.

Factors affecting tunneling current are identified and analyzed.

Abstract

Flash memory based on floating gate transistor is the most widely used memory technology in modern microelectronic applications. We recently proposed a new concept of multilayer graphene nanoribbon (MLGNR) and carbon nanotube (CNT) based floating gate transistor design for future nanoscale flash memory technology. In this paper, we analyze the tunneling current mechanism in the proposed graphene-CNT floating gate transistor. We anticipate that the proposed floating gate transistor would adopt Fowler-Nordheim (FN) tunneling during its programming and erase operations. In this paper, we have investigated the mechanism of tunneling current and the factors that would influence this current and the behavior of the proposed floating gate transistor. The analysis reveals that FN tunneling is a strong function of the high field induced by the control gate, and the thicknesses of the control oxide and the tunnel oxide.