English

A back-end, CMOS compatible ferroelectric Field Effect Transistor for synaptic weights

Emerging Technologies 2020-03-31 v1 Applied Physics

Abstract

Neuromorphic computing architectures enable the dense co-location of memory and processing elements within a single circuit. This co-location removes the communication bottleneck of transferring data between separate memory and computing units as in standard von Neuman architectures for data-critical applications including machine learning. The essential building blocks of neuromorphic systems are non-volatile synaptic elements such as memristors. Key memristor properties include a suitable non-volatile resistance range, continuous linear resistance modulation and symmetric switching. In this work, we demonstrate voltage-controlled, symmetric and analog potentiation and depression of a ferroelectric Hf57_{57}Zr43_{43}O2_{2} (HZO) field effect transistor (FeFET) with good linearity. Our FeFET operates with a low writing energy (fJ) and fast programming time (40 ns). Retention measurements have been done over 4-bits depth with low noise (1%) in the tungsten oxide (WOx_{x}) read out channel. By adjusting the channel thickness from 15nm to 8nm, the on/off ratio of the FeFET can be engineered from 1% to 200% with an on-resistance ideally >100 kOhm, depending on the channel geometry. The device concept is using earth-abundant materials, and is compatible with a back end of line (BEOL) integration into complementary metal-oxidesemiconductor (CMOS) processes. It has therefore a great potential for the fabrication of high density, large-scale integrated arrays of artificial analog synapses.

Keywords

Cite

@article{arxiv.2001.06475,
  title  = {A back-end, CMOS compatible ferroelectric Field Effect Transistor for synaptic weights},
  author = {Mattia Halter and Laura Bégon-Lours and Valeria Bragaglia and Marilyne Sousa and Bert Jan Offrein and Stefan Abel and Mathieu Luisier and Jean Fompeyriney},
  journal= {arXiv preprint arXiv:2001.06475},
  year   = {2020}
}

Comments

14 pages, 5 figures, supplementary information available, submitted to ACS Applied Materials & Interfaces

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