An Ultralow Power Li<i><sub>x</sub></i>TiO<sub>2</sub>‐Based Synaptic Transistor for Scalable Neuromorphic Computing
Ngoc‐Anh Nguyen, Olivier Schneegans, Raphaël Salot, Yann Lamy, J. Giapintzakis, Van Huy, Sami Oukassi
Abstract
Abstract Artificial synapses based on electrochemical synaptic transistors (SynTs) have attracted tremendous attention toward massive parallel computing operations. However, most SynTs still suffer from downscaling limitations and high energy consumption. To overcome such drawbacks, a complementary metal–oxide–semiconductor (CMOS) back‐end‐of‐line compatible solid‐state SynT is presented, which includes an ultrathin (10 nm thick) quasiamorphous Li x TiO 2 channel. A nonvolatile conductance modulation (<75 nS) is achieved through reversible lithium intercalation into the channel, and synaptic functions, such as long‐term potentiation/depression involve ultralow switching energy of 2 fJ µm −2 . Moreover, this SynT shows excellent endurance (>10 5 weight updates) and recognition accuracy (>95% on the MNIST data test using crossbar simulations). Furthermore, a comprehensive electrochemical study allows deeper insight into the specific pseudocapacitive mechanism at the origin of conductance modulation. These results underline the high potential of Li x TiO 2 ‐based SynTs for energy‐efficient neuromorphic applications.