Spiking neurons from tunable Gaussian heterojunction transistors
Abstract
Spiking neural networks exploit spatiotemporal processing, spiking sparsity, and high interneuron bandwidth to maximize the energy efficiency of neuromorphic computing. While conventional silicon-based technology can be used in this context, the resulting neuron-synapse circuits require multiple transistors and complicated layouts that limit integration density. Here, we demonstrate unprecedented electrostatic control of dual-gated Gaussian heterojunction transistors for simplified spiking neuron implementation. These devices employ wafer-scale mixed-dimensional van der Waals heterojunctions consisting of chemical vapor deposited monolayer molybdenum disulfide and solution-processed semiconducting single-walled carbon nanotubes to emulate the spike-generating ion channels in biological neurons. Circuits based on these dual-gated Gaussian devices enable a variety of biological spiking responses including phasic spiking, delayed spiking, and tonic bursting. In addition to neuromorphic computing, the tunable Gaussian response has significant implications for a range of other applications including telecommunications, computer vision, and natural language processing.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Mar 26, 2020
- Source ID
- 10.1038/s41467-020-15378-7
Entities
People
- Ahish Shylendra
- Amit R. Trivedi
- Hadallia Bergeron
- Hocheon Yoo
- Katherine Su
- Mark Hersam
- Megan E. Beck
- Silu Guo
- Vinod K Sangwan
- William A. Gaviria Rojas
Organizations
- National Institute of Standards and Technology
- National Science Foundation
- Office of Naval Research