3D Neuromorphic Hardware with Single Thin-Film Transistor Synapses Over Single Thin-Body Transistor Neurons by Monolithic Vertical Integration.
Joon-Kyu HanJung-Woo LeeYeeun KimYoung Bin KimSeong-Yun YunSang-Won LeeJi-Man YuKeon Jae LeeHyun MyungYang-Kyu ChoiPublished in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2023)
Neuromorphic hardware with a spiking neural network (SNN) can significantly enhance the energy efficiency for artificial intelligence (AI) functions owing to its event-driven and spatiotemporally sparse operations. However, an artificial neuron and synapse based on complex complementary metal-oxide-semiconductor (CMOS) circuits limit the scalability and energy efficiency of neuromorphic hardware. In this work, a neuromorphic module is demonstrated composed of synapses over neurons realized by monolithic vertical integration. The synapse at top is a single thin-film transistor (1TFT-synapse) made of poly-crystalline silicon film and the neuron at bottom is another single transistor (1T-neuron) made of single-crystalline silicon. Excimer laser annealing (ELA) is applied to activate dopants for the 1TFT-synapse at the top and rapid thermal annealing (RTA) is applied to do so for the 1T-neuron at the bottom. Internal electro-thermal annealing (ETA) via the generation of Joule heat is also used to enhance the endurance of the 1TFT-synapse without transferring heat to the 1T-neuron at the bottom. As neuromorphic vision sensing, classification of American Sign Language (ASL) is conducted with the fabricated neuromorphic module. Its classification accuracy on ASL is ≈92.3% even after 204 800 update pulses.
Keyphrases
- artificial intelligence
- machine learning
- deep learning
- neural network
- room temperature
- big data
- spinal cord
- skeletal muscle
- ionic liquid
- autism spectrum disorder
- heat stress
- liquid chromatography
- spinal cord injury
- body composition
- reduced graphene oxide
- sensitive detection
- solid phase extraction
- loop mediated isothermal amplification