Ferroelectric 2D SnS 2 Analog Synaptic FET.
Chong-Myeong SongDongha KimShinbuhm LeeHyuk-Jun KwonPublished in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2024)
In this study, the development and characterization of 2D ferroelectric field-effect transistor (2D FeFET) devices are presented, utilizing nanoscale ferroelectric HfZrO 2 (HZO) and 2D semiconductors. The fabricated device demonstrated multi-level data storage capabilities. It successfully emulated essential biological characteristics, including excitatory/inhibitory postsynaptic currents (EPSC/IPSC), Pair-Pulse Facilitation (PPF), and Spike-Timing Dependent Plasticity (STDP). Extensive endurance tests ensured robust stability (10 7 switching cycles, 10 5 s (extrapolated to 10 years)), excellent linearity, and high G max /G min ratio (>10 5 ), all of which are essential for realizing multi-level data states (>7-bit operation). Beyond mimicking synaptic functionalities, the device achieved a pattern recognition accuracy of ≈94% on the Modified National Institute of Standards and Technology (MNIST) handwritten dataset when incorporated into a neural network, demonstrating its potential as an effective component in neuromorphic systems. The successful implementation of the 2D FeFET device paves the way for the development of high-efficiency, ultralow-power neuromorphic hardware which is in sub-femtojoule (48 aJ/spike) and fast response (1 µs), which is 10 4 folds faster than human synapse (≈10 ms). The results of the research underline the potential of nanoscale ferroelectric and 2D materials in building the next generation of artificial intelligence technologies.
Keyphrases
- artificial intelligence
- big data
- high efficiency
- neural network
- machine learning
- electronic health record
- deep learning
- endothelial cells
- quality improvement
- atomic force microscopy
- multiple sclerosis
- induced pluripotent stem cells
- primary care
- healthcare
- skeletal muscle
- prefrontal cortex
- data analysis
- high resolution
- risk assessment
- pluripotent stem cells
- single molecule