Overview Of The Stretchable Reconfigurable Synaptic Transistor A

(PDF) A Stretchable And Reconfigurable Synaptic Transistor

(PDF) A Stretchable And Reconfigurable Synaptic Transistor Stretchable and reconfigurable artificial synaptic devices with both excitatory and inhibitory properties have a wide range of applications and requirements in high performance neuromorphic computing and wearable electronics. In this article, we report a stretchable and reconfigurable synaptic transistor created using a stretchable bilayer semiconductor.

Overview Of The Stretchable Reconfigurable Synaptic Transistor A ...

Overview Of The Stretchable Reconfigurable Synaptic Transistor A ... Neurons of the ventral tegmental area of the brain contain single axon terminals that release excitatory and inhibitory neurotransmitters, creating reconfigurable synaptic behaviour. In this mini review, we introduced the stretchable materials used in each functional layer (e.g., substrate, electrode, semiconductor, insulator) of stretchable synaptic transistors, and focused on the main manufacturing methods and emerging device structures of stretchable synaptic transistors. To study the stretchable reconfigurable synaptic transistor, we first investigated the stretchable synaptic transistors based on a single layer n type or p type semiconductor with excitatory characteristics. Artificial synaptic transistors that exhibit similar excitatory and inhibitory behaviour—and hence synaptic function reconfiguration—could provide diverse functionality and efficient computing in various applications.

Overview Of The Stretchable Reconfigurable Synaptic Transistor A ...

Overview Of The Stretchable Reconfigurable Synaptic Transistor A ... To study the stretchable reconfigurable synaptic transistor, we first investigated the stretchable synaptic transistors based on a single layer n type or p type semiconductor with excitatory characteristics. Artificial synaptic transistors that exhibit similar excitatory and inhibitory behaviour—and hence synaptic function reconfiguration—could provide diverse functionality and efficient computing in various applications. It can exhibit both excitatory and inhibitory synaptic behaviors and allows synaptic behavior to switch between them, thus recreating the unique function of neurons in the ventral tegmental area of the brain described above. Here, we report a stretchable synaptic transistor fully based on elastomeric electronic materials, which exhibits a full set of synaptic characteristics. these characteristics retained even the rubbery synapse that is stretched by 50%. Cunjiang yu and collaborators present a soft, reconfigurable synaptic transistor based on a top gated stretchable bilayer semiconductor and using an encapsulating elastomer as the gate. Here, we report the development of a fully rubbery synaptic transistor which consists of all organic materials, which shows unique synaptic characteristics existing in biological synapses.

Flexible, Powerful, Fast Bioelectronic Devices: ion-driven soft transistors