Issue 31, 2024

Unveiling cutting-edge developments: architectures and nanostructured materials for application in optoelectronic artificial synapses

Abstract

One possible result of low-level characteristics in the traditional von Neumann formulation system is brain-inspired photonics technology based on human brain idea. Optoelectronic neural devices, which are accustomed to imitating the sensory role of biological synapses by adjusting connection measures, can be used to fabricate highly reliable neurologically calculating devices. In this case, nanosized materials and device designs are attracting attention since they provide numerous potential benefits in terms of limited cool contact, rapid transfer fluidity, and the capture of photocarriers. In addition, the combination of classic nanosized photodetectors with recently generated digital synapses offers promising results in a variety of practical applications, such as data processing and computation. Herein, we present the progress in constructing improved optoelectronic synaptic devices that rely on nanomaterials, for example, 0-dimensional (quantum dots), 1-dimensional, and 2-dimensional composites, besides the continuously developing mixed heterostructures. Furthermore, the challenges and potential prospects linked with this field of study are discussed in this paper.

Graphical abstract: Unveiling cutting-edge developments: architectures and nanostructured materials for application in optoelectronic artificial synapses

Article information

Article type
Review Article
Submitted
02 Mar 2024
Accepted
25 May 2024
First published
27 Jun 2024

Nanoscale, 2024,16, 14589-14620

Unveiling cutting-edge developments: architectures and nanostructured materials for application in optoelectronic artificial synapses

R. Khan, N. U. Rahman, M. F. Hayat, D. Ghernaout, A. A. M. Salih, G. A. Ashraf, A. Samad, M. A. Mahmood, N. Rahman, M. Sohail, S. Iqbal, S. Abdullaev and A. Khan, Nanoscale, 2024, 16, 14589 DOI: 10.1039/D4NR00904E

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