Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)

Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)

<p><b>Graphical Abstract</b></p> <p><b>Integrated Opto-Electronics</b></p> In-memory computing mimics biological neurons by collocating the memory and processing unit. In article number 2200383, Harish Bhaskaran and co-workers engineer a path to perfor...

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Main Authors: Farmakidis, N, Youngblood, N, Lee, JS, Feldmann, J, Lodi, A, Li, X, Aggarwal, S, Zhou, W, Bogani, L, Pernice, WH, Wright, CD, Bhaskaran, H
Format: Journal article
Language:English
Published: Wiley 2022
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author Farmakidis, N
Youngblood, N
Lee, JS
Feldmann, J
Lodi, A
Li, X
Aggarwal, S
Zhou, W
Bogani, L
Pernice, WH
Wright, CD
Bhaskaran, H
author_facet Farmakidis, N
Youngblood, N
Lee, JS
Feldmann, J
Lodi, A
Li, X
Aggarwal, S
Zhou, W
Bogani, L
Pernice, WH
Wright, CD
Bhaskaran, H
author_sort Farmakidis, N
collection OXFORD
description <p><b>Graphical Abstract</b></p> <p><b>Integrated Opto-Electronics</b></p> In-memory computing mimics biological neurons by collocating the memory and processing unit. In article number 2200383, Harish Bhaskaran and co-workers engineer a path to perform data-storage and computations by electronically modulating the intensity of light. By defining plasmonic structures to confine optical power to a nanoscale volume and by employing active phase-change materials, the authors demonstrate ultra-low energy, non-volatile switching with electrical and optical readout.
first_indexed 2024-09-25T04:23:15Z
format Journal article
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institution University of Oxford
language English
last_indexed 2024-09-25T04:23:15Z
publishDate 2022
publisher Wiley
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spelling oxford-uuid:2f23b2bb-3f85-4ad3-a278-629d34d4198d2024-08-21T13:40:16ZElectronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)Journal articlehttp://purl.org/coar/resource_type/c_dcae04bcuuid:2f23b2bb-3f85-4ad3-a278-629d34d4198dEnglishSymplectic ElementsWiley2022Farmakidis, NYoungblood, NLee, JSFeldmann, JLodi, ALi, XAggarwal, SZhou, WBogani, LPernice, WHWright, CDBhaskaran, H<p><b>Graphical Abstract</b></p> <p><b>Integrated Opto-Electronics</b></p> In-memory computing mimics biological neurons by collocating the memory and processing unit. In article number 2200383, Harish Bhaskaran and co-workers engineer a path to perform data-storage and computations by electronically modulating the intensity of light. By defining plasmonic structures to confine optical power to a nanoscale volume and by employing active phase-change materials, the authors demonstrate ultra-low energy, non-volatile switching with electrical and optical readout.
spellingShingle Farmakidis, N
Youngblood, N
Lee, JS
Feldmann, J
Lodi, A
Li, X
Aggarwal, S
Zhou, W
Bogani, L
Pernice, WH
Wright, CD
Bhaskaran, H
Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)
title Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)
title_full Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)
title_fullStr Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)
title_full_unstemmed Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)
title_short Electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials (Adv. Sci. 20/2022)
title_sort electronically reconfigurable photonic switches incorporating plasmonic structures and phase change materials adv sci 20 2022
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