Optogenetics-inspired photoelectric memories based on flexible nanogap electrodes
Lead Research Organisation:
University of Southampton
Department Name: Optoelectronics Research Centre (ORC)
Abstract
The aim of this project is to develop a new form of neuromorphic systems that merge photonic, electronic and ionic effects, bringing new prospects for in-memory computing and artificial visual memory applications. This will be achieved upon developing photoelectric memories that employ coplanar nanogap electrodes and multi-functional solution-processed materials, fabricated with low-cost processes compatible with large-area flexible substrates.
Neuromorphic engineering is poised to revolutionise information technologies by developing electronic devices that can realistically emulate biological neural networks. A key component is the "artificial synapse" that needs to be highly scalable and power efficient, whilst supporting rich dynamical responses akin to biological synapses. An emerging application of such platforms is in neuromorphic vision, where light sensors mimic the spatio-temporal nature of human vision not only by turning light into electrical signals but also by capturing and sending the useful-only information to the processing unit in an extremely efficient manner. This is particularly relevant for real-time pattern recognition tasks that support a plethora of applications, from autonomous locomotion to point-of-care diagnostics, leveraging the sensors advances in speed, greater dynamic range and decreased computational cost. The field of optogenetics has pioneered the use of light-sensitive proteins that can be activated at will upon illumination and stimulate the neurons to fire. Inspired by this technology, I will fabricate artificial synapses that can be controlled by optical stimuli, which, in contrast to electrical ones, can be spatially confined reducing thus significantly the crosstalk and noise, while they enable higher sensitivity and signal propagation speed. I will employ a simple nanofabrication method to design prototype devices of the same dimensionality as the actual synapse, namely large aspect ratio nanogap-separated electrodes, the nanogap being in the range of 15 nm, similar to the size of the synaptic cleft.
Interconnected nanogap electrodes emulating neuronal networks will be fabricated using adhesion lithography technique to address the current challenge of reliable manufacturing of nanoscale structures on large area flexible substrates. Finally, I will employ photosensitive polyoxometalate and halide perovskite to fabricate synaptic-like metal/semiconductor/metal junctions. The film forming properties of these materials and their interfaces with the metal structures will be tailored to demonstrate neuromorphic functionalities, such as (a) associative learning, (b) parallel addressing of devices to emulate homeostasis of biological networks and (c) spatial integration of the optical stimulus in the array to enable selective storage depending on the light intensity/wavelength on each pixel.
My approach presents several advantages over the existing memristive technologies, which are based on crossbar architectures and solely electrical stimulus. First, coplanar nanogap electrodes, owing to their low dimensionality, hold great promise for achieving low power consumption and fast switching speeds, as already demonstrated with other types of devices (radiofrequency diodes, photodetectors), while their planar geometry facilitates a light-controlled operation, enabling both analogue tuning of resistance states and elimination of sneak currents in the array configuration. Second, the aforementioned solution-processable materials present many attractive optoelectronic properties, chemical tunability and manufacturability merits that render them suitable to reach the set performance goals.
Successful implementation of this fellowship will represent a paradigm shift in the fabrication of neuromorphic devices, supporting the UK-based electronics and manufacturing industry, while it will establish me as a leader in the field of nanoscale optoelectronics for AI hardware.
Neuromorphic engineering is poised to revolutionise information technologies by developing electronic devices that can realistically emulate biological neural networks. A key component is the "artificial synapse" that needs to be highly scalable and power efficient, whilst supporting rich dynamical responses akin to biological synapses. An emerging application of such platforms is in neuromorphic vision, where light sensors mimic the spatio-temporal nature of human vision not only by turning light into electrical signals but also by capturing and sending the useful-only information to the processing unit in an extremely efficient manner. This is particularly relevant for real-time pattern recognition tasks that support a plethora of applications, from autonomous locomotion to point-of-care diagnostics, leveraging the sensors advances in speed, greater dynamic range and decreased computational cost. The field of optogenetics has pioneered the use of light-sensitive proteins that can be activated at will upon illumination and stimulate the neurons to fire. Inspired by this technology, I will fabricate artificial synapses that can be controlled by optical stimuli, which, in contrast to electrical ones, can be spatially confined reducing thus significantly the crosstalk and noise, while they enable higher sensitivity and signal propagation speed. I will employ a simple nanofabrication method to design prototype devices of the same dimensionality as the actual synapse, namely large aspect ratio nanogap-separated electrodes, the nanogap being in the range of 15 nm, similar to the size of the synaptic cleft.
Interconnected nanogap electrodes emulating neuronal networks will be fabricated using adhesion lithography technique to address the current challenge of reliable manufacturing of nanoscale structures on large area flexible substrates. Finally, I will employ photosensitive polyoxometalate and halide perovskite to fabricate synaptic-like metal/semiconductor/metal junctions. The film forming properties of these materials and their interfaces with the metal structures will be tailored to demonstrate neuromorphic functionalities, such as (a) associative learning, (b) parallel addressing of devices to emulate homeostasis of biological networks and (c) spatial integration of the optical stimulus in the array to enable selective storage depending on the light intensity/wavelength on each pixel.
My approach presents several advantages over the existing memristive technologies, which are based on crossbar architectures and solely electrical stimulus. First, coplanar nanogap electrodes, owing to their low dimensionality, hold great promise for achieving low power consumption and fast switching speeds, as already demonstrated with other types of devices (radiofrequency diodes, photodetectors), while their planar geometry facilitates a light-controlled operation, enabling both analogue tuning of resistance states and elimination of sneak currents in the array configuration. Second, the aforementioned solution-processable materials present many attractive optoelectronic properties, chemical tunability and manufacturability merits that render them suitable to reach the set performance goals.
Successful implementation of this fellowship will represent a paradigm shift in the fabrication of neuromorphic devices, supporting the UK-based electronics and manufacturing industry, while it will establish me as a leader in the field of nanoscale optoelectronics for AI hardware.
Publications
Panidi J
(2022)
Advances in Organic and Perovskite Photovoltaics Enabling a Greener Internet of Things
in Advanced Functional Materials
Pecunia V
(2023)
Roadmap on energy harvesting materials
in Journal of Physics: Materials
Raeis-Hosseini N
(2023)
Addition to "High On/Off Ratio Carbon Quantum Dot-Chitosan Biomemristors with Coplanar Nanogap Electrodes"
in ACS Applied Electronic Materials
Raeis-Hosseini N
(2022)
High On/Off Ratio Carbon Quantum Dot-Chitosan Biomemristors with Coplanar Nanogap Electrodes
in ACS Applied Electronic Materials
Wagih M
(2023)
Microwave-Enabled Wearables: Underpinning Technologies, Integration Platforms, and Next-Generation Roadmap
in IEEE Journal of Microwaves
Description | Presentation to DSIT meeting |
Geographic Reach | National |
Policy Influence Type | Contribution to a national consultation/review |
Description | Talk at EPSRC Early Career Forum in Manufacturing - Glasgow meeting |
Geographic Reach | National |
Policy Influence Type | Participation in a guidance/advisory committee |
Description | EPSRC Core Equipment Award 2022/23 |
Amount | £925,000 (GBP) |
Funding ID | EP/X035034/1 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 01/2023 |
End | 07/2024 |
Description | Going Global Partnerships - Reconnect Travel Grant |
Amount | £12,000 (GBP) |
Organisation | British Council |
Sector | Charity/Non Profit |
Country | United Kingdom |
Start | 03/2023 |
End | 03/2024 |
Description | Resistive Switching Nanogap Reconfigurable Biosensors |
Amount | € 10,000 (EUR) |
Organisation | University of Ghent |
Sector | Academic/University |
Country | Belgium |
Start | 01/2024 |
End | 12/2024 |
Description | UKRI AI Centre for Doctoral Training in AI for Sustainability |
Amount | £8,787,058 (GBP) |
Funding ID | EP/Y030702/1 |
Organisation | United Kingdom Research and Innovation |
Sector | Public |
Country | United Kingdom |
Start | 03/2024 |
End | 09/2032 |
Description | Invited seminar talk at Southampton University Women in Engineering Society meetings |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Local |
Primary Audience | Undergraduate students |
Results and Impact | Dr Dimitra Georgiadou was invited to give a talk to the Southampton University Women in Engineering Society (SUWES), entitled "Drawing inspiration from the brain to create next generation electronics". The main attendees of these seminar series are undergraduate and MSc students from either Engineering or ECS Department of th Univrsity of Southampton. Many students approached the speaker after the talk asking for opportunities to perform summer internships and PhD under her supervision. |
Year(s) Of Engagement Activity | 2023 |
Description | Outreach Activity at UKRI Festival of Tomorrow event |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | The Flexible Nanoelectronics team, led by Dr Dimitra Georgiadou, and supported by PhD candidates Ms Emilie Gerouville, Mr Chris Madden and Ms Evangelia Founta, participated with a stand in the UKRI Festival of Tomorrow event in Swindon and presented demos on "How a memory works", "How a battery charges and discharges" and "Construct your own molecule using atoms and bonds". We circulated an evaluation survey to attendants and 100% said they had a good time at our stand, 88% said they learned something new (e.g. "How your research is helping memory technology", "How a battery is charged", "I've learnt how the memories work and how we can use the evaporator in order to deposit thin films of metals on a surface and also how we can use nature materials to make safe and flexible batteries"), while all three activities were rated exceptional (>4.5/5). We awarded gifts to those who filled in the survey after lottery (a Molymod "build-your-own-molecule" kit and a rechargeable batteries set). |
Year(s) Of Engagement Activity | 2022 |
Description | Outreach Activity in Southampton Science and Engineering Festival (SOTSEF) |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | The Flexible Nanoelectronics team, led by Dr Dimitra Georgiadou, and supported by PhD candidates Ms Emilie Gerouville, Mr Chris Madden and Ms Evangelia Founta, participated with a stand in the Southampton Science and Engineering Festival (SOTSEF) 2022 event that took place at the Highfield Campus of the Univerity of Southampton and presented demos on "How a memory works", "How a battery charges and discharges" and "Construct your own molecule using atoms and bonds". The attendees of the festival ranged from 5-10 y.o. kids who played with the molecules and batteries toys, teenagers who were interested in the concepts of "How stuff works" and of the day-to-day life of a researchers, and adults with interest in science and technology and wanted to learn the latest in computing and in safer batteries. |
Year(s) Of Engagement Activity | 2022,2023 |