Powering a microprocessor by photosynthesis
Powering a microprocessor by photosynthesis
Sustainable, affordable and decentralised sources of electrical energy are required to power the network of electronic devices known as the Internet of Things. Power consumption for a single Internet of Things device is modest, ranging from μW to mW, but the number of Internet of Things devices has already reached many billions and is expected to grow to one trillion by 2035, requiring a vast number of portable energy sources (e.g., a battery or an energy harvester). Batteries rely largely on expensive and unsustainable materials (e.g., rare earth elements) and their charge eventually runs out. Existing energy harvesters (e.g., solar, temperature, vibration) are longer lasting but may have adverse effects on the environment (e.g., hazardous materials are used in the production of photovoltaics). Here, we describe a bio-photovoltaic energy harvester system using photosynthetic microorganisms on an aluminium anode that can power an Arm Cortex M0+, a microprocessor widely used in Internet of Things applications. The proposed energy harvester has operated the Arm Cortex M0+ for over six months in a domestic environment under ambient light. It is comparable in size to an AA battery, and is built using common, durable, inexpensive and largely recyclable materials.
2529-2536
Bombelli, P.
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Savanth, A.
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Rowden, S. J. L.
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Scarampi, A.
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Green, D.H.
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Erbe, A
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Arstol, E.
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Jevremovic, I.
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Hohmann-Marriott, M. F.
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Trasatti, S.
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Ozer, E.
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Howe, C. J.
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June 2022
Bombelli, P.
cb7eeb06-eefa-400e-8250-e43aa0ea0def
Savanth, A.
57b60ac8-bbb6-4517-9d5e-668d82500190
Rowden, S. J. L.
01b5da2d-ac28-4fd1-a095-f8a00d7435c4
Scarampi, A.
fbecc116-efd6-4f49-8075-44202f030d94
Green, D.H.
e91f78d9-73c6-420b-9772-1abc3ca1d2fa
Erbe, A
39f7f177-6a38-4c05-8713-027d8d30d0dd
Arstol, E.
7d9cb3b7-05fa-4538-a8bc-110b6b3ed246
Jevremovic, I.
660d9734-1e09-4ef8-b9cb-933e89e329b9
Hohmann-Marriott, M. F.
8e78cdbf-7d34-4ac2-a956-8d5cc2e83ad7
Trasatti, S.
2400e836-a731-4b71-93a9-1ea111042b62
Ozer, E.
07d738b5-0b1c-4291-8284-9179c191c3d2
Howe, C. J.
ad320e56-4da1-4faf-b497-91888c77970a
Bombelli, P., Savanth, A., Rowden, S. J. L., Scarampi, A., Green, D.H., Erbe, A, Arstol, E., Jevremovic, I., Hohmann-Marriott, M. F., Trasatti, S., Ozer, E. and Howe, C. J.
(2022)
Powering a microprocessor by photosynthesis.
Energy & Environmental Science, 15 (6), .
(doi:10.1039/D2EE00233G).
Abstract
Sustainable, affordable and decentralised sources of electrical energy are required to power the network of electronic devices known as the Internet of Things. Power consumption for a single Internet of Things device is modest, ranging from μW to mW, but the number of Internet of Things devices has already reached many billions and is expected to grow to one trillion by 2035, requiring a vast number of portable energy sources (e.g., a battery or an energy harvester). Batteries rely largely on expensive and unsustainable materials (e.g., rare earth elements) and their charge eventually runs out. Existing energy harvesters (e.g., solar, temperature, vibration) are longer lasting but may have adverse effects on the environment (e.g., hazardous materials are used in the production of photovoltaics). Here, we describe a bio-photovoltaic energy harvester system using photosynthetic microorganisms on an aluminium anode that can power an Arm Cortex M0+, a microprocessor widely used in Internet of Things applications. The proposed energy harvester has operated the Arm Cortex M0+ for over six months in a domestic environment under ambient light. It is comparable in size to an AA battery, and is built using common, durable, inexpensive and largely recyclable materials.
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More information
Accepted/In Press date: 4 April 2022
e-pub ahead of print date: 12 May 2022
Published date: June 2022
Additional Information:
This work was funded by a Biotechnology and Biological Sciences Research Council studentship, BB/M011194/1 (to ASc), the National Biofilms Innovation Centre 02POC19029 (to SJLR), the
Italian Ministry of Education, University and Research (MIUR) (to PB) and the Natural Environment Research Council National Capability Science & Facilities funding NE/ R017050/1 and
Scottish Association for Marine Science internal research funds (to DHG). The authors thank Eystein Vada (NTNU) for technical assistance with SEM.
Identifiers
Local EPrints ID: 475565
URI: http://eprints.soton.ac.uk/id/eprint/475565
ISSN: 1754-5692
PURE UUID: 8ac865b3-06fd-4334-ace9-d741cb1641ea
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Date deposited: 21 Mar 2023 17:47
Last modified: 16 Mar 2024 17:32
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Contributors
Author:
P. Bombelli
Author:
A. Savanth
Author:
S. J. L. Rowden
Author:
A. Scarampi
Author:
D.H. Green
Author:
A Erbe
Author:
E. Arstol
Author:
I. Jevremovic
Author:
M. F. Hohmann-Marriott
Author:
S. Trasatti
Author:
E. Ozer
Author:
C. J. Howe
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