Award details

ISCF WAVE 1 AGRI TECH: Low cost sensors to reduce storage losses

ReferenceBB/R021597/1
Principal Investigator / Supervisor Professor Michael Turner
Co-Investigators /
Co-Supervisors
Professor Royston Goodacre, Professor Krishna Persaud
Institution The University of Manchester
DepartmentChemistry
Funding typeResearch
Value (£) 149,290
StatusCompleted
TypeResearch Grant
Start date 01/01/2018
End date 31/03/2019
Duration15 months

Abstract

Onion storage rots in the UK result in annual losses of 20% of the crop, worth approximately £6.5 million based on an average price. Detecting rots effectively while the crop is in store would enable better management decisions to be made and losses reduced. However, detecting incipient rots in a large store environment is problematic and frequently rots will be well advanced before they are noticed and affected crates or boxes removed. Plant material affected by pathogens causing rots emits volatile substances which can be detected and used to indicate that a problem is present. Detection systems are however expensive and difficult to deploy in sufficient numbers in a store environment. In this research project, we will develop a standard pathogen challenged onion material which will feed into the development of a novel printed electronic sensor, and then validate the effectiveness of the sensor in a series of small scale onion storage units where patogens have been deliberately introduced. The sensors have the advantage of being relatively inexpensive, and thus can be massively deployed in commercial storage units for effective and sensitive detection of developing rots.

Summary

Onion storage rots in the UK result in annual losses of 20% of the crop, worth approximately £6.5 million based on an average price. Detecting rots effectively while the crop is in store would enable better management decisions to be made and losses reduced. However, detecting incipient rots in a large store environment is problematic and frequently rots will be well advanced before they are noticed and affected crates or boxes removed. Plant material affected by pathogens causing rots emits volatile substances which can be detected and used to indicate that a problem is present. Detection systems are however expensive and difficult to deploy in sufficient numbers in a store environment. In this research project, we will develop a standard pathogen challenged onion material which will feed into the development of a novel printed electronic sensor, and then validate the effectiveness of the sensor in a series of small scale onion storage units where patogens have been deliberately introduced. The sensors have the advantage of being relatively inexpensive, and thus can be massively deployed in commercial storage units for effective and sensitive detection of developing rots.

Impact Summary

The world population is expected to grow to over 9 billion people by 2040 and food production will need to increase by more than 50% to cope with the expected demand. Improving yields from existing agricultural surface is critical to deliver this deficit as land suitable for conversion to agriculture is dwindling. European agriculture is one of the most efficient worldwide but further progress in yield and productivity are critical to meet the immediate challenges of this century. The minimization of agricultural losses for crops that require extended storage such as onions and potatatoes is one approach to improve productivity and the development of distributed sensor systems is crucial to detect diseases at an early stage and enable effective intervention. UK agriculture must act now to maintain its technological edge, to continuously develop and use innovative technologies and management techniques in order to stay at the forefront in this strategic area, and improve the competitiveness to capture the significant opportunities within this growing global market. To address new market opportunities novel advanced highly functional sensing systems are required with the following properties: low-cost, simplicity, portability, high sensitivity and specificity, high-speed, and real-time capability. At present sensors for the agricultural sector represent 4.5% of the total global sensor market and this is expected to grow to 9% by 2018. This project is therefore ideally placed to exploit market growth in this area and capture market share.
Committee Not funded via Committee
Research TopicsCrop Science, Microbiology, Technology and Methods Development
Research PriorityX – Research Priority information not available
Research Initiative Industrial Strategy Challenge Fund Wave 1 - Agri Tech (ISCF AT) [2017]
Funding SchemeX – not Funded via a specific Funding Scheme
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