Towards a better understanding of the lifecycle of Pesticides in the Atmosphere at The University of Manchester on FindAPhD.com

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Prof Hugh Coe, Prof M Gallagher, Dr Tom Bannan, Dr J Allan No more applications being accepted Competition Funded PhD Project (Students Worldwide)

Manchester United Kingdom Environmental Sciences

About the Project

Since pesticides have been measured on regional scales and in the background environment there is a pathway for transport to these remote locations from the area of application. Given the distance scales this is likely to involve transport via the atmosphere, either in the gas phase or particle phase, or in all likelihood both. There are potential health impacts at the near field scale to farm workers or nearby inhabitants and previous work has investigated this near field transport during periods of application. There is an absence of data on how the emission of pesticides evolves after application and what environmental factors, if any control further release. There is also a lack of data at the wider scale.

This PhD project will examine the fluxes of pesticide from the point of application to the regional scale. Mass spectrometric detection of pesticides in the gas phase is now possible using online methods. UoM has extensive expertise in eddy correlation flux measurements of particulates and gases. Essentially the technique uses correlation between rapid changes in the component concentration of interest and the vertical wind velocity to derive a flux. Chemical ionisation mass spectrometry has been shown to be capable of measuring pesticides in the gas phase and this has previously been applied to eddy correlation measurements of organic matter in Finland. The UoM CIMS can be developed into such a flux system and used to examine gas phase emission fluxes. The UoM instrument can also be fitted with an electrospray ionisation inlet which allows online measurement of the particle phase concentration of pesticides and this can also be operated in flux mode.

The objectives are

1) to develop a flux system for both the gas and particle phase characterisation of pesticides

2) to demonstrate the capability of the system at the field scale

3) to quantify fluxes of pesticides at the field and regional scale

Initially the work will involve developing a working knowledge of the CIMS-ToF-MS instrument and the analysis tools used to analyse the data. The EESI inlet will also be fitted and the student will work on understanding this system. We have collaborators in the USA who have already worked on an eddy correlation version of the CIMS instrument and will assist with the development of the CIMS and the EESI configurations, both of which will use the same mass spectrometer system. The development of this system will be a major task of the first year and the first part of the second year of the study.

The system will then be tested in a series of field studies designed to assess the emission fluxes during and following application under a range of environmental conditions and around specific farming practices such as ploughing and harvesting. Particle flux measurements will also be made during controlled trials. This work can then be extended by examining the concentrations of pesticides at the region scale during a period before, during and after extensive pesticide application to examine the regional burden. A way of achieving this could be to target aircraft flights with generic seasonal periods and link these to documented activity in emission under suitable boundary layer conditions. The PhD would entail instrument development, as well as data analysis and interpretation.

Aerosol science is crucial to disciplines as broad ranging as transmission of disease, drug delivery to the lungs, climate change, energy and combustion science, novel materials, and consumer and agricultural products.

An aerosol is any collection of particles dispersed in a gas. The CDT brings together a multi-disciplinary team of 80 post-graduate students and academics from 7 UK universities spanning the physical, environmental and health sciences, and engineering. Our aim is to tackle the global challenges in which aerosol science is key.

Further details are available from our website: https://www.aerosol-cdt.ac.uk/

Doctoral Training in Aerosol Science

During your doctorate, you will learn to research in diverse multidisciplinary teams, gain an advanced understanding of the core physical science of aerosols, and collaborate with industrial and public sector partners, equipping you to undertake ground-breaking research in aerosol science.

During the first 7 months of your PhD, you will join the CDT cohort based at the University of Bristol. Core training in aerosol science, research methods, professionalism and translation will be delivered by Team Based Learning. You will then undertake a short research project at your home or partner institution before starting your PhD research. You will gain experience outside academia in a placement with an industrial/public sector partner in Year 2 or 3.

More Information and How to Apply

Candidates who aspire to work in a multidisciplinary field, and hold or will achieve a minimum of an upper second-class undergraduate degree in any of these areas are encouraged to apply: chemistry, physics, biological sciences, life and medical sciences, mathematics and computer science, chemical and mechanical engineering, pharmaceutical and environmental sciences.

Visit our website: Contact us:

https://www.aerosol-cdt.ac.uk/ [Email Address Removed]

Diversity and Inclusion

We are committed to furthering issues of equality, diversity and inclusion. We recognise the benefits of recruiting a diverse group of students to the Aerosol CDT and strive to avoid any conscious or unconscious bias in our recruitment. The needs of individuals will be accommodated during the recruitment process and while studying with the CDT. Further information on our commitment to equality and diversity can be found on

For application queries please contact [Email Address Removed]

Applications link: https://www.aerosol-cdt.ac.uk/how-to-apply/our website.

Funding Notes

This project is funded as part of the EPSRC CDT in Aerosol Science. Successful candidates meeting the funding criteria will receive a studentship covering tuition fees, research and training support grant, plus a stipend to cover your living expenses while you train, paid at the standard UKRI rate. An additional contribution from the Industrial sponsor will be paid.

References

• Mehra, A., Canagaratna, M., Bannan, T. J., Worrall, S. D., Bacak, A., Priestley, M., Liu, D., Zhao, J., Xu, W., Sun, Y., Hamilton, J. F., Squires, F. A., Lee, J., Bryant, D. J., Hopkins, J. R., Elzein, A., Budisulistiorini, S. H., Cheng, X., Chen, Q., Wang, Y., Wang, L., Stark, H., Krechmer, J. E., Brean, J., Slater, E., Whalley, L., Heard, D., Ouyang, B., Joe, W., Acton, F., Hewitt, C. N., Wang, X., Fu, P., Jayne, J., Worsnop, D., Allan, J., Percival, C. and Coe, H.: Using highly time-resolved online mass spectrometry to examine biogenic and anthropogenic contributions to organic aerosol in Beijing †, Faraday Discuss., Advance Ar, doi:10.1039/d0fd00080a, 2020.
• Novak, G. A., Vermeuel, M. P., and Bertram, T. H.: Simultaneous detection of ozone and nitrogen dioxide by oxygen anion chemical ionization mass spectrometry: a fast-time-response sensor suitable for eddy covariance measurements, Atmos. Meas. Tech., 13, 1887–1907, https://doi.org/10.5194/amt-13-1887-2020, 2020.
• Lopez-Hilfiker, F. D., Pospisilova, V., Huang, W., Kalberer, M., Mohr, C., Stefenelli, G., Thornton, J. A., Baltensperger, U., Prevot, A. S. H., and Slowik, J. G.: An extractive electrospray ionization time-of-flight mass spectrometer (EESI-TOF) for online measurement of atmospheric aerosol particles, Atmos. Meas. Tech., 12, 4867–4886, https://doi.org/10.5194/amt-12-4867-2019, 2019.