Dr Elizabeth Follett

Cyhoeddiadau

• Date
• Type
• Selected

Structure and function of wood jams for natural flood management

Natural flood management practices, including engineered logjam installations, can promote floodwater storage and infiltration in upstream catchments, ehancing sediment storage and ecological resilience. Dr Follett's research considers the effects of engineered log jam installations on stream hydrodynamics and sediment transport in order to accurately assess the implications of natural flood management projects and guide management interventions.

Funding: Royal Academy of Engineering-Sêr Cymru Research Fellowship [2020-2025]

The answer lies in the soil: Environmental resilience in rural Wales

Welsh farmers play a crucial role in sustaining ecosystem services of clean water, air and habitat provision, as well as food production. In addition to pressures to produce food cheaply, farmers are at serious risk due to the negative impacts of climate change, which is already increasing summer storm intensity and sediment runoff. Online and in-person workshops communicated basic mechanisms of sustainable farming actions and collected feedback from farmers on barriers to implementation, key decisionmaking points, and preferences for information delivery. Partnership with NFU Cymru, Nuffield Farming Trust Scholar Ms. Lorna Davis and designer Mrs. Penelope Turnbull, who is developing mosaic sculpture based on farmer-identified tensions and bilingual childrens' art tutorials.

Funding: NERC Wales Showcase 2021 [March-Nov 2021]

WoodJam: Sediment dynamics of instream wood jams and managed installationsIn order to reduce flood damages and prepare for an expected increase in severe floods due to climate change, the EU Water Framework Directive encourages the use of engineered logjams and other natural flood management interventions. It is necessary to consider the effects of channel- spanning engineered log jam installations, which are the most common, on stream hydrodynamics and sediment scour and retention in order to guide management interventions and accurately assess the implications of natural flood management project. This project experimentally investigated the impact of jam geometry and spacing on sediment storage, including development of a method to assess the porosity of a jam without disassembly in partnership with Slow the Flow Shropshire, a DEFRA-designated natural flood management site.

Funding: Marie Skłodowska-Curie Individual Fellowship [2018-2020]

Particle transport in vegetated canopies

The feedbacks between plants, flow, and particle fate shape the size, shape, and resilience of vegetated regions, which provide key ecosystem services to the landscapes in which they reside. Vegetation acts as an ecosystem engineer by creating distinct regions of flow diversion, turbulent mixing, and quiescent flow, dependent upon canopy physical parameters. The density and extent of vegetated canopies alters the canopy mediated flow profile, in turn influencing particle transport. In order to predict the resilience and future growth of vegetation, it is necessary to consider particle transport in light of the canopy-mediated flow environment. Dr Follett's research considers particle fate and transport in emergent and submerged vegetated canopies through laboratory experiments and numerical modeling, connecting transport trends to the physical parameters governing the canopy mediated flow profile, as well as particle size and density.

Funding: U.S. National Science Foundation Grant No. AGS-1005480 (PI Professor Heidi Nepf)
EAR-0738352 (PI Professor Heidi Nepf)

Supervision

I am happy to discuss support of applications for external PhD and postdoctoral funding related to environmental fluid mechanics, vegetated flows, and natural flood management. Currently, I supervise 1 PhD student (start Oct 2021) and PDRA.

Currently, we have an open EPSRC DTP studentship in fluid-structure interaction for logjams placed over a mobile sediment bed, using a combination of flume experiments and numerical modelling (co-I Dr Zhihua Xie). Please see linked advert for additional details.

Past projects