Details of Award
NERC Reference : NE/S00582X/1
Developing a 'GI4RAQ' platform to predict quantitatively the potential of strategic green infrastructure to improve roadside air quality at planning
Grant Award
- Principal Investigator:
- Professor AR MacKenzie, University of Birmingham, Sch of Geography, Earth & Env Sciences
- Grant held at:
- University of Birmingham, Sch of Geography, Earth & Env Sciences
- Science Area:
- Atmospheric
- Earth
- Freshwater
- Marine
- Terrestrial
- Overall Classification:
- Unknown
- ENRIs:
- Natural Resource Management
- Pollution and Waste
- Science Topics:
- Aerosol precursors
- Aerosols
- Atmospheric chemistry
- Atmospheric fluxes
- Forest canopy
- Greenhouse gases
- Land use change
- Vegetation management
- Vegetation modelling
- Land - Atmosphere Interactions
- Hydroxyl radical chemistry
- Volatile organic compounds
- Biogenic vol organic compounds
- Boundary layer
- Greenhouse gases
- Hydroxyl radical chemistry
- Nitrogen oxides
- Ozone chemistry
- Radical chemistry
- Tropospheric Processes
- Trace gases
- Tropospheric modelling
- Tropospheric ozone
- Climate change adaptation in planning
- Environmental assessment
- Environmental policy/regulation
- Infrastructure Planning
- Local Planning
- Sustainable development
- Urban planning
- Urban policy and regeneration
- Spatial Planning
- Design and sustainability
- Development Frameworks
- Master planning
- Public realm design
- Urban structure & design
- Urban Design
- Pollutant pathways
- Pollutant transport
- Urban emissions
- Gas emissions
- Pollution
- Air pollution
- Diffuse pollution
- Abstract:
- Air pollution constitutes the greatest environmental risk to human health, with 90% of the world's urban population living in cities exceeding the World Health Organization's air quality (AQ) guidelines and outdoor air pollution claiming approximately 3 million lives each year. In the UK alone, outdoor air pollution is linked to 50,000 deaths annually, and road transport has been identified as the main culprit in urban areas. Roadside air quality (RAQ) often exceeds AQ objectives and has been the subject of litigation against the UK government, but the government devolves responsibility for AQ to local authorities (LAs). RAQ is therefore a particular concern to LAs. Whilst multiple recent studies have highlighted the potential for strategic green infrastructure (GI) to improve RAQ, there is currently a lack of appropriate platform to quantitatively predict the highly location-specific impacts of GI interventions at the planning stage; the requisite quantitative research has been carried out, but not translated into practice. The purpose of this Pathfinder is to plan the full development to market of an easily-adopted 'GI4RAQ' platform (TRL 2 to 5) through a process of co-design with target end-users and informed market assessment. The Pathfinder Project Objectives are listed below; please see 'Objectives' section for more details and directly-mapped Milestones and Outputs. 1. Confirm target end-users and secure early-adopters 2. Engage with early-adopters to determine precise form of platform required 3. Commission independent market assessment 4. Plan development of GI4RAQ platform to market (TRL 2 to 5) The University of Birmingham's (UoB's) Institute of Forest Research (BIFoR) will develop the platform. BIFoR, and colleagues from the UoB's School of Geography, Earth and Environmental Sciences, has expertise in: computer modelling of AQ, including RAQ specifically and effects of vegetation; in-situ measurements of RAQ and their use in validating model predictions of RAQ impacts; and engagement with built environment practitioners via the Trees and Design Action Group, Woodland Trust and Forest and Woodlands Advisory Committees' Urban Network. BIFoR researchers used the CiTTyCAT computer model to carry out a first exploration of the potential of GI to improve RAQ, and have since added ultrafine particle multicomponent microphysics to a closely-related model, CiTTy-Street-UFP. They have also recently made conceptual advances in the parsimonious description of streetscapes, enabling tractable diagnosis of their effect on RAQ. The likely route of GI4RAQ platform development comprises: consolidation of these models and recent advances to produce a single open-source, freely-available CiTTyCAT-Street model; and the co-design with target end-users of a simple and intuitive graphical user interface, linked to 'pre-validated parameter sets' and 'results look-up tables' derived from CiTTyCAT-Street, for rapid design decision-making in the planning process. The UoB could, alternatively, seek to add proprietorial code to a commercial industry-standard urban AQ model. The preferred route of model development will depend on the expected uptake of the platform, relative speed of development and implications for intellectual property rights and revenue to be determined during the Pathfinder via end-user engagement, market assessment and further exploration with the aid of the UoB Technology Transfer Office (TTO), respectively. Keywords: BIFoR; natural environment; built environment; green infrastructure; air quality; human health; natural capital; ecosystem services; urban forestry; planning; research; academic, public and private sectors. Stakeholders: BIFoR Director; BIFoR Steering Committee members; UoB; UoB School of Geography, Earth and Environmental Sciences; UoB TTO; NERC; Greater London Authority; Birmingham City Council; Cambridge City Council; other local authorities; DEFRA; and DCLG.
- NERC Reference:
- NE/S00582X/1
- Grant Stage:
- Completed
- Scheme:
- Innovation
- Grant Status:
- Closed
- Programme:
- Follow on Fund Pathfinder
This grant award has a total value of £20,053
FDAB - Financial Details (Award breakdown by headings)
| DI - Other Costs | Indirect - Indirect Costs | DA - Investigators | DA - Estate Costs | DI - Staff | DI - T&S |
|---|---|---|---|---|---|
| £3,922 | £4,802 | £2,022 | £696 | £5,288 | £3,323 |
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