Predicting the microbial exposure risks in urban floods using GIS, building simulation, and microbial models

Jonathon Taylor*, Phillip Biddulph, Michael Davies, Ka Man Lai

*Corresponding author for this work

Research output: Contribution to journalJournal articlepeer-review

8 Citations (Scopus)


London is expected to experience more frequent periods of intense rainfall and tidal surges, leading to an increase in the risk of flooding. Damp and flooded dwellings can support microbial growth, including mould, bacteria, and protozoa, as well as persistence of flood-borne microorganisms. The amount of time flooded dwellings remain damp will depend on the duration and height of the flood, the contents of the flood water, the drying conditions, and the building construction, leading to particular properties and property types being prone to lingering damp and human pathogen growth or persistence. The impact of flooding on buildings can be simulated using Heat Air and Moisture (HAM) models of varying complexity in order to understand how water can be absorbed and dry out of the building structure. This paper describes the simulation of the drying of building archetypes representative of the English building stock using the EnergyPlus based tool 'UCL-HAMT' in order to determine the drying rates of different abandoned structures flooded to different heights and during different seasons. The results are mapped out using GIS in order to estimate the spatial risk across London in terms of comparative flood vulnerability, as well as for specific flood events. Areas of South and East London were found to be particularly vulnerable to long-term microbial exposure following major flood events.

Original languageEnglish
Pages (from-to)182-195
Number of pages14
JournalEnvironment International
Publication statusPublished - Jan 2013

Scopus Subject Areas

  • Environmental Science(all)

User-Defined Keywords

  • Building simulation
  • Flood
  • GIS
  • Hygrothermal
  • Mould
  • Urban


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