March 16, 2018

Climate change and construction a recipe for future Calgary floods, study finds

Research by Babak Farjad's team shows Elbow River basin will strain under climate change, urban growth
Babak Farjad, a postdoctoral fellow at the University of Calgary, studied the combined impact of climate change and urbanization on the Elbow River watershed.

Babak Farjad studied the impact of climate change and urbanization on the Elbow River watershed.

Michael Platt, Schulich School of Engineering

Climate change and urban development along Calgary’s Elbow River may be a recipe for frequent flooding disasters in the future, says the lead author of a study focused on the impact of precipitation, thaw and development on the city’s second-largest river basin.

Babak Farjad and his team investigated the combined effects of future climate and land-use/land-cover (LULC) changes on the Elbow River watershed, concluding that changing precipitation patterns, warmer springs and reduced natural absorption in riverside communities means Calgary’s risk of flooding will increase greatly over the next 50 years.

“This should serve as a warning. The results can help decision-makers in both mitigation and adaptation strategies,” says Farjad, a post-doctoral fellow in Geomatics at the Schulich School of Engineering.

Study weighs climate and construction together

Farjad’s study, entitled An Integrated Modelling System to Predict Hydrological Processes under Climate and Land-Use/Cover Change Scenarios, weighs the combined impact of climate change and urbanization, rather than measuring each as a separate factor.

The study states: “The impacts of climate and LULC change on streamflow are positively correlated in winter and spring, which intensifies their influence and leads to a significant rise in streamflow, and, subsequently, increases the vulnerability of the watershed to spring floods."

Heavy snowfall, increased rain and rapid spring melts due to warmer temperatures are all significant contributors to flooding, but it’s human development that aggravates that potential by replacing natural groundcover and forest with buildings, asphalt and concrete.

“A conversion from forest to urban areas results in less canopy and root density, and in turn, more paved areas, which causes a reduction in infiltration and evapotranspiration (natural evaporation through soil and plants),” it reads.

University of Calgary students, faculty and staff volunteered around Alberta for the 2013 flood relief effort.

Students, faculty and staff volunteered around Alberta for the 2013 flood relief effort.

University of Calgary

Rain and thaw flows directly into river

Instead of being intercepted and slowly released by the forest and soil, all that extra rain and melt flows directly into the river in the form of increased overland flow.

While increased flooding is one possible outcome of climate and LULC scenarios, Farjad says the study makes it clear that the two factors play off each other and a slight change in one can amplify or offset the other.

Farjad started the research in 2011 under the supervision of Professor Danielle Marceau and Adjunct Professor Anil Gupta at the University of Calgary, with initial results being produced just after the flood disaster of 2013. That flood saw more than 100,000 Albertans displaced after heavy spring rains triggered catastrophic flooding along major rivers, including the Bow and Elbow.

Other urban rivers face similar future

Gupta says the research shows the importance of using an integrated modeling approach to investigate the combined impacts of climate and LULC changes, and the future of the Elbow can serve as a model for other municipal rivers.

“We might have the same situation in different watersheds,” he explains.