Tag Archives: Flood Defences

Rivers are changing all the time, and it affects their capacity to contain floods

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Houses alongside the Saigon river in Vietnam. Tony La Hoang/Unsplash, CC BY-SA

This guest post was written by: Louise Slater, University of Oxford; Abdou Khouakhi, Loughborough University, and Robert Wilby, Loughborough University.

The rainfall that has inundated the North of England is the latest in a long line of flood events that are becoming the country’s new normal. Indeed, across the world, flooding is expected to become more frequent and more extreme as the planet heats up.

Building robust flood defences and modelling vulnerable areas is crucial if we are to avoid loss of life and livelihoods from these devastating weather events. But our new research reveals that the capacity of rivers to keep water flowing within their banks can change quickly – and in failing to acknowledge this, some flood models and defences may be under-equipped to deal with the consequences when they do.

Many assume that flooding is due to heavy rainfall. This is true, but only part of the explanation. Floods also occur when the amount of water running off the land exceeds the capacity of rivers to carry that flow – as was the case when the River Don breached flood defences in the Sheffield area recently. So, floods are partly caused by the amount of rain falling, partly by the moisture that is already in the ground, and partly by the capacity of rivers to contain water within their channels.

This means that if the capacities of river channels change, then two identical rainfall events falling on similarly wet ground can cause flooding of very different severity.

Most rivers are forever changing. They are shaped by the sediments and water they carry. Humans have modified most of the world’s rivers in some way. In some cases this is through direct influence, such as dam construction or river engineering. Other influences are indirect – building on nearby land reduces the capacity of ground to absorb water, agriculture draws water from rivers, and deforestation leaves more water to flow elsewhere.

After the River Don burst its banks in places, multiple roads in urban centres such as Rotherham flooded. DnG Photography/Shutterstock

Rivers respond to changes in climate as well. During drier periods, less water flows through river systems. This means that there is often less energy to move the sediments at their beds, so riverbed levels may progressively rise, decreasing the capacity of the river. Abundant plant growth within the channel can also reduce a river channel’s capacity by slowing the flow.

But it is not always easy to predict how rivers will change. Extreme shifts in channel shape and capacity can occur very rapidly. After a recent flash flood in Spain, one river rose almost a metre as huge volumes of sediment from upstream were displaced and dumped further along. In tropical river systems, which tend to carry more sediment than temperate rivers, these changes can be several metres.

Uncertain risk

Unfortunately, such changes are typically ignored by flood engineers and modellers, who generally treat the channel as a fixed feature. If rivers actually change their capacity in space and time, then estimates of flood probability may be incorrect, putting people and property at risk.

Motivated by these concerns, we investigated the pace at which channel changes occur, and to what extent these alterations might be driven by climate. We began with a simple conceptual model: climate controls rainfall, rainfall affects river flow, and river flow shapes channel capacity.

Direct observations of this link were lacking in river systems over short timescales. So, we took 10,000 measurements of the capacity of 67 rivers in the US, covering a period of nearly 70 years. We also gathered rainfall and river flow data, to assess how climatic changes affected the capacity of the rivers.

We discovered that temporary shifts in river capacity, lasting years to decades, were far more frequent than had previously been assumed. Overall, river capacity tends to increase during periods that are wetter than average due to greater erosion of river channels, and decrease in drier periods.

The flood-prone Ganges river is a lifeline to millions who live along its course. Joachim Bago/ Shutterstock

We also found that multi-year climate cycles that affect regional precipitation patterns – such as the El Niño Southern Oscillation – can cause channel capacity to expand and contract too, perhaps on a global scale. Armed with this knowledge, we may eventually be able to predict how the capacity of rivers changes, and hence better understand flood risk.

In temperate regions such as the UK, where rivers tend to be vegetated, heavily engineered and relatively stable, delicate changes in channel capacity are hard to detect and unlikely to be life threatening. However, in river systems that carry high volumes of sediment, or in parts of the world where rainfall varies considerably during the year, sudden reductions in river capacity may dramatically increase flood risk for nearby settlements. For example, the Ganges-Brahmaputra river in India and Bangladesh falls under this category. Its capacity is already changing, and its floodplains are some of most densely populated in the world.

Unfortunately, we still have very poor understanding of the nature and causes of channel capacity changes in most regions – and it is the most at-risk places that tend to have the least data. To better understand what’s happening, we need to use satellite imagery to monitor how fast rivers are responding to changes in the climate. What we can’t yet do though is monitor river adjustment in real time. Developing technologies that do this would greatly improve our understanding of how changes in river shape and capacity affect flood risk across the world.

Until this information becomes apparent, flood models and defence structures should build this uncertain risk into their designs. Doing so could make all the difference for those living in vulnerable areas.

Louise Slater, Associate Professor in Physical Geography, University of Oxford; Abdou Khouakhi, Research Associate, Climate and Weather Data Analysis, Loughborough University, and Robert Wilby, Professor of Hydroclimatic Modelling, Loughborough University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Further reading from our blog:

Flood prevention and protection: how the Dutch do it

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Dredging to make a new canal and new recreation area, for flood control, Nijmegen, Netherlands. Image by Steven Vance via Creative Commons

“Every time there is a crisis, we see an opportunity”
– Jan Hendrik Dronkers, director general, Netherlands Ministry of Infrastructure and Environment

It’s been another stormy weekend, with large parts of the UK experiencing damage and disruption from high winds and flooding. Storm Gertrude is the latest in a succession of storms to hit the country since December. Thousands of homes and businesses have been flooded, not only in rural areas, but in the city centres of Leeds, York and Manchester. The storms have also left stretches of Dumfries and Galloway, the Scottish Borders and Aberdeenshire under water. And in Cumbria, one especially hard hit village has been flooded four times in eight weeks.

Although unprecedented, the most recent storms to hit the UK follow significant flooding events over the past decade. A report by the Met Office in 2011 suggested that this exceptional run of bad weather may be part of a trend towards more intense rainfall.

The increasing prevalence of flooding in the UK has put additional pressures on local and national government. Local councils have had to make provision for those made homeless, inform householders about support, repair roads and support the emergency services. At a wider level, initiatives, such as the Scottish Government’s flood prevention action plan, and the review of flood defence investment in England are indicative of how seriously the problem is now being viewed (although one recent opinion poll indicates that more needs to be done). The human costs of flooding are incalculable, but the economic impact is significant. Research by the Environment Agency estimated that record-breaking floods in 2012 could have cost the UK economy close to £600m.

Flood prevention in the Netherlands: making a virtue out of a crisis

In the Netherlands, where 60 per cent of the population lives below sea level, the threat from flooding has been an ever-present worry for hundreds of years. But in recent decades, the risks have appeared to be escalating. In 1953, a severe storm in the North Sea caused floodwater to inundate south-west Holland, resulting in 1800 fatalities (the same storm killed more than 300 people in the UK).

The Dutch response to the 1953 flooding was the Delta Project, a system of dams, sluices, locks, dykes, levees, and storm surge barriers, intended to prevent similar disasters striking again.

Spijkenisse_-_Hartelkering_gesloten

The Hartelkering storm surge barrier in Spijkenisse, Netherlands, part of the Delta Works project .  Image: Quistnix at nl.wikipedia via Creative Commons

Making room for the river

In 1993 and again in 1995, the focus of concern shifted to the south-east of the Netherlands, when heavy rains threatened to breach the dikes holding back the waters of the Meuse and Waal rivers. Thousands of people were evacuated from their homes, and although the flood defences held, the experience came as a profound shock to the country. “We thought we were prepared for everything,” an infrastructure and environment ministry official told The Surveyor magazine, “We thought evacuation was for other countries.”

This time, the Dutch responded with the Room for the River programme. The spatial development scheme not only involves the construction of higher, stronger dikes, but also the creation of wider, deeper floodplains. These give rivers additional space, reducing the chance of flooding elsewhere. The project has also involved difficult decisions, including the displacement of 200 families. But the near-catastrophes of 1993 and 1995 brought home that there was no alternative to relocation.

While the Dutch government is funding the €2.3bn project, it is being delivered in collaboration with local authorities, water boards and private sector partners. As well as improving flood defences, the project has generated some impressive spin-offs.  In Holland’s oldest city of Nijmegen, a completely new island has been formed from a flood control channel, providing additional land for housing and recreation. In effect, a new section of the city is being created from the river that once threatened to submerge it.

Learning from experience

At the end of 2015, as Storm Frank brought further misery to many residents across the UK, an analysis found that 10,000 homes are being built on floodplains in Britain each year. Although many of these may be protected by existing flood defences, recent flood events provide cause for concern.

Hard experience has reminded the Netherlands that flooding is a natural function of rivers. Instead of fighting the elements, the Dutch are becoming experts in water management, and offering advice to other flood-prone countries, such as Bangladesh and Vietnam. Perhaps the UK can also learn from the Holland’s flood resilience know-how: it may be time to look across the water.

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Further blog posts from The Knowledge Exchange on flooding and climate change: