In Beijing, Chennai and Fortaleza, the rate of fatalities from road crashes is 20-27.2 deaths per 100,000 residents. What do these cities have in common? They have traffic lanes wider than 3.6 meters (11.8 feet).
A long-standing belief among transportation planners and engineers is that wider traffic lanes ensure safe and congestion-free traffic flow. Recent academic research, highlighted in Cities Safer by Design, a WRI Ross Center for Sustainable Cities publication, shows that wider lanes are more dangerous than narrower lanes. To further investigate how cities are stacking up against the existing evidence, the Health and Road Safety team of WRI Ross Center for Sustainable Cities decided to compare typical lane widths in selected global cities with reported traffic fatality rates.
How Wide Should a Traffic Lane Be?
WRI’s research shows that cities with travel lane widths from 2.8 to 3.25 meters (9.2 to 10.6 feet), such as Amsterdam, Copenhagen and Tokyo, have the lowest crash fatality rates per 100,000 residents. However, many cities, specifically in the developing world, have wider lanes and higher fatality rates (See Figure 1).
New Delhi, Mumbai and São Paulo have wider lanes, ranging from 3.25 meters to 3.6 meters (10.6 to 11.8 feet), which leads to a fatality rate of 6.1-11.8 residents per 100,000, while Beijing, Chennai and Fortaleza have the highest fatality rate, 20-27.2 deaths per 100,000, with lane widths of 3.6 meters (11.8 feet) and higher.
But Why Are Wider Lanes Misinterpreted As Safer?
For decades, transport engineers and planners have considered wider lanes safer, as they provided higher maneuvering space within the lane and were said to help prevent sideswipes among cars. Yet, in an urban setting, this means cars may go faster, and, when cars go faster, the likelihood of crashes and injuries increases. For example, if a car is traveling at 30 km/h (18.6 mph), pedestrians have a 90 percent chance of survival, but, if the car is traveling at 50 km/h (31 mph), there is only a 15 percent chance the struck pedestrian will survive (See Figure 2).
Narrower travel lanes, coupled with lower speed limits, can foster a greater sense of awareness among drivers. Narrower lanes also ensure shorter crossing distances for pedestrians at intersections, which reduces the risk of an accident.
Do Wider Lanes Help to Reduce Congestion?
In 1963, Lewis Mumford said: “Increasing road width to reduce congestion is the same as loosening your belt to fight obesity.” In fact, increasing road space by having wider lanes doesn’t reduce congestion due to rebound effects. More road space results in generating more traffic. Research shows that 3 meter-wide lanes have 93 percent of the road capacity of 3.6 meter lanes—not a noticeable difference. In addition, if narrower lanes reduce speeds, this should not put great strain on vehicle movement. A recent study from Grenoble shows that private vehicles take only 18 seconds longer to travel a kilometer on a road with speed limit of 30km/h as compared to a road with a speed limit of 50km/hr. Moreover, signal delays at intersections create congestion—it rarely depends on mid-block traffic flows.
How Would Road Dieting Help?
Road dieting is a technique of narrowing lane widths to achieve sustainable and safer pedestrian and cyclist environments. If cities embrace narrower lanes, there are a range of possibilities for re-designing city streets to make them safer and more accommodating for pedestrians and cyclists.
Scenario 1: Narrowing lanes may provide space for a pedestrian refuge island or median
Scenario 2: Narrower lanes may provide space to install protected bicycle lanes
Scenario 3: Narrower lanes can provide wider sidewalks
But Why Aren’t 3 Meter Lanes the Norm?
Most cities in developed countries, like the United States, follow road design guidelines from standard-setting bodies like the American Association of State Highway and Transportation Officials’ A Policy on Geometric Design of Highways and Streets, commonly known as the Green Book, which actually allows lane widths to vary between 10-12 feet (3.0 to 3.6 meters). While the book provides a range, engineers tend to design streets with the maximum lane width, due to the ill-informed notion that wider lanes are safer and can help reduce congestion. Many cities in low- and middle-income countries have adopted this same approach, erring on the supposed side of caution.
Today, with new research showing the opposite of the status quo and a rising interest in cycling, walking and bus systems, it is time for cities to reassess how their own standards foster a safer and healthier city.