3. Transformational change #1: From induced demand towards disappearing traffic

Radical street redesign holds enormous opportunities: Barcelona’s Superblocks

Among the most iconic examples that bring together Complete Streets and Place-making and where climate has been a central focus is that of Superblocks in Barcelona. The development of superblocks is part of the city’s response to numerous challenges. Among them are the lack of green space and heat island effects, high noise and pollution, and high transport CO₂ emissions (accounting for 36% of total city CO2 emissions) (Ajuntamient de Barcelona and BCNecología, 2020[48]). The implementation of Superblocks constitutes an exceptional example where transformational action, based on redesigning the urban and transport system, has been put at the centre of climate (both mitigation and adaptation) and other (e.g. green infrastructure, biodiversity) plans and targets (Zografos et al., 2020[49]). To date, six Superblocks have been implemented, which has meant the reconfiguration of 143 hectares in the city, and three more are already being planned (López, Ortega and Pardo, 2020[50]). When fully implemented, the superblocks project will imply a significant reconfiguration of the entire city (in total 503 superblocks are planned and these will cover the entire Barcelona municipality).

The model of mobility and public space based on Superblocks establishes a network that integrates in its perimeter the circulation of all modes of transport. The network of Superblocks reorganises the city into polygons of approximately 400 m x 400 m and around 5 000-6 000 resident population. Inner roads are not closed to motorised vehicles, as these can enter the superblock but they cannot cross it (and have to stay within a speed limit of 10 km/h). The loop system (see Figure 3.5) allows the car to enter the superblock and have access to houses/services in every block, but it forces it to exit through the same side it entered it, since it is not possible to cross the superblock. Sometimes the passage of motorised vehicles inside the superblocks is reserved only for residents, services and urban distribution. Pedestrians and bicycles can cross the superblocks in both directions. Superblocks support in this way converting streets from a single function (basically right-of-ways for vehicles) to spaces with multiple functions (including those as a place) and uses (Ajuntament de Barcelona, 2014[51]) (Rueda, 2019[52]).

Figure 3.5. Road hierarchy in the Superblock model

Source: Authors.

The Superblocks model seeks, first of all, to liberate the maximum surface of public space dedicated to traffic, while at the same time ensuring the functionality of the system. By adopting the Superblocks model 70% of space dedicated to traffic could be liberated while only reducing total car travel by 15% (a percentage similar to the traffic reduction in Barcelona due to the 2008 economic crisis), and also maintaining current traffic speeds. Secondly, the model seeks to minimize the dysfunctions generated by the current mobility model (Rueda, 2020[53]).

The mobility plan (PMUS 2018-2024), aims however to go beyond and reduce traffic by 21% by 2024 (Rueda, 2019[54]), while having 79% of all trips made by walking, cycling or public transport (Rueda, 2019[52]); (Postaria, 2021[55]). This, together with the technological changes of the engines expected for a certain percentage of vehicles, will allow reducing CO₂ emissions ​​by 36% (Rueda, 2019[54]) (see.Table 3.1). In addition, this will allow reducing air pollution to values ​​below 40 micrograms / m3 for 96% of the population (today only 56%) (Rueda, 2019[54]),and cutting NO2 emissions in line with European Union standards (Rueda, 2019[52]); (Mueller et al., 2020[56]; López, Ortega and Pardo, 2020[50]). It will also permit reducing noise below 65 dBA for 73.5% of the population (compared to 54%), and drastically reducing serious or fatal traffic accidents (the speed of the perimeter roads of the superblocks is limited to 30 km / h and the interiors to 10 km / h). At the same it will reverse the excessive occupation of land by motorised mobility (6,200,000 m2 of public space will be freed) (Rueda, 2019[54]).

In 2023, there could be 31 superblocks in total, while as said before the long-term plan is to transform the entire municipality of Barcelona (to implement 503 superblocks). The complete reconfiguration would imply a 61% reduction of the public space dedicated to the road network utilised by cars (from 912 km to 355 km), which currently occupy 60% of the total public space in the city (Rueda, 2019[52]). This will allow increasing the average space dedicated to pedestrians from 15, 8% to 67% while increasing the comfort and safety features of streets and sidewalks (Rueda, 2019[52]). Liberated space is also being converted into other uses besides transport, such as playgrounds and picnic areas, which have been chosen in consultation with the local neighbourhoods over time (Roberts, 2019[57]).

Superblocks and the health and environmental benefits they can generate can also importantly contribute to economic improvements. Mueller et al. (2020[56]) estimate that, if all of the planned Superblocks are implemented in Barcelona, 667 premature deaths (estimated to cost EUR 1.6 billion) could be prevented every year. This is due to lower exposure to pollution (NO2 emissions are accounted for in the study), noise and heat (accounting for 291, 163 and 117 preventable deaths respectively) as well as to increased physical activity generated by a modal shift from cars and motorcycles to walking and cycling (accounting for 36 preventable deaths) and increased access to green space (accounting for 60 preventable deaths).

Figure 3.6. Annual premature death that the “Superblocks” Model could avoid

Source: (Mueller et al., 2020[56]).

The implementation of the superblock model is not a problem, but rather a solution, from a traffic point of view and it is not a problem from an economic point of view either. The development of superblocks does not involve investment in hard infrastructure. Rather, it is about transforming the urban environment by changing the use of existing infrastructure. As described in López, Ortega and Pardo (2020[50]), it is “very low-tech and low-cost urbanism”, yet it has the potential to completely transform the urban ecosystem. The implementation of the 503 superblocks, based on tactical urbanism (see below) can be carried out with an investment of around 300 million euros. The budget of the City Council of Barcelona was, for the year 2021, equivalent to 3,400 million euros. In the event that the 503 superblocks were implemented in a period of 4 years, the accumulated budget of the City Council for this period would be EU 13.6 billion. This would represent only 2% of the accumulated budget (Rueda, 2020[58]).

Importantly, while the implementation of superblocks has been anchored in the urban mobility plans for the city,16 it also implies a radical change in land-use policy (Zografos et al., 2020[49]). The reallocation and redesign of road space is a central feature of Superblocks, and thus these interventions have huge potential for addressing and reversing induced demand. Furthermore, the comprehensive planning and thinking behind such projects also bring together a number of actions that can allow addressing other dynamics behind car dependency, creating a number of synergies to transform urban and transport systems. On the one hand, the integration of bicycle lanes and the reorganisation of bus services as part of these interventions (see below) is key to address the erosion of alternative modes. On the other, reconfiguring neighbourhoods and liberating space from car use is an important step in changing the urban landscape. This brings important opportunities for increasing proximity to amenities and services, reducing longer distance trips, and making developed areas more attractive, all of which can contribute to limiting and reversing sprawl.

The reconfiguration of large areas of the city into Superblocks will allow the expansion of the network of bicycle lanes and complementing the network of main routes with the development of secondary/proximity bike lanes, as well as incorporating parking facilities for bicycles. In parallel to space redistribution, Superblocks incorporate necessary efforts to better integrate bicycle and public transport use to ensure alternatives to car use (a necessary action discussed in more detail in Chapter 5). This includes adapting public transport for bicycle access (especially inter-city ones) and integrating bike parks at stations. Adapting the city for the use of electric bicycles is another objective of Superblocks, e.g. ensuring bike lanes are available in streets with slopes and implementing bike-sharing schemes that include electric bikes.

The implementation of Superblocks will also incorporate the reconfiguration and expansion of the bus network, in parallel to increasing frequencies. Interurban services will also be improved, including by integrating bus lanes into road infrastructure connecting different territories. Indeed, a distinguishing feature of Superblocks is the possibility to shift from a radial to an orthogonal system of buses. This allows more efficient services, which can be more accessible to the population (e.g. the goal is to have population that is at most 300 m away from a stop), and offer frequencies similar to those of the metro (4-5 min apart instead of 15 min). All of which contributes to shifting longer trips from car to public transport. Before the pandemic, the new orthogonal bus network (fully implemented at the end of 2018 following the perimeter of the superblocks) had increased the number of users by 15%. The bus network implemented at the end of 2009 in Vitoria-Gasteiz (the capital of the Álava Province), designed following the perimeter of the superblocks in the same way as in Barcelona, had increased, before the pandemic, by almost 100% the number of users (Rueda, 2019[52]).

Making street reconfiguration a wide-scale plan is also important to avoid gentrification and eviction. In addition to limiting benefits, when such projects are only implemented as pilots in reduced areas of cities, an important downside tends to be gentrification and eviction, as it creates better relative conditions in a constrained space and thus creates price differentials between the reconfigured area and other areas, making it unaffordable for current residents to stay. In Barcelona, the first Superblocks in the Eixample neighbourhood have been introduced in areas with social housing. Moreover, the fact that new amenities (e.g. quality public and green space) will be distributed throughout all of the 503 Superblocks avoids the risk of creating price differentials between areas (Rueda, 2019[54]); (Postaria, 2021[55]). That said, it is important to think about how to extend the model beyond the municipality of Barcelona, to avoid increasing price differentials and living conditions between Barcelona and the surrounding municipalities in the larger metropolitan area and region.

Figure 3.7. The changes brought about by the Superblocks model

Source:BCnecologia and Ajuntament de Barcelona (2014[51]).

Although Superblocks have the potential to bring significant benefits, their implementation has not been free from challenges (Postaria, 2021[55]). Experience implementing them brings valuable insights on the role and importance of the political context and dynamics for the implementation of transformative projects, as well as on the challenges of obtaining public acceptability. These issues are discussed below, building on the experience of Barcelona’s Superblocks as well as other international examples involving significant road reallocation and redesign.

Revisiting parking policies is crucial to redesign streets and improve management of public space

Parking policies hold significant emissions reduction potential. As such, they should be more central in climate strategies for the transport sector. Parking policies are often overlooked (Kodransky and Hermann, 2011[65])and, as signalled by (Franco, 2020[66]), “have significant environmental and economic implications, including effects on climate change, air pollution, energy consumption, traffic congestion, housing affordability and economic development”.

Parking policies, as used (or not used) today, incentivise car use. Policies subsidising, under-pricing or providing an oversupply of parking space influence automobile use, land use and urban form (Franco, 2020[66]). Evidence from cities across the globe demonstrates that the parking space required could be reduced by 10-30% with efficient parking policies, and these could also reduce general vehicle traffic volumes (Litman, 2016[67]). The availability of parking space, in particular at residential and work sites, has been signalled as importantly related to vehicle ownership and use, showing that people tend to drive walkable or bikeable distances if parking is easily available (Franco, 2020[66]). For instance, Franco and Khordagui (2019[68]) find that increasing on-street parking by 10% is associated with a 1.3% increase in the probability of driving. A back-of-the-envelope calculation by Russo, van Ommeren and Dimitropoulos (2019[69]) suggests that the provision of free parking at the workplace by employers may be responsible for 17 million tonnes of CO₂ emissions per year in the United States.

Subsidies are often in the form of “free parking”. As (Franco, 2020[66])highlights, there is no such thing as free parking. Where parking is “free” or under-priced (which is often the case), its costs are being paid elsewhere and by someone else, for example through mortgages and rents in the case of off-street parking provided in buildings, or through general taxes in the case of on-street parking (Franco, 2020[66]). Subsidised or free on-street parking also incentives cruising, i.e. driving around the area waiting for a parking space to be liberated, which leads to congestion, emissions and air pollution (Franco, 2020[66]); (Russo, van Ommeren and Dimitropoulos, 2019[69]). People living in areas with free on-street parking tend to use this space instead of private parking (Scheiner et al., 2020[70]), occupying parts of the street that could be used for different functions (e.g. green areas to foster biodiversity, etc.) (Russo, van Ommeren and Dimitropoulos, 2019[69]).

Parking policies can instead be designed to regulate and discourage car use (Kodransky and Hermann, 2011[65]), positively contributing to emissions and pollution reduction efforts. This would imply a shift from current parking policies, which are mainly focused on accommodating cars and thus incentivise its use. Higher parking prices, smart parking meters, zoning and the revisiting of parking supply are some of the ways in which parking policies can play a role in the redesign of streets and the improved management of public space, with the ultimate goal of reducing emissions and improving life quality.

Higher parking prices have the potential to incentivise modal shifts away from private cars. In the city of Amsterdam, for example, it is estimated that a 10% increase of the parking price for residential parking would translate into an 8% reduction of car ownership (price elasticity of -0.8) (Groote, van Ommeren and Koster, 2016[71]). Note that this elasticity might be lower in cities with limited options for substituting car trips (e.g. public transport, walking or cycling), highlighting the importance of combining parking policies with policies to improve conditions for active and shared modes of transportation, such as the ones described in Chapter 5. In San Francisco, smart parking meters (SFpark) have enabled implementing real-time fare adjustments and have increased the effectiveness of variable-rate on-street parking prices (OECD, 2015[30]). Prices are set precisely to balance supply and demand to leave one or two spaces free per block (Pierce and Shoup, 2013[72]), which can “save time for parkers, reduce congestion, speed up public transit, and improve transportation for almost everyone” (Pierce and Shoup, 2013[72]).

Shifting parking costs from employer to employee can drive an important change in commuters’ modal choices, as well as reduce incentives to move to the suburbs (Franco, 2020[66]) based on Breuckner and Franco (2018[73])). The authors propose that workers pay for parking at market rate, and that employers raise employee wages to offset the cost. A parking cash-out is another policy option: employers lease or partially subsidise parking for employees and offer them the choice of keeping their parking spot or trading it in for an equivalent cash payment. Employees that choose to forgo the cash payment are choosing to spend it on parking, while those who accept the payment can use the money however they see fit (Brueckner and Franco, 2018[73]). Allowing employees such choice sheds light on the parking cost and has resulted in less people driving to work. For example, in California, based on surveys carried out in the years following the implementation of the Cash-out Law (1992), the number of people driving to work alone decreased by 17%; carpooling, using public transportation and active travel increased by 64%, 50% and 33%, respectively (Franco, 2020[66]) based on (Shoup, 2005[74]).

The effectiveness of cash-out programmes is dependent on the accessibility of alternative transport modes, urban density and the amount of the cash subsidy (i.e. the parking price) (Brueckner and Franco, 2018[73]). Synergies can be made if revenues are used to develop alternatives to driving. The Nottingham City Council has introduced a Workplace Parking Levy (WPL), a type of annual congestion-charging scheme for employers providing workplace parking. All employers who provide workplace parking are legally required to license the spots, although employers with ten or fewer parking spots may qualify for a 100% discount. The central government releases the Retail Price Index, which is used to calculate the WPL charge. Employers must register for an annual license, which runs from April to March of the next year, with the cost of each parking spot set prior to 1 January. Nottingham has used the revenue from the WPL to fund the tram system extension (NET Phase Two), Nottingham Station and the Link Bus Network, while also incentivising employers to manage employee parking (Nottingham City Council, n.d.[75]).

Differentiating parking prices by zone can improve their efficiency and public acceptability. In Lisbon, three parking price zones exist. Zoning is determined according to the availability of public transport services and to the density of parking sought in the different areas. Red areas correspond to main transport corridors. In these areas, relatively high parking prices (EUR 1.6 per hour) and maximum parking duration limits (2 hours) are implemented. Contrastingly, in green zones, where there is relatively low public transport availability and where parking space is less scarce, parking prices are the lowest (EUR 0.8 per hour) and time limits are longer (4 hours). Yellow areas are central areas of the city that, while not on a transport corridor, have a relatively high availability of public transport. In these areas, the price of parking is EUR 1.2 per hour and the maximum time allowed for on-street parking is 4 hours (Government of Lisbon, 2018[76]; ELTIS, 2014[77]).19 In the same vein, the three-zone parking pricing scheme in Copenhagen discourages car use and promotes the use of active transport modes such as biking in the city centre, with lower prices for parking in peripheral areas and higher ones in central areas of the city (Kodransky and Hermann, 2011[65]). In Strasbourg (France), a concentric three-zone parking pricing scheme imposes higher parking prices as well as shorter parking times in the city centre, compared to the periphery of the city as well. This policy has gone hand-in-hand with the replacement of on-street parking spaces in the city centre with cycling lanes and tramways, providing a good example of synergistic policy packages (as explained above, the elasticity of parking pricing correlates to the availability of alternative options to cars). Such a policy bundle seeks to reduce car use in the city centre and to concentrate long-term parking needs at park-and-ride and other off-street parking facilities in more residential areas on the outskirts of the city (General Commission for Strategy and Foresight, 2013[78]).

Parking policies can also promote the purchase of more efficient cars, by linking the parking price to the emissions efficiency of the car. For example, some boroughs in London differentiate the charges for permits of residential parking according to the type-approval20 CO₂ emissions of the applicant’s car (Kodransky and Hermann, 2011[65]). Moreover, the City of London introduced differentiated parking fees for on-street parking in the Square Mile in 2018. While low-emission vehicles (electric and hybrid) pay GBP 4 per hour, conventional cars are charged up to GBP 6.8 per hour (FleetNews, 2018[79]). In this case, however, careful attention is necessary to ensure that all cars pay what is needed to achieve an efficient use of space and trigger modal “shift” and encourage “avoid” effects, regardless of their technology. Embedding such a policy in a larger package of policies intended to reverse car dependency is key and if keeping a car-dependent system this could also have negative equity implications. In addition, electric and hybrid vehicles should not be given the same treatment (see Chapter 6 for a discussion).

Road pricing focused on the efficient use of road space and embedded in street redesign plans can also be a powerful tool

Road pricing can contribute to shifting away from a “predict and provide” approach (see Chapter 2), the focus on expanding road capacity for cars as the way to fight congestion (the consequences of which are explained in Section 3.1), towards an emphasis on better managing the use of existing roads. Road-pricing schemes will better deliver climate goals if they are designed with the aim of efficiently using road space. Road-pricing schemes have often been set with the expectation of increasing traffic speeds and reducing time delays for motorists, often considered as congestion’s most important disutility (van Dender, 2019[81]; ITF, 2018[82]). However, as explained above, climate and well-being goals do not depend on allowing people to travel as fast and far as possible, but on sustainably delivering accessibility, for which adequately allocating and managing public space (of which roads are a part of) is crucial. Thus, rather than looking at road pricing as a way of increasing speeds per se, schemes should be used with the view of efficiently using road space.

Crozet and Mercier (2018[83]) find that in urban areas, space use per car is more efficient at speeds between 20 km/h and 40 km/h, as within this range speed is high enough for the available road space to deliver significant access, while minimising the consumption of space per vehicle, as space needed for safe travel is less. Space consumption per car is just above 1 m²h22 within this speed range, compared to 4 m²h at speeds of 130 km/h (Crozet and Mercier, 2018[83]). Such a speed range can be taken as a reference when designing road-pricing schemes. In Singapore, for instance, periodical updates on prices are realised to ensure average speed flows are within this “optimal” speed level.

In addition, as also suggested by Crozet and Mercier (2018[83]), road pricing could also contribute to incentivising shared mobility if pricing is differentiated by vehicle occupancy (see below for other criteria for differentiating pricing). This would not only create an efficient use of road space by minimising space consumed per vehicle, but would also create disincentives for low occupancy or even empty vehicles (in the case of autonomous cars in the future), to encourage efficiency on a per person basis.

Moreover, research suggests that fostering optimal average travel speeds, rather than the “highest-possible” speeds, may also be a more efficient way to reduce congestion per se (ITF, 2017[84]), which is associated with high levels of greenhouse gas emissions and pollution. In dense urban areas, speeds between 20 km/h and 40 km/h (which are in line with speeds that minimise space consumption per car) reduce the likelihood of bottlenecks and time delays (ITF, 2017[84]). Real-world emissions testing has revealed that “[T]he low velocity and the increased braking may double the [local pollutant] emissions per kilometre in congested urban situations” (ITF, 2017[84]). The smooth car traffic conditions enabled by keeping average speeds within shorter ranges are also associated with lower CO₂ emissions than stop-start conditions. Studies in the United States have shown a 40% reduction in CO₂ emissions when driving in smooth traffic at an average speed of 45 km/h rather than in congested, stop-start conditions (Grote et al., 2016[85]). While this is slightly above the threshold mentioned above, it provides a reference for comparing emissions under smooth and congested traffic. In addition, lowering speeds (in particular inside urban areas) is also relevant for road safety reasons (Litman, 2012[86]). For this, implementing and enforcing speed limits is also crucial.

The greatest gains will come if pricing road use by motorists is implemented in parallel to re-allocating space away from cars and towards other transport modes and uses (i.e. beyond transport) (see above). The same congestion levels can be associated with very different overall travel volumes and emissions. As such, introducing road pricing without revisiting an over dimensioned road space supply allocated for driving and parking (and without investing in public and active modes) could result in reduced congestion, but still very high total traffic volumes and emissions. On the other hand, introducing road pricing while adjusting the supply of road space for driving and parking, which at the same time liberates space for other modes and uses beyond transport, can provide greater incentives for modal shift, as well as the conditions for shorter distance trips. Reduced congestion levels in this case (which could be similar to those resulting from the case above) would be associated to much lower overall traffic and emissions. Thus, if embedded in comprehensive policy packages and investment programmes, road pricing can contribute to supporting transit-oriented development and to containing (or reversing) sprawl (ITF, 2018[82]), bringing much larger mitigation, air quality and other (e.g. equity) benefits.

Unlocking these benefits requires (once again) prioritising the need to correct the excessive allocation of public space for car use, which is a barrier to modal shift and the creation of proximity, over short-term congestion alleviation gains. Indeed, as shown in the London example below, implementing road-pricing schemes while reallocating road space away from cars can offset to an extent the congestion reductions in the short term. However, as explained above, only in this way can road pricing lead to congestion reductions that effectively deliver significant traffic and emissions reductions in the mid- and long run.

Importantly, focusing on the efficient use of road and public space, rather than higher car travel speeds, does not mean that motorists can’t benefit as well, as these would both have quality alternatives for a number of trips as well as benefit from more fluid traffic and greater reliability of trips when they consider it is worth paying to drive (Litman, 2021[32]). Indeed, embedding road pricing into a larger package focused on shifting systems away from car dependency is key to limiting a relevant downside, which is that those who can afford to tend to drive more (ITF, 2021[10]). Improving the relative attractiveness of other modes vis-à-vis the car can help decrease the time cost threshold at which a motorist would be discouraged to drive (Litman, 2021[32]; 2014[87]). Thus, presumably it would also increase the price threshold at which motorists would rather pay than use alternatives. This will allow better channelling car use towards the trips where it will have more value than costs, which is what would happen in a system that is no longer car dependent (ITF, 2021[10]), and can reflect the “healthy” transport system depicted in Section 2.1.