4.1. Puerto Viejo

Puerto Viejo is a coastal town in Costa Rica, located in the canton of Talamanca, Limón. Talamanca is the second largest canton in the country, with an area of 2,810 km² (INDER, 2014). The temperatures vary between 21 and 29°C (Weather Atlas, 2022). According to the last national population census, in 2011 the district of Cahuita, where Puerto Viejo is located, was Talamanca’s most populated district, with 8,861 inhabitants. Of that population, 56% self-identifies as white or mestizo, 14.7% as indigenous, 12.5% as bi-racial, 10.7% as Afro-descendant, and 0.5% as Chinese (INEC, 2011).

The canton of Talamanca contains at least 11 spaces for the conservation of natural resources (INDER, 2014). The Cahuita National Park and the Gandoca-Manzanillo Wildlife Refuge have positioned themselves as renowned tourist attractions in the area. In 2021, these two areas attracted 122,389 and 96,472 visitors, respectively (ICT, 2022). This has resulted in tourism becoming the main source of income for the coastal sector of Talamanca, where Puerto Viejo is located (Municipalidad de Talamanca–MIDEPLAN, 2014).

Even though tourism development is centered on the coast, the development conditions of the canton do not allow to take full advantage of this potential due to the poor conditions and lack of access roads, poor quality of water for human consumption, low coverage of telecommunications and energy (Image 1) (Municipality of Talamanca–MIDEPLAN, 2014). Talamanca has the second lowest cantonal human development index in the country (UNDP Costa Rica, 2021) and doubles the national average in terms of the number of households with insufficient resources (national average: 11%, Talamanca: 22%) (Municipality of Talamanca–MIDEPLAN, 2014).

Image 1. Puerto Viejo’s main roads.

The road infrastructure in the area comprises three national routes and a local road network of 585.10 km, of which 93% are gravel roads (Unidad de Gestión Vial–Municipality of Talamanca, 2016). There is one bus route providing bus services to the Cahuita, Puerto Viejo, and Manzanillo areas from San José, one from the central canton of Limón, and one providing connecting services between Puerto Viejo and the Bribri area, where the local government is located. Other routes existed, but these have been merged under one company, and others have been closed recently (MIVAH, 2013; CTP, 2022). Bus service hours are very limited, direct services to San José are only available once a day, and the maximum frequency for routes that connect to Puerto Viejo is once every hour between 4 am and 6 pm during weekdays and less frequent on Sundays. The service to Bribri operates between 5 am and 6 pm, usually every other hour or every two hours. There are no bus services in the area after 6 pm. Formal taxis can be found, though the offer is very limited. According to data from the Public Transport Council, only two authorized taxis provide transport services in Puerto Viejo (Map 1) (CTP, 2022).

Map 1. Main roads and towns of Cahuita district where Puerto Viejo is located.

4.2. Soledad

Located in the Caribbean Region of Colombia, Soledad is a medium-sized city, home to more than 600,000 inhabitants that live at an average temperature between 25 and 30°C. It is the sixth largest city in Colombia and the third on the country’s Caribbean coast. The area of Soledad spreads over 67 km² with an average population density of 8,999 inhabitants per square kilometer. In 2018, 51% of Soledad’s inhabitants were women, 70% were between 15 and 64 years old, with more than half the population (55%) between 15 and 50 years old (Table 1). The percentage of the population self-identifying with ethnic minorities has decreased since the last national population census, rising from 3% in 2005 to 1.4%, with 1.3% identifying as Afro-Colombian. Most dwellings in Soledad are not overcrowded (more than 3 people per bedroom); most have access to piped water and electricity and are connected to the sewerage system. According to the last national population census, 2.3% lived in overcrowded conditions, 10% in dwellings lacking access to sewerage, 1.45% without piped water, and 0.5% without electricity. Despite having relatively high access to public utilities, most of Soledad’s neighborhoods are classified by the Colombian Statistics Agency as “socio-economic stratum” 1 or 2 (96.6%). In Colombia, socioeconomic strata offer a proxy variable for household income (Cantillo-García et al., Reference Cantillo-García, Guzman and Arellana2019) ranging from 0 to 6 based on the physical characteristics of the dwelling (e.g., building materials, access to basic utilities, flooring) and immediate surroundings (pavements, access roads) with 0 being undetermined and 1 the lowest level of income. Less than 1% of the population lives in dwellings classified above economic stratum 3 (0.06%) (see Map 2).

Map 2. Soledad location, main roads, and economic strata distribution.

Table 1. Determination of the emission factor

Soledad is part of a conurbation with Barranquilla, the fourth most populated municipality in Colombia and the nucleus of the metropolitan area. The conurbation has played a major role in Soledad’s transport infrastructure, particularly following the development of a Bus Rapid Transport System. Soledad’s urban mobility infrastructure is characterized by the dichotomy of hosting major metropolitan (bus terminal and international airport) and national transport infrastructure and numerous unpaved narrow roads. The national-level highway that divides the city in two and the distribution of BRT trunk and feeders and bus routes illustrate the priority given to connectivity with Barranquilla (the main city of the metropolitan area) over local mobility. The latter comprises motorcycles (15% of journeys), active travel modes (3% and 39% in peripheral neighborhoods), and since 2002, MTW (12%) (Nieto-Combariza, Reference Nieto-Combarizaforthcoming). In 2008 the use of MTW for public transport was banned by the national government in municipalities with over 50,000 inhabitants. The Ministry of Transport Decree (4125) disregarded the diverse roles MTW had acquired in some urban areas in the country, particularly in Soledad, without any public document or declaration to justify the limitation of this form of transport to municipalities with less than 50,000 inhabitants.

5.1. Surveys

In Puerto Viejo, an online survey collected data on users’ experiences with and perceptions of MTW services. Using Google Forms, 148 surveys were sampled from the area’s population of 8,861 (INEC, 2011), offering a 95% confidence level and an 8% margin of error. The survey was disseminated via social media, WhatsApp, and physical venues, and designed to accommodate both English and Spanish speakers. Questions were based on a previous Soledad survey, adapted to the Costa Rican setting and online format.

A separate survey targeted local businesses, seeking insights into their interactions with and usage of MTW services. The sample was sourced from members of the South Caribbean Tourism and Commerce Chamber and distributed through similar channels as the user survey.

The Soledad survey employed a two-level stratification process, ensuring representation across six sociodemographic attributes (gender, age, socioeconomic strata, birthplace, disabilities, and ethnicity). The resulting sample spanned 134 out of 136,134 city blocks, as per the 2018 population and housing census, with 515 completed questionnaires. Surveys were administered in person by a two-person team over several months. Data were subsequently coded into a unified database.

The research sought to understand the demographics of MTW users, the nature of their travel, and their experiences compared to other mobility options in Soledad and Puerto Viejo. The Soledad survey captured the area’s demographic heterogeneity (see Table 1), providing a representative snapshot of travel behavior and mobility patterns. Surveys in both regions included questions related to travel behavior and user experiences, inspired by the findings of Marquez (Márquez, Reference Márquez2017). Responses were processed and analyzed to align with the research’s objectives. In Puerto Viejo, trip mapping was accomplished using origin-destination data collected through the survey, driver focus groups, and interviews.

In the case of Soledad, the questionnaire also collected geospatial information: the coordinates of origin (sampled dwelling see Map 3) and destination (attraction zones). The team used the geolocation feature in WhatsApp to map the origin. According to Oviedo et al. (2022), WhatsApp geolocation accuracy depends on the phones’ characteristics, with an average error of between 3 and 10 m. The geocoding of the destinations resulted from converting the addresses or reference points in the surveys into geographic coordinates with Google My Maps.

Map 3. Survey/origin locations – Soledad.

The mobility surveys in Puerto Viejo and Soledad were first explored through descriptive statistics. In Soledad, through the geolocation of the origin-destination pairs in the survey, we defined the start and end points for the measurements of exposure to air pollution.

5.2. Sensors

Recently, the use of low-cost Air beam sensors to measure PM2.5 has increased research about exposure to air pollution in urban mobility. Ma et al. (Reference Ma, Tao, Kwan and Chai2020) showed how smart technologies and individual activity-travel microenvironments affect the assessment of individual-level pollution exposure in space and time at a very fine resolution in different modes: car, metro, and walk.

In China and the United States, Air beam units were used for spatial modeling of particulate matter air pollution sensor measurements collected by community scientists while cycling, land use regression with spatial cross-validation, and applications of machine learning for data correction; feasibility and acceptability of monitoring personal air pollution exposure with sensors for asthma self-management (Adams et al., Reference Adams, Massey, Chastko and Cupini2020; Guevara-Luna et al., Reference Guevara-Luna, Guevara-Luna and Belalcázar-Cerón2020; Xie et al., Reference Xie, Meeker, Perez, Eriksen, Localio, Park, Jen, Goldstein, Temeng, Morales, Christie, Greenblatt, Barg, Apter and Himes2021). Although air sensors are not a replacement for regulatory monitors, they entail a valuable teaching tool (Anastasiou et al., Reference Anastasiou, Vilcassim, Adragna, Gill, Tovar, Thorpe and Gordon2022). The data may help the general public better understand the air quality in their communities.

The air quality measurements were carried out to identify pollutant exposure while riding an MTW. The trip route was determined based on the insights of the MTW drivers and the O-D information collected. In Puerto Viejo, the route selected is the most common for trips in MTW during the day and night, as well as on weekdays and weekends. The starting point was the MTW station at the corner of the Hot Rocks restaurant, and the return point was Punta Uva Beach. The measurement is constant until returning to the starting point. In Soledad, seven sub-zones were delimited. The division was made considering the spatial distribution of the reported trips in the survey, the land use, and the main roads in the area. The O-D of MTW users in the survey was distributed in these zones. In Soledad, the road network monitored during two periods, the morning peak on a weekday and the weekend, represents 10.5% of the local network. During the sampling, the users of the MTW indicate to the driver their destination, letting the driver decide the route. In both cases, during the air quality measurement, a field diary was kept to register eventualities or situations that might contribute to changes in measurements, such as construction sites, changes in road quality, congestion, or vehicles on the road.

5.3. Geolocation

In Puerto Viejo and Soledad, we identified “stations” and hubs where different groups of MTWs operate. In Puerto Viejo, the stations were identified based on online information, mainly Facebook pages where MTW services are advertised or tourism sites that provide information about how to use these services. Common origin and destination sites were identified through the user survey and records provided by some of the tuk-tuk operators. In Soledad, we used Google Street views and the data from the surveys to identify the location of MTWs’ parking areas and the distribution of the origin and destination of the travelers in the surveys. Additionally, the identified locations were confirmed and complemented by the interviews with MTWs’ drivers and site visits.

The most likely routes were estimated using My Map, and the information about origins and destinations was compiled in each case. The GPS information from the air quality sensor complements this information.

5.4. GHG emissions estimation

Emissions were calculated for the working day of a motorized MTW driver, and these calculations were performed using the Greenhouse Gas Protocol (2013) methodology and the Auto-Data (2020) database. The fossil fuel quantity approach described in the technical guide’s upstream transport and distribution section was applied. These emissions are calculated by multiplying the average distance traveled in a day, the average vehicle fuel efficiency data,Footnote ¹ the corresponding emission factor, and for CH₄ and N₂O, the global warming potential to obtain a total of CO₂ equivalent (Eq. 1). The data and considerations taken for this calculation are included in the Appendix.

(1) $$ \mathrm{emissions}=\mathrm{average}\ \mathrm{distance}\ \mathrm{travelled}\;\left(\mathrm{km}\right)\;\mathrm{x}\;\mathrm{vehicle}\ \mathrm{fuel}\ \mathrm{efficiency}\;\left(\mathrm{km}/\mathrm{L}\right)\;\mathrm{x}\;\mathrm{emission}\ \mathrm{factor}\left({\mathrm{kgCO}}_2\mathrm{L}\right)\hskip0.24em $$

In Soledad, the distance traveled by vehicles was estimated by using a set of 53 different traffic counts around the city to estimate GHG emissions. The traffic counts were divided into four road types: arterial, collector, residential, and service. Additionally, five categories of vehicles were considered: car, bus, truck, motorcycle, and MTW. The team calculated the average peak hour volume for each road category (vehicles per hour) and we worked on the assumption that this value behaves similarly for roads in the same classification. In addition, we assume the average daily traffic was about 15% of the peak-hour volume. Finally, with the total length of each road category within the Soledad transportation network, an approximation of the distance traveled by each vehicle was obtained.

Vehicle efficiency was calculated based on performance (km/gal). The average performance of each vehicle category was defined based on an experimental campaign developed in 2021 by the Mining and Energy Planning Unit–UPME, in which the following variables were considered: model year, most representative brands, and emission control technologies in the country, as well as the driving cycles used for each vehicle category. Similarly, the emission factor for CO₂ was determined based on the type of fuel used by each vehicle type according to that developed by the UPME for Colombia (Table 2). Generic gasoline is 8.15 kg CO₂ eq/gal; generic diesel is 10.15 kg CO₂ eq/gal (records are included in the Appendix).

Table 2. Comparative GHG Emissions per vehicle per day according to different vehicle typology scenarios

5.5. Comparative analysis

The second stage was completed by the two teams developing a staggered comparative analysis of the two cases. Inspired by the transnational approach (Roy and AlSayyad, Reference Roy and AlSayyad2004) and following Robinson’s (Reference Robinson2016) proposal to “thinking cities/the urban through elsewhere,” we use the two cases to think comparatively, highlighting the differentiation of current conditions of three-wheeled mobility. We use “questions and answers generated at one site to more substantially interrogate other, fundamentally different sites” (Roy and AlSayyad, Reference Roy and AlSayyad2004, p. 22). The comparison of Soledad and Puerto Viejo, two urban areas of very different sizes (population and area wise), brings into light the distinctiveness of each case and the shared characteristics of the form of mobility under study. The comparison of these two cases is a comparison of an urban process and experiences avoiding restricting variation-finding methods to relatively similar cities (Robinson, Reference Robinson2011). The comparability of the cases is based on the relevance of mobility in MTW as a comparator or as the “third term”, the term that enables to relate two processes and experiences (Jacobs, Reference Jacobs2012; Robinson, Reference Robinson2016).

6.1. Contributions to accessibility and to overcoming instances of social exclusion

In Puerto Viejo, most of the people who responded to the online user survey were women (63%), people between 25 and 34 years (37%) and identifying themselves as Latin (52%), White (22%) and Mestizo (18%). However, there were also responses from people identifying as Afro-descendant (7%), Indigenous (0.7%) and Chinese (0.7%). The survey’s low percentage of the indigenous population responds to their location in several Indigenous Territories on the outskirts of Puerto Viejo, the closest being the Keköldi Territory. Such limited representation of a specific social identity due to their location highlights the importance of future research of considering in the methodology the location and/or digital accessibility of particular populations to secure their inclusion in the process of data collection. Questions about education and income level were answered only by 8% of the sample. The majority of the participants who responded to these questions have a university degree and enough or more than enough resources to cover their basic needs. The digital nature of the survey entails less information about people with lower income levels and less access to higher education who tend to have less access to the internet and time to engage in non-income related activities. Similarly, there were no respondents who reported having any form of disability. Most of the respondents are Costa Rican residents, closely followed by people who have visited Puerto Viejo as tourists and residents who are not Costa Rican.

More than half of the respondents (66.8%) have used MTW, 63.6% of which are women, 44.4% live in Puerto Viejo and are Costa Rican, 27.3% live in Puerto Viejo but are from another country, and 21.2% are tourists. The user’s age range is predominantly between 25 and 44 years old (58.7%), and 17.2% are between 18 and 24 years old. The lower representation of older users might also be a consequence of the survey being online. MTW are not combined with other modes of transport, showing they work as principal modes of transport (Figure 2).

Figure 2. Dashboard of respondents and MTW users’ characteristics in Puerto Viejo.

In Soledad, the socioeconomic characteristics of the surveyed population are similar to the distribution in the 2018 Population and Housing Census (DANE, 2018) with some characteristics related to conditions of social exclusion such as disabilities and minorities being overrepresented (see Appendix for the % census data vs. survey). The majority of individuals surveyed did not identify with any ethnic group (40.27%), and a third of the survey respondents identified themselves as Mestizo (37.74%), followed by Afro-descendant (11.48%) and White (8.37%), with 2% identifying as Indigenous. About 51.75% of the respondents identified as women, and 0.19% identified as trans. The totality of the sample was in households classified in economic strata 1 and 2 and 2% in strata 3. Accordingly, nearly two-thirds of the population declared their monthly income to be just enough to cover their basic needs, 25% considered having more than enough, and 5% went a day or more without eating for lack of money. Half of the respondents who missed a day or more meals also had children. One-third of the respondents have as their main activity to do household work, and one-third have a job with a written contract, 10% without a contract, and 10% said to be self-employed. The living conditions of the population surveyed are varied. Close to half own the house they live in, 35% with property title (35%) and 12% without. The remaining respondents live with family or friends (26%) and rent with a contract (13%) and without a written contract (13%). Less than 2% of the respondents live in houses with floor materials considered inadequate by the Ministry of Housing in Colombia. Close to half of the respondents (49%) do not have children living with them, 22% have 1, and 19% have 2. 51% of the individuals in the sample are heads of their household, with 58% of these individuals self-identifying as men and a quarter being single-headed households (Figure 3).

Figure 3. Dashboard of respondents and MTW users’ characteristics in Soledad.

All the surveyed inhabitants have used MTW at least once in their lives, and 14% use these vehicles as their main mode of transport. Users of MTW as the principal mode of transport combine it with walking (42%) or use it exclusively. Only 1% of the respondents combine their main mode of mobility with another use of MTW. Half of this 1% of users of MTW as a complementary mode are bus users, and a third are motorcycle taxi users. The majority of users are women (80%), and the main activity is running errands (57%), followed by work (21%) (16% with contract, 6% without contract), leisure activities (9%) studying (5,8%). A third of the respondents with disabilities are MTW users. Regarding the other sociodemographic characteristics, the distribution is similar for all the transport modes: around 40% of MTW users identify as Mestizo, 33% as none, and there is some variation in users, 10% more MTW users identifying as Afrodescendant instead of White compared to other modes. Around 19% of users are older than 60 years old or younger than 25, and 66% are between 25 and 59 years old. Regarding education, 20% of respondents with primary education use MTW, and a similar percentage uses the bus (25%). Inhabitants with university and postgraduate degrees use predominantly private modes (73%).

Regarding modal share, MTW were the third preferred option for daily travel in Puerto Viejo (13.5% of respondents reported this is their main travel mode) and Soledad (14.17%). While in Soledad, buses are the most used transport mode (28.35%), buses in Puerto Viejo were the least used (6.8% of responses), and travel by private car is the mode of transportation of 42.6% of the surveyed. The second most used mode in Puerto Viejo is the bicycle (20%), while in Soledad, they are private motorcycles. In relation to other small-capacity modes of transport that exist in grey regulatory areas, like “pirate taxis” in Puerto Viejo (6%) and motorcycle taxis in Soledad (9%), MTWs are more used in both areas (Figure 4).

Figure 4. Distribution of the most frequently used mode of transport in Soledad and Puerto Viejo.

Trip length in MTW is generally short. More than half of the trips in tuk-tuks were between 5 and 10 min, and only 8% took more than 15 min (Figure 5). According to the trips recorded by the MTWs in Soledad and users’ responses, the average distance of the trips is 5.5 km. Similarly, in Soledad two-thirds of the trips are less than 20 min, and only 11% are longer than 30 min. Regarding frequency, most responses show that MTW are used several times a week, or at least once a week and several times a month. In Puerto Viejo, there are also a lot of occasional users and people who have only used the MTW once. This could be explained by the number of tourists who answered the survey and might have only used the MTW while visiting Puerto Viejo.

Figure 5. Length of trips taken on MTW in Puerto Viejo and Soledad.

6.1.2. Geographical and temporal access

To evaluate the relation of MTW to the fragmentation–inaccessibility–exclusion process, we start with the geographic and temporal distribution of this form of mobility in the two case studies. The types of trips that are characteristics of MTW users are also interpreted as indicative of their function within this process of fragmentation-inaccessibility and exclusion from the geographical and temporal dimensions of exclusion. Additionally, we consider the rationale of MTW in choosing this form of mobility to understand their functionality further.

The similarity of uses of MTW in the two case studies considering the different scales and urban trajectories highlight the predominant role of MTW in complementing higher capacity public transport with short, frequent, and flexible trips that enable access to otherwise inaccessible locations. In Puerto Viejo, buses are the only form of high-capacity public transport, with the central bus station close to the beach line. Buses have regional destinations, including San José (Costa Rica’s capital) the center of the province of Limón, and other areas such as Cahuita, Sixaola, and Manzanillo. Taxis and MTW are the other two forms of public transport. In contrast, access to taxis is limited as there are only three authorized providers, and two MTW stations are located in the two extremes of the city’s core. The distribution of destinations all around the surrounding area of Puerto Viejo shows their geographic coverage (Map 4), The main destinations for MTW trips are the towns around Puerto Viejo, many of which have beaches, hotels, and other attractions. Also, many trips are made to downtown Puerto Viejo. The workshop with MTW drivers, the user survey, and records from the MTW providers and MTW Call Center show that MTW services provide access to places in the Puerto Viejo area that are not connected by bus services. These include, for instance, gravel roads that connect the beach area to hotels or restaurants that are deeper into the mountain area (see Map 5).

Map 4. Main points of access and destinations of public transport in Puerto Viejo and surrounding areas.

Map 5. BRT trunk and routes 300 and 500 m buffer access.

In Soledad, high-capacity public transport includes a Bus Rapid Transit (BRT) trunk, feeder routes, and collective bus providers. Three BRT stations are fed by twelve feeder routes running from 4:45 or 5 am to 9:40 or 10:38 PM on weekdays from east or west to the trunk that divides the city into two areas ( Map 5). Soledad’s collective buses run predominantly from north to south and back, with only two routes connecting the city’s east to west (Map 6). It is also possible to see in the destinations of users of public transport modes other than MTW (i.e., bus and BRT) that most trips are directed outside Soledad (Map 7). On-demand, intermediate capacity services include MTW, motorcycle taxis, and taxis. In Soledad, these modes have no specific stations but the main hubs identified were located outside all four major shopping malls and chain supermarkets and the three BRT stations. Based on the user survey, the coverage of MTW shows predominantly trips that connect the east to the west, excluding the most western parts of the city. Based on the sights from fieldwork, the review of Google Street View, and the mapping of origins and destinations of respondents of the survey that use MTW as their main transport mode (Map 8), it is possible to argue that MTW increases Soledad’s connectivity, thus contributing to reduce geographical conditions of exclusion.

Map 6. East–west routes identified in Soledad.

Map 7. Origin-destination of all transport modes in Soledad.

Map 8. Origin-destination users of MTW as the main mode of transport.

Regarding temporal access in Soledad, it is important to note that the mobility of respondents in the sample is characterized by the flexibility of leaving and returning journeys (71%). Based on the schedules of MTW users (Figure 6), we identified positive contributions of MTWs to the temporal accessibility of Soledad’s inhabitants that require services before and after the bus and BRT start operating. The positive contribution to temporal access is stronger in the case of Puerto Viejo. Considering the limited-service hours for the bus operation (see Appendix), where maximum frequencies are of one service per hour, and the latest hour being 6 pm, the availability of MTW increases access to transport services throughout the day. There are few taxis available in the area, and they seem insufficient for the local demand. In contrast, the two MTW stations identified where 35% of respondents to the survey accessed the service, always had vehicles available and there was a call center that provided services at all hours. There are also options to coordinate trips using WhatsApp (26.3% of respondents) or via cell phone calls (14%). Similarly, the rationale given by the respondents of the surveys in both cases shows that the contribution of MTW to temporal and geographic access is stronger in Puerto Viejo. In the case of MTW users in Soledad, short distances (25%) and comfort (22%) are the main reasons to choose these vehicles as the main mode of transport. Less than a tenth of Soledad’s MTW users (7%) chose “no having any other option” as their reason to use this mode. In Puerto Viejo, the reasons most respondents use MTW are because they are convenient (45%), it is fun to drive them (40%), and to travel short distances (40%).

Figure 6. Hours of travel of MTW users in Soledad.

In both cases, MTWs improve the integration and connectivity to existing public transport services. In Puerto Viejo, MTW reports show that a common trip is early morning runs (between 4 and 6 am) to take passengers to the local bus stop to take the only bus service to San José or the early services going to Limón. In Soledad, three major hubs are the BRT stations. However, in Puerto Viejo, MTW services are mainly in the surroundings of Puerto Viejo’s urban area, and most trips are roughly 5.5 km long. As a result, the population segregated from urban areas, predominantly indigenous people use these services only sporadically to come to Puerto Viejo for special events or run errands. The very few registers of trips to the areas where the indigenous population is located point to their reliance on other transport modes as well as lower frequency of trips. Similarly, in Soledad, in the north-west and south-west parts of the city, where less consolidated neighborhoods are located- the origin-destination map (Map 8) has fewer observations, pointing to a coverage limitation in the contribution of MTW to reduce geographical exclusion. During informal conversations with drivers, some mention that these areas are avoided because of the state of the roads or safety concerns.

6.1.4. Economic affordability

Identifying the function of MTW play regarding exclusion due to economic affordability of mobility is limited in Puerto Viejo to the nature of the online tool. Within the respondents, users consider that the tariffs of MTW are neither very cheap nor very expensive (35%), yielding mixed perceptions about the affordability of these services. Determining if MTW are increasing accessibility in terms of economic affordability in Puerto Viejo requires further research. In Soledad, being cheap is only chosen as the main reason to use MTW by 4% of users (Figure 7).

Figure 7. User perceptions of MTW cost in Puerto Viejo.

MTW tariffs are not regulated in Soledad or Puerto Viejo and therefore are defined by drivers and their bargaining with users. In both cases, attempts to agree on prices are not always successful. In Puerto Viejo, some drivers do not adhere to agreed tariffs. Others stick to agreed tariffs during the daytime but raise their prices during hours when there are no other transport options, for example at night and before dawn. An example is the early morning runs (between 4 and 6 am) to take passengers to the local bus stop in Puerto Viejo to take the only bus service to San José or the early services to Limón. Similarly in the case of Soledad, taking MTW to get to the BRT stations increases the total cost of travel compared to using the system feeders with an integrated fare. In contrast to Puerto Viejo, bargaining in Soledad might enable some users to access mobility at a lower price when their capacity to pay is lower. However, there is also an exclusionary dimension when the driver sets a higher tariff for those users who need to access more peripheral areas. Furthermore, the tariff and use of the service fluctuate at the times of the month when salaries are paid. The fluctuation of demand to the times of the month when people have more disposable income might signal that MTW in Soledad can often be a luxury rather than contributing to accessibility through improved economic affordability. Overall, the lack of clarity or standards for tariffs poses a risk for users, as there is often no certainty about how much they will have to pay for a service and nowhere to turn if they feel they have been overcharged for it.

6.1.5. Fear of crime, harassment and injury

The operation of MTW in Puerto Viejo became mainstream in Costa Rican media after news about a case of sexual assault linked to MTW (Muñoz, 2022). The case has not been resolved but it generated a stigma for the use of these services. However, our user survey found that perceptions of safety while using these services are relatively high, with a 3.8 out of 5 average rating, and a majority of users (42%) feeling safe (ranking of 5/5) while using the service (Figure 8). Regarding fear of injury, there is no available data on road accidents, injuries, or death in the region.

Figure 8. Perception of safety while riding MTW in Puerto Viejo.

In Soledad, fear of crime or harassment and road safety for users of MTW is analyzed based on four questions: how the person felt when using each mode of transport, the reason why they use the vehicle they use more frequently, the perception of safety, and the selection of the mode of the safest and most secure mode of transport. “Calm” was the feeling chosen by most MTW frequent users (28.7%) followed by “alert” (26%) and “comfortable” (20.5%). The feelings chosen by MTW users follow the distribution of the overall sample for this question. When asked about safety, three times more respondents considered that their form of mobility is safe (33%) compared to unsafe (12%). Most MTW users do not think that the mode is safe or unsafe (16% chose very unsafe and 9.6% very safe). Only 3% perceived MTW as the least likely to have an accident and 2% as the least likely to be robbed while using it. Considering the maximum speed that MTW can reach (65 kmh) and the available data of road accidents in Soledad, from the National Police (injuries and deaths reported), MTW are arguably safer than other small-scale vehicles like motorcycles and automobiles, both for users as for other users of the street like pedestrians or cyclist. From January 2010 to 31 July 2023, none of the 298 deaths and 370 injuries reported by traffic accidents involved an MTW in Soledad. 86 of the 298 deaths involved a motorcycle and 182 involved cars.

In the case of Puerto Viejo, authorities’ main response to ensuring safety while using these services is periodic traffic control operations where they confiscate or fine MTW operators (Chinchilla, Reference Chinchilla2022). When MTW suspend their operations because of police presence, people must find other alternatives to get to their destinations, often walking or cycling. The lack of safe pedestrian or cyclist infrastructure makes active mobility unsafe, especially at night. Furthermore, MTW provides services for people who want to attend a party, drink, and not have to drive back home. When these services are unavailable, they suggest there might be a risk of increased drunk driving because regulated taxis in the area are insufficient to cater to existing demand.

6.2. Environmental effects

6.2.1. Air quality

The results of the measurement of PM2.5 and PM10 show constant behavior (Figure 9), except for around the measurement time of 10:38–10:39 when the vehicle stopped to give way to several other vehicles on a narrow bridge. From 10:27 to 10:31, there was an entrance to a gravel street. This is a very visited road since it leads to one of the favorite beaches in the area. The gravel road implies the presence of more dust and particles in the measurement. This situation can happen in several secondary streets in the area due to the material from which they are made. In the first minutes of the trip, no external situation was noted down that could have caused higher peaks.

Figure 9. Measurement of PM2.5 and PM10 in an MTW in Puerto Viejo.

When comparing the average values obtained in this exercise with those established by the World Health Organization (WHO) (2021) and the Air Quality Regulation for Pollutants Criteria of Costa Rica (2016), the values are lower than those established as maximum. The Costa Rican regulation recommends, on average, 35 μg/m³ for PM2.5 and 100 μg/m³ for PM10, while the WHO recommends 15 μg/m³ for PM2.5 and 45 μg/m³ for PM10. With a general average value in the measurements of 1 μg/m³ for both PM, the overall outcome remains within the recommended values. The fact that Puerto Viejo is a coastal town, not very developed, with low vehicle density, and the main roads where measurements were taken are very near to the coast contribute to a low concentration and quick dispersion of pollutants.

For Soledad, the team calculated the average PM2.5 concentration for all the trip routes measured. In contrast with Puerto Viejo, during weekday rush hours in the mornings and afternoons, and weekend values (Figure 10) are higher than the 2021 recommended values of the World Health Organization (15 μg m⁻³) and the Colombian government (37 μg m⁻³). Significant location differences exist, with the highest values obtained during traffic congestion. Results evidenced high PM2.5 levels (average 39.7, 23.6, and 19.7 μg m⁻³), with the highest value of 959 μg m⁻³ in the morning peak. Lower concentrations were obtained on weekends, demonstrating the traffic influence in PM2.5 personal exposure. The location also influences the pollution patterns (Figure 11) that are not uniform throughout the territory; concentration peaks (red color) are recorded in locations with high vehicular flow and traffic light stops. For the morning peak period, the 77.8% of km traveled within the sample design exceeded the permissible limits established by local and international regulations for PM2.5, 37 μg/m³ and 15 μg/m³, respectively. Similarly, lower pollution magnitudes are observed for the weekend compared to the morning peak, with 63.2% of km traveled within the sample design exceeding the permissible limits.

Figure 10. Measurement of PM2.5 in MTW trips in Soledad.

Figure 11. Spatial distribution of PM2.5 concentrations in the road network assessed in the morning peak.

The substantial differences between the two case studies as well as the variation in the measurements in Soledad dependent on other sources of pollution, point to the small contribution of MTW to air pollution.

6.2.2. GHG emission estimates

An analysis of 38 license plates obtained from the site visit to Puerto Viejo and a database containing a list of vehicles and drivers provided by one of the operators in the area found three main types of vehicle models operating in the area: Bajaj RE 4S (79% of all the sampled vehicles), Piaggio Ape City (16% of all the sampled vehicles), and TVS King Deluxe (5% of all the sampled vehicles). All MTW found in Puerto Viejo use four-stroke engines (two-stroke engines are illegal in Costa Rica) and use gasoline. Most vehicle models range between 2018 and 2019, the average model being 2019 (Figure 12). The three existing regulated taxis in the area are a 2006 Peugeot Partner (diesel fuel), a 2010 Daihatsu Terios (gasoline fuel), and a 2009 Mitsubishi L200 (diesel fuel).

Figure 12. Distribution of MTW vehicle models and ages in Puerto Viejo.

Based on the data, the Bajaj RE 4S was used as the default vehicle type for estimating GHG emissions. For Puerto Viejo, the emissions for the total of km that each MTW travels per working day are 9.54 kg CO₂ eq. Our calculations showed that if these trips were made with the taxis available in the area, the total emissions would more than double, resulting in 19.2 kg CO₂ eq. In a more optimistic scenario, if all these trips were made using Toyota Yaris 2022 sedan vehicles to substitute MTW, the total emissions per vehicle in a working day would be 15.2 kg CO₂ eq, 55% higher than the emissions from the existing MTW. Because Puerto Viejo and its surrounding area is semi-rural and has many gravel roads, this scenario is unrealistic but valuable, considering sedans are the most common vehicle used for cabs in Costa Rica. The comparison with taxis and not with nonmotorized options such as bicycles or pedestrians responds to the similarity of use of the two modes. The weather conditions of Puerto Viejo—average temperature is X—make nonmotorized modes more strenuous and less likely to be a substitute for motorized modes (Table 3).

Table 3. Comparative GHG emissions per vehicle per year according to different vehicle typology

In Soledad, based on the average distance traveled (Figure 13) and the vehicle efficiency for each vehicle type (Table 4). The GHG estimation for Soledad showed that emissions for the total km traveled by MTW vehicles are 7940.15 kg CO₂ eq/day, reaching 2860 Ton CO₂ eq/year. These calculations show that 1.72% of the emissions generated by the vehicle fleet are present in the study area. If these same trips were made by other modes such as motorcycles or cars, emissions would reach 17% and 21% of the emissions generated by the entire vehicular flow.

Figure 13. Distribution of distance traveled by each vehicle category in Soledad.

Table 4. Comparative GHG emissions per vehicle per year according to different vehicle typology

7.1. Increasing geographical access

MTW fit within gaps produced by the specific trajectories of the development of transport systems in Puerto Viejo and Soledad, playing a role in supplying transport at different scales of operation and spatial coverage. The flexibility in the operation of these services has enabled them to adapt to changing supply conditions over time. Different strategies were identified for adapting to the changing geographies of transport supply: to establish hubs or service areas or corridors that respond to the functional configuration of the urban spaces in which they operate, and which find synergies with existing land uses and terminals for other transport services for increasing demand. This is consistent with research both within and outside Latin America and the Caribbean.

Considering the more rigid schedules and operation patterns of competing transport services in both contexts, MTWs also fill temporal gaps in transport and account for the diversity of users meeting their needs at “unusual” hours for the local context. As such, MTWs address some of the localized complexities of the temporal dimension of accessibility, albeit at a premium, potentially pricing out poorer users when they may need access to public transport the most.

7.2. Reducing exclusion from facilities

The use patterns of MTWs are closely linked with their ability to provide access to different opportunities in each context. The distribution and functioning of facilities where different activities can be completed refer to the land-use component of accessibility and the individual characteristics of those seeking to carry out such activities. In both cases, centralization of facilities and well-defined infrastructure corridors predetermine what neighborhoods are more accessible.

Similarly, how well MTWs adapt and respond to these configurations determines their contributions to access relevant social inclusion opportunities. MTWs are instrumental in securing access to employment in both case studies, particularly for groups often excluded from conventional public transport, such as shift and night-time workers. This is consistent with the literature on social exclusion in the LAC context, which suggests that popular transport plays a fundamental role in securing access to income above other opportunities. Interestingly, the evidence does not suggest that MTWs play a similar role in enabling access to education. A limitation of this study is the lack of evidence from minors due to ethical concerns. This warrants further investigation as available data in this segment is scarce.

The analysis of the selected contexts shows the relevance of different driving local economies. In the Puerto Viejo area, MTW’ role in ensuring connectivity and access to mobility for touristic activities and sites has become essential. Their relevance for safely and easily accessing recreational activities in both cities at night should also be considered. The interruption of these services can result in economic impacts for residents, local businesses, drivers, and tourists, in addition to the exclusion of certain populations without access to a motorized vehicle to access these types of activities. Furthermore, evidence about travel for leisure in both cases shows that MTWs in Soledad serve a more disadvantaged population than they do in Puerto Viejo. This, however, does not reduce the relevance of these services for vulnerable populations, who reported using them for social interactions and accessing open green spaces. Enabling coverage of traditional services and their availability in accessible and affordable spaces for leisure, recreation, and sports may go a long way in improving the accessibility of low-income residents to these opportunities.

While the evidence about care mobilities is limited, errands were identified as a relevant travel purpose being addressed by MTWs in both cases. This is consistent with findings emerging from the analysis of the geographic dimension of social exclusion that highlighted the flexibility of these services to respond to needs addressed with diverse locations and times. MTWs hold significant potential for improving access to care facilities such as hospitals, particularly when transport supply is scarce. However, they require support, and integration with these facilities, which is currently absent in the two case studies.

7.3. Changing the affordability of transport

Fares and their integration are significant drivers of (in)accessibility and can constitute a barrier to inclusion. As such, MTWs adapt to current fare schemes for individual and collective transport in both cases, being influenced differently by regulations, involving imbalances in power, and mediating relationships between suppliers and users that ultimately enable or restrict access to specific opportunities. Given the informal nature of MTWs, the relationships between service providers and users are often unequal, opening room for irregular fares and excessive premiums on services in areas or times with limited or no coverage of alternative transportation. This is the dimension of social exclusion where MTW are less likely to make positive contributions. Lack of fare control and enforceable pricing standards restrict the increase of fares for vulnerable populations. Nonetheless, the literature has pointed to the potential of popular transport for building social capital between users and providers, enabling better affordability for users with limited purchasing power or in conditions of social vulnerability.

7.4. Reducing fear of crime, injury, and harassment

Pockets of exclusion tend to be pockets of insecurity, and MTWs respond differently to the spatial distribution of crime and the enabling conditions of other drivers of fear, such as perceptions of insecurity, fear of injury, and sexual harassment. In line with research about subjective perceptions of transport systems, safety and security are often governed by the public’s image of other transport modes and public space. Stigma associated with crime and violence can linger in the collective conscience, changing perceptions about transport modes, and often leading some social groups to avoid them altogether. Despite this, the relationship between perceived insecurity in MTWs is at odds with the perceived insecurity at specific times of the day or in parts of the city.

Filtered by gender, the experience is distributed in the same quarters. The difference in perceptions between men and women regarding safety was similar to the one found for comfort.

The lack of involvement of authorities, beyond attempts to fine or confiscate MTW, is perpetuating the inequalities and vulnerabilities of drivers and users regarding job precarity, affordability, and safety of these services. Measures intended to improve the safety of MTW users must not unintentionally result in increasing other types of risks. Any policies aiming to tackle insecurity in the sector must be accompanied by an integrated approach to safety and mobility and ensure that people are not left without options to move in a safe and efficient way.

7.5. Addressing the needs of the vulnerable

Beyond stigma, fear, and safety concerns regarding these services, women continue to use them and are the majority users of MTW in both case studies. This implies a need to use these services even if they do not constitute the ideal user experience for this population. Improving the safety and experience of using MTWs will be key to reducing the vulnerability of these users. In Soledad, a third of the disabled respondents are MTW users.

Although operators suggest that they provide services for a wide diversity of users, further research is recommended to determine whether these services are actually improving transport access to these specific populations.

7.6. Environmental impacts and externalities

The urban configuration, mobility system, and city typology in each case study generated very different results in terms of air pollution between Soledad and Puerto Viejo. Puerto Viejo’s low-density urban configuration, with small-scale coastal developments, high presence of natural landscapes, and a small-scale vehicle fleet, and road network has maintained good air quality levels. On the other hand, Soledad’s larger urban scale, density, and vehicular dynamics have affected air quality levels and increased exposure to drivers and passengers as well.

Regarding GHG emissions, both cities showed that the use of MTW contributes to lower emissions mobility. If MTW trips were substituted by trips with other existing transport modes (including motorcycles), emissions would increase significantly. Regulatory efforts to ban these types of services reduce mobility options for users and go against transport decarbonization goals.

Although MTW vehicles contribute less to the CO₂ eq emissions in the study areas, particularly in Soledad, they are exposed to high pollution levels from other vehicles, adding vulnerability to drivers.

7.7. The positive and negative effects of MTW on accessibility and social exclusion

In this section, we engaged in an in-depth analysis of the influence exerted by MTW on the cycle of inaccessibility and social exclusion. We observed that MTW constitute the third principal mode of travel in Puerto Viejo and Soledad, albeit operating within distinct temporal frameworks. This revelation holds considerable significance, especially when juxtaposed against the backdrop of the dissimilar scales and urban configurations characterizing our two selected case studies.

Exploring MTW’ influence on the inaccessibility-social exclusion cycle unveils a multifaceted spectrum of positive and negative impacts. While MTWs address critical gaps in geographical access, contribute to employment and care mobility, and offer lower emissions mobility, they also exhibit shortcomings in affordability, safety, and potential environmental consequences. Regarding affordability, the irregular fare structures and varying premiums of MTWs can result in irregular pricing, potentially excluding economically vulnerable individuals. Additionally, the uneven perception of safety associated with MTWs, particularly among women, highlights areas where further improvements are needed to alleviate concerns. Moreover, MTWs may contribute to congestion and air quality issues in denser urban areas like Soledad, adversely impacting the overall urban environment. Acknowledging these nuanced dynamics is vital for informing policy decisions that harness the positive attributes of MTWs while mitigating their negative repercussions.