Flying Cars Will Undermine Democracy and the Environment

Flying Cars Will Undermine Democracy and the Environment
Getty/Alain Jocard/AFP

A flying car prototype developed by Airbus and Audi is pictured at an exhibition in Paris, May 2018.

Introduction and summary

Recent advances in lithium-ion batteries have opened the door to flying car development.1 At least 20 companies are currently working on novel designs, including both major aerospace firms such as Boeing and Airbus as well as smaller startups.2 A Morgan Stanley analysis estimates that the global market for on-demand, short-distance urban air travel could top $850 billion by 2040.3

Unfortunately, flying cars represent the technological apotheosis of sprawl and an attempt to eradicate distance as a fact of life for elites who are wealthy enough to routinely let slip the bonds of gravity. Proponents offer a utopian vision of seamless convenience and efficiency that delivers broad-based societal benefits. The inevitable reality is that flying cars will confer advantages on direct users while exacerbating the geographic isolation of elites—a spatial manifestation of deepening inequality that undermines the shared experiences that are necessary to sustain democracy. Additionally, removing distance as a constraint in metropolitan development and land use will have profoundly negative consequences for the environment.

The desire for transportation-induced isolation is not new. In the 20th century, interstate highways served as the conduit for racial, ethnic, and income segregation. The combination of expanding automobile ownership and supportive infrastructure allowed developers to tap into vast stretches of land around center cities. By reducing the friction of distance, highways acted as a centrifugal force on cities, undermining through sprawl the racial integration that political movements and courts had sought to implement.

Flying cars threaten to magnify the corrosive effects—both sociopolitical and environmental—of sprawl and segregation by eliminating distance altogether. For the wealthy, the magnetic attraction to flying cars derives from their ability to connect in a few minutes the walled garden of home to the rich cultural amenities and economic opportunities of metropolitan life. In short, the high-speed transportation service that flying cars provide will help elites achieve a dual demand for hyperseclusion and hyperaccess.

When discussing elites and flying cars, it may be tempting to think of the people who regularly land on Forbes’ billionaires list. However, the target demographic for short regional flights is actually highly paid professionals. The commercial vision is to offer flights at a price point that generates regular demand. To bring flight costs down, the annual production of flying cars needs to reach a level sufficient to trigger significant economies of scale. Otherwise, according to Uber, flying cars risks becoming “a cottage industry for the wealthy not unlike Lamborghinis.”4

The issue of scale is important. If flying cars only provided the occasional trip to a few centimillionaires or billionaires, the effect on society would be negligible. The technology would be just another toy in the stable along with exotic cars and megayachts. Yet, if the technology becomes more ubiquitous, the effect will become substantially more threatening.

Flying cars represent a political danger because they will allow wealthy elites to further opt out of common institutions and everyday experiences, deepening social segregation. The biggest societal challenges such as combating climate change or alleviating poverty can only be solved through persistent, collective action. Yet, it’s hard to fashion a broad-based political project if the most sophisticated and powerful actors live in a parallel society decoupled from the problems in need of solutions. Substantive democracy is a way of life, a mechanism to facilitate the give and take of ideas and reconcile divergent interests. This process relies on shared experiences, and it requires more than a narrow adherence to the procedural act of voting.5

The technology also presents a significant environmental threat because it will unleash development of pristine lands heretofore unattractive because of the limitations of distance and travel time. These lands provide essential environmental services related to air and water quality as well as carbon sequestration. The fact that most flying cars will be battery-electric vehicles is irrelevant. Any direct emissions reductions from electric drivetrains will be offset by the indirect emissions that result from lower-density regional land use.

Before flying cars can become a reality, technology entrepreneurs must convince elected officials and the public that their new invention will deliver substantial, broad-based benefits. In short, they will argue that the technology functions as a quasi-public good worthy of favorable regulatory treatment and robust infrastructure subsidies. Yet, there is little reason to believe that flying cars will accomplish anything more than extending the equivalent of on-demand helicopter travel to a wider circle of elites. For this reason, the development and implementation of flying cars should be an exclusively private endeavor. Furthermore, the negative political and environmental consequences of the technology may eventually require government to levy use taxes, zoning, and airspace restrictions to reduce demand.

Flying car and VTOL technology

Mention flying cars to someone and they are likely to envision a real-life version of “The Jetsons.” The actual vehicles under development that carry the label of flying cars are typically a cross between a helicopter and a small airplane. Some look like a human-sized quadcopter drone while others look like a hypermodern Cessna with multiple propellers. The one characteristic that all of these prototypes share is the ability to carry out vertical takeoffs and landings (VTOL). Flying cars need to be able to take off and land without runways to operate in urban environments. Throughout this report, the terms flying cars and VTOLs will be used interchangeably.

Left: Rendering of VTOL concept provided by Rolls-Royce. Right: Rendering of VTOL concept provided by Uber.

The engineering challenges facing flying cars are manifold. The most daunting obstacle to deployment is the limitations of current lithium-ion batteries. Battery-electric VTOLs are preferable to traditional combustion engines because they are significantly quieter and release no emissions at the point of use. The importance of these two characteristics cannot be overstated since excessive emissions and noise would result in massive community opposition. The prospect of bringing airport-level noise to dozens or even hundreds of area rooftops would be enough to short-circuit VTOLs in the planning stage.

However, current battery technology is lacking in three important ways: First, batteries are too heavy and store too little energy, limiting the load and range of VTOLs; second, charging speeds are too slow, reducing total daily revenue service hours and, by extension, the profitability of each vehicle; and third, current batteries lose charge capacity quickly, shortening the period during which a battery pack is commercially viable for aviation use.6

There is also the issue of vehicle design and certification. The flying car prototypes that are under development attempt to combine the best characteristics of airplanes and helicopters. The advantage of helicopters is that they allow for vertical takeoffs and landings. However, helicopter blades provide little lift, making the vehicles highly energy inefficient. By comparison, airplane wings provide substantial lift and energy efficiency during flight, but planes require runways.

The resulting hybrid designs are completely novel and include both wings and multiple pivoting propellers. The technology community’s goal of industry disruption by moving fast and breaking things may work well when developing smartphone applications, but it becomes deeply problematic when the product involves human flight. Under federal law, the Federal Aviation Administration (FAA) must certify new aircraft designs and avionics systems.

The two recent fatal crashes of Boeing’s 737 Max aircraft demonstrate the tragic consequences of system failure and poor regulatory oversight. The 737 Max crashes are especially relevant to the development of flying cars because they involved the failure of automated flight control systems.7 As a 2016 white paper by Uber states, “Over time it’s highly likely that VTOLs will become autonomous, though we expect that initial operations will require pilots.”8

Finally, deployment of flying cars will require dramatic upgrades to air traffic control (ATC) systems and procedures. The existing ATC system was developed to handle commercial aviation traffic into and out of airports. At commercial airports, flights are scheduled and follow established air corridors. Even at modest scale, the presence of flying cars in urban airspace will present significant operational challenges and the potential for routing errors that lead to deadly collisions. Moreover, in addition to the potential of flying cars, urban airspace is going to experience a rapid influx of drone delivery vehicles. The FAA estimates that by 2021, there will be more than 420,000 small drones or unmanned aerial systems providing commercial services from package delivery to crop and bridge inspections, among many others.9 The FAA anticipates that these systems will quickly become larger and no longer rely on a human operator with a visual line of sight. Safely accommodating flying cars and drones will require additional infrastructure, personnel, and the eventual automation of many ATC functions for low-altitude flight.10

Taken together, these challenges make it difficult to predict when VTOLs will begin providing regular commercial service. Yet, it is a certainty that these vehicles will arrive.

The issues of subsidies and congestion

To deploy flying cars in meaningful numbers, private industry will need substantial public support in the form of favorable regulations, expensive infrastructure improvements, and even operating subsidies. This support could include direct public provision of essential infrastructure facilities. For instance, a state department of transportation may decide to build takeoff and landing pads, storage and maintenance yards, and charging sites in a bid to attract VTOL service providers. Governments frequently build new parking decks, industrial parks, and highway interchanges to serve particular businesses—to say nothing of offering generous tax credits and abatements.

Public subsidies could also flow to VTOL operators indirectly. For example, general aviation aircraft—both corporate jets and personal aircraft—cover only a fraction of the ATC costs they impose on the national airspace system through fuel taxes paid into the Airport and Airway Trust Fund.11 In effect, large commercial carriers and passengers subsidize general aviation with the taxes and fees they pay to fly. Both drone and flying car operators could similarly benefit if the cost of ATC modernization and operation is covered by federal appropriations and taxes paid by commercial air carriers and passengers.

Proponents will argue that flying cars will deliver broad public benefits, including reduced roadway congestion and the option value of having access to an additional transportation mode, even if most people never use it or use it infrequently. Unfortunately for VTOL boosters, there is no reason to believe flying cars will improve terrestrial mobility. The benefits of flying cars will overwhelmingly accrue to the fortunate few who are able to afford the service as well as the web of private industries that build, operate, and maintain the vehicles and related systems.

The reason is that flying cars will be small, carrying only two or three passengers per flight. Additionally, VTOLs will require a significant amount of airspace to operate safety. Standing on the ground and looking up provides a misleading sense that the sky has a nearly unlimited capacity to accommodate flying cars. In reality, airspace becomes congested much more quickly than a roadway. A car traveling on an arterial roadway needs modest spacing from other vehicles to ensure safe operations. For instance, the stopping sight distance for a vehicle traveling at 15 miles per hour is 80 feet.12 At 45 miles per hour, the distance jumps to 360 feet.13

Depending on altitude, speed, and aircraft systems, the FAA requires commercial airplanes traveling in the same direction to maintain 30 to 50 nautical miles of lateral (i.e., side-by-side) and longitudinal (i.e., following distance) separation.14 Uber’s white paper envisions vehicles with a cruising speed of 150 to 200 miles per hour. A flying car traveling at a speed of more than 150 miles per hour—without the benefit of antilock brakes and subject to the unpredictable forces of air currents—will need extensive vertical, lateral, and longitudinal clearances to operate safely.

An additional capacity constraint is that both VTOLs and drones may have to operate within a relatively narrow low-altitude band. Currently, NASA and the FAA are working on different technological approaches for handling autonomous drone traffic below 400 feet. These efforts include “airspace design, corridors, dynamic geofencing, severe weather and wind avoidance, congestion management, terrain avoidance, route planning and re-routing, separation management, sequencing and spacing, and contingency management.”15 Many of these same challenges apply to VTOLs as well.

While the FAA has not made final decisions about airspace design, it is likely that flying cars would operate above the 400-foot drone threshold but below the airspace set aside for traditional commercial aircraft. Finally, commercial service airports would need to maintain their extensive airspace exclusion zones. In metropolitan regions with multiple airports, known as metroplexes, these exclusion zones would meaningfully restrict service operating areas for flying cars, just as they do for drones today.

Because VTOLs are an emerging technology and the FAA has not finalized its ATC procedures, there is no standard methodology for calculating the theoretical carrying capacity of regional airspace for short-hop flights. Yet, small vehicle size, spacing requirements, and limited operational airspace make it clear that flying cars will not provide the carrying capacity of either highways or public transportation.

To put the issue in context, each lane of an access-controlled highway can carry a maximum of approximately 2,200 cars per hour.16 According to the 2017 National Household Travel Survey, the average light-duty vehicle occupancy rate is 1.7 people.17 Thus, on average, each limited-access highway lane can carry 3,740 people per hour during the morning and evening peak travel periods.18 Transit rail projects can carry even more. For instance, the Metrorail Orange Line in Washington, D.C., which has one track in each direction, carries more than 15,400 people per hour during peak periods.19

According to Uber, “Based on prior helicopter noise sensitivity … the greatest probability of meeting the severe community noise limitations exists with smaller VTOL aircraft that are carrying fewer passengers.”20 The company goes on to state, “Because of all these factors, the payload capacity that likely best serves urban air-taxi flights would be a 2 to 4 passenger-size aircraft (including the pilot, if there is one).”21 Given these limitations, it is likely VTOLs will carry at most three passengers per flight. How many VTOLs would it take to achieve the carrying capacity of one highway lane? Assuming every flight carried three passengers, the answer is 1,246 flying cars in the air at the same time.

However, this estimate is low because VTOLs will make many flights without any passengers—an activity known in the industry as deadheading. A flying car that transports someone from an outlying area into the central business district during the morning peak period may have to deadhead back out to an exurban location for the next paying customer.

Research on taxi and ride-hailing companies such as Uber and Lyft suggest that deadheading accounts for approximately 40 percent of all vehicle miles traveled.22 While ride-hailing and short-hop flights are not perfect correlates, VTOLs will need to fly empty on a regular basis. This means that achieving the capacity of one highway lane could require more than 2,000 VTOLs in operation at the same time.23 To put this number into perspective, it’s more than the total number of commercial carrier takeoffs and landings at Los Angeles International Airport every day.24 It’s hard to imagine even a large metropolitan area accommodating this level of air traffic demand, let alone what would be necessary to equal the capacity of a high-quality transit line.

Even if flying cars could eventually provide service equivalent to a lane of traffic, it would have no measurable impact on terrestrial mobility. Putting aside the issue of induced demand, adding a single lane of traffic to a bottleneck does not improve regional mobility. This is especially true when considering that VTOLs will offer service over a radius of 60 or 70 miles from the city center. Spreading out any potential capacity gains over a commute shed of that magnitude will result in no measurable effect.

For this reason, any claims by VTOL proponents that their product will deliver benefits for drivers or transit riders on the ground are wishful thinking. Flying cars will only benefit the wealthy few who can afford to use them.

Democracy, elitism, and distance

The idea that deep inequality is incompatible with democracy and the common good is not new. Aristotle argued that any form of government that regards “only the interest of the rulers” is “defective and perverted.”25 More recently, former U.S. Supreme Court Justice Louis Brandeis stated, “We may have democracy, or we may have great wealth concentrated in the hands of a few, but we can’t have both.”26

Political scientist Robert Dahl states that an essential element of democracy is “the continuing responsiveness of the government to the preferences of its citizens, considered as political equals.”27 Extreme income and wealth inequality provides a select few outsized political power that undermines the democratic ideal that all individuals should have equal standing and voice to shape public policy.28 Implicit in this critique is the idea that wealthy elites use their power to advance policies tailored to their narrow interests as opposed to policies that deliver benefits to society at large.

Where does this divergence of interests come from? One answer is that elites live apart from the rest of society in terms of both experience and geography. The theorist Michael Eldridge argues that to be a democrat is “to commit oneself to participation in the intelligent give and take of our common life.”29 In other words, common experience is essential for the formation of a common will.

At a basic level, democracy is a mechanism for building the consensus necessary for sustained collective action to address society’s most pressing challenges. Yet, it’s difficult to form consensus or a common will when the most powerful citizens live fundamentally separate lives. Flying cars will amplify this separation and exacerbate the worst tendencies of wealth, power, and privilege with deleterious long-term effects on democracy.

It may seem like a stretch to suggest that sitting in traffic is necessary for democracy. Indeed, there is nothing deliberative or communal about slogging through a morning or evening commute. The point is not traffic per se but the fact that flying cars will skew the political priorities of elites by allowing them to further opt out of societal problems. People rarely care about issues that don’t affect them. Eliminating distance as a meaningful constraint of daily life is a hyperefficient mechanism for generating elite apathy.

When elites petition the government for a redress of grievances, those grievances will correspond to the unique features of their lived experience. When it comes time to debate the allocation of scarce transportation dollars, elites that frequently glide above the masses are likely to advocate for investments that further their special traveling status. For instance, elites are more likely to push the state to build new landing pads rather than light rail lines. In times of economic downturn, elites who fly are more likely to support air traffic control operators that direct short-hop flights rather than critical bus service with affordable fares. After all, what good is taking a flying car to the symphony if there is no return flight because falling tax revenues have resulted in shorter ATC operating hours?30

It may be tempting to argue that flying cars are a new twist on an old problem since wealthy elites have always been able to purchase exclusive goods and services. However, flying cars deserve special scrutiny because they have the ability to greatly exacerbate the trend of rising social segregation.31 These political implications simply don’t attach to trendy handbags or fancy cars. Consider the case of residential airparks, which are typically vacation homes built around a small airfield. Flying magazine summarizes the value proposition:

For many pilots, the thought of stepping out of the house, getting into an airplane and taxiing just a few hundred feet to the runway—all without ever touching a car door—is the ultimate fantasy. For the thousands who live in residential airparks around the country, that way of life isn’t just a pipe dream but an everyday reality.32

When flying no longer requires a runway and private ownership of an airplane, how long will it take before developers build fly-in, fly-out residential communities meant for everyday living? For decades, private golf courses have served as an attraction and anchor around which to build luxury homes. It doesn’t take a mental leap to see how easy it would be to swap out a golf course for high-end VTOL facilities.

Unlike existing golf course homes, future VTOL communities won’t have to worry about staying within a reasonable driving distance of the metropolitan central business district. The negative social and political implications arise when this type of development reaches scale. Developments that start with a landing pad and a few hundred homes will soon need schools, health care facilities, and other essential services. The risk is that these, too, could be folded into the walled garden—either literally behind the gate or so far removed from the rest of the region as to amount to the same thing.

Of course, this exact outcome isn’t guaranteed. The physicist Niels Bohr once quipped, “Prediction is very difficult, especially about the future.”33 New transportation technologies often produce novel results. However, it’s hard to envision VTOLs creating outcomes that further economic inclusion and democratic cohesion rather than the inverse.

Aristotle argued by way of analogy in Politics that just as “sailors have different functions … they have all of them a common object, which is safety in navigation. Similarly, one citizen differs from another, but the salvation of the community is the common business of them all.”34 At first, this passage appears affirming and optimistic by suggesting that there is a natural tendency for people living in a community to ensure its continued success. Yet, this optimism starts to give way with a simple follow-up question: Which community?

A cosmopolitan is likely to respond that they are a citizen of the world. While this sentiment is touching, history suggests that most people extend the ambit of their moral concern to the people and places they see and visit most often. For the elite residents of fly-in, fly-out developments, the community that is worthy of salvation and the common business of them all is likely to be a narrow one.

Country clubs, private schools, and gated communities have existed for a long time. The danger of flying cars comes from their ability to exacerbate existing patterns of exclusion. The threat is pronounced because the startups and aerospace companies building prototypes are aiming for a price point that, while clearly out of reach for the average traveler or family, will extend the special privilege of flying to a wider circle of elites.

Techno sprawl and sustainability

The brave new world of flying cars will be electric. To many people, battery-electric vehicles represent the pinnacle of sustainability. This view focuses on the first order benefit of eliminating tailpipe emissions. While incredibly important, focusing exclusively on vehicle emissions misses the deeply unsustainable second-order effects that VTOLs will have on land use.

History demonstrates that the introduction of affordable transportation technologies and supportive infrastructure fuels outward expansion. For instance, the modern era of highway construction began when Congress passed the Federal Aid Highway Act of 1956.35 The resulting highway system not only provided for efficient travel between urban areas but also facilitated an explosion of low-density suburban development.

The enormity of the population shift becomes apparent by looking at metropolitan area population density before and after the introduction of interstate highways.36 In 1950, metropolitan regions had an average of a little more than 400 people per square mile. By 2000, when the interstate construction era had ended, the density of metropolitan regions had fallen by a quarter to a little more than 300 people per square mile.37 The change was even more dramatic in center cities. According to U.S. Census Bureau data, the population density within center cities fell from 7,517 people per square mile in 1950 to 2,716 people per square mile in 2000.38

This profound change in settlement patterns has important implications for ecological sustainability. Distance is an emissions multiplier for two reasons. First, low-density development often makes walking impractical and the provision of transit service difficult or cost prohibitive. The lack of options creates auto dependence while lower density means longer vehicle trips. Data from the U.S. Department of Transportation (USDOT) shows that suburban area residents have daily vehicle miles of travel that are approximately 50 percent higher than residents in center cities.39

Second, the development of agricultural or forested land for commercial and residential use entails the loss of critical environmental services, including carbon sequestration and flood-risk reduction. Depending on a number of factors, including the age and type of trees as well as the density of cover, reforested land can sequester anywhere from 1.1 to 9.5 metric tons of carbon dioxide per acre per year.40 Additionally, undeveloped land—especially wetlands and prairies—filter and absorb water and reduce flood risk. For example, the Environmental Protection Agency estimates that an acre of wetland is able to store between 1 million and 1.5 million gallons of water.41

The loss of greenfield land and its environmental services to development is not theoretical. Recent research by Descartes Labs shows greenfield losses to commercial and residential development and other forms of impervious surface over the past decade.42 The intensity and extent of red shows that the trend of outward growth unleashed by decades of highway construction continues even as many center cities experience revivals as well. Flying cars will only exacerbate this trend.

Map showing the growth of impervious surfaces over the past 10 years provided by Descartes Labs.

Beyond land use, flying cars and associated infrastructure represent an enormous amount of embodied energy. Every electric motor, concrete landing pad, and computer system involved in VTOL operations required huge quantities of energy and natural resources to manufacture, transport, and install. Of course, the same is true of every form of transportation. What makes flying cars so deeply unsustainable is the ratio of energy and resource consumption to productive travel—especially when factoring in deadheading.

Then there is the issue of energy consumption from use. In its 2016 white paper, Uber compared the motion efficiency, defined as the amount of energy required to travel a certain distance, of a VTOL with that of an electric car. Uber’s model assumed a trip distance of 50 miles. Both the theoretical scenario and the results are instructive.

Over 50 miles, Uber found that a VTOL traveling at 125 miles per hour and an electric car traveling at 65 miles per hour have roughly equivalent motion efficiencies.43 First, this result is an indictment of the intense energy inefficiency of terrestrial single-occupant vehicle travel—not an absolution for VTOLs. Second, the finding relies on a trip scenario that favors VTOLs but that does not match contemporary travel behavior.

Over short distances and at lower speeds, Uber found that automobile travel is much more energy efficient than VTOLs. Moreover, short-distance, lower-speed travel is the norm. According to the USDOT, the average American drives 29 miles a day, making three vehicle trips of roughly 10 miles each.44 Uber notes that for short flights, “the VTOL is less energy efficient per mile because it spends less time in the more efficient cruise mode while the power required for vertical takeoff and landing remains constants.”45 The energy needed for takeoff and landing is greater for VTOLs than traditional helicopters “because instead of using large rotors to bias the vehicle design for hover efficiency, the VTOLs can focus on achieving low noise and high cruise efficiency.” Thus, Uber chose to model a hypothetical use case that favors VTOL technology.

Looking to the future, the 50-mile use case deserves attention because travel behavior is strongly shaped by technology, pricing, and land use, among other factors. There is no law or principle of physics that requires people to travel 30 miles. This outcome is the result of decades of highway investment by states and the federal government combined with the economic accessibility of automobiles and local government land use regulations mandating low-density development. Stated differently, travel behavior is not fixed. The introduction of VTOLs will profoundly alter daily travel and land use patterns just as highway construction and the proliferation of automobiles did in the 20th century.

The impact on the environment will be substantial and negative because flying cars will allow affluent people to make trips they otherwise would not due to time, distance, or other constraints imposed by terrestrial travel. And there is every reason to believe that longer VTOL trips will not be a substitute for automobile trips but additive, increasing overall energy and resource consumption tied to daily mobility. A technology that starts as a novelty becomes a utility, and business transactions that would have been a phone call become an in-person meeting. Why? Because the technology enables it. For this reason, it is irrelevant to compare the energy efficiency of a longer VTOL trip with that of an electric vehicle since a very high percentage of longer trips would never be made in the absence of the technology. Therefore, from an emissions and resource use accounting perspective, VTOLs should be treated not in marginal terms compared with a terrestrial alternative but as an additional environmental burden.

Innovation and the terms of debate

Technological innovation is often treated as synonymous with societal progress. Starting from this perspective biases the public debate about the proper role of government policy and funding. A better and more nuanced starting position would be to treat technology as neither inherently beneficial or harmful but rather a neutral element that takes on significance based on its use.

For instance, a cellphone may be used to dial 911 in an emergency, helping to save someone’s life; or it may be used to detonate an improvised explosive device on the battlefield. In each case, the technology is the same. The societal benefit or harm is a consequence of how the technology is used. Flying cars, like cellphones, could be used in an almost infinite number of potentially harmful or beneficial scenarios. It is not necessary—or possible—to think through every conceivable use case when crafting public policy.

Instead, when deciding which emerging technologies deserve subsidies in the form of tax dollars and favorable regulations, the debate should focus on the likely overall net effect (i.e., cumulative benefits minus cumulative harms). This approach can be thought of as inherently probabilistic. Emerging technologies are, by their very nature, emerging. This means that policymakers do not have a robust research record of ex post studies. Instead, policy design must largely rely on extrapolation and argument by analogy.

As previously made clear, there is little reason to believe that subsidizing elite demand for hypermobility will produce meaningful positive externalities. This is not to argue that flying cars will not provide marginal benefits to the elites capable of affording the service. However, far from yielding broad-based societal benefit, flying cars are more likely to undermine democracy and accelerate environmental degradation. Flying cars are the mobility equivalent of trickle-down economics.

Therefore, the development and deployment of flying cars should be a completely private endeavor. The only remaining question is whether or not the harms that flying cars cause are sufficiently large as to warrant a pricing mechanism to reduce overall demand.

Conclusion

As flying cars move from the realm of idle fantasy to emerging reality, the public policy debate should put aside simplistic techno-utopian pronouncements and focus on the most likely impacts on society and the environment. The history of transportation innovation indicates that flying cars will likely accelerate low-density development patterns and reinforce the isolation of elites to the detriment of the shared life necessary to sustain a healthy democratic society. Flying car development, deployment, and operations should remain a purely private undertaking. Instead of subsidizing the hypermobility preferences of elites, grant funds should support transportation projects that deliver meaningful benefits to the greatest number of people, principally by expanding the geographic reach, frequency, and quality of public transportation.

About the author

Kevin DeGood is the director of Infrastructure Policy at the Center for American Progress.

Endnotes

  1. At the most recent Consumer Electronics Show in Las Vegas, a senior administrator at the FAA stated that several companies were well along in the process to receive type certification—which is a key step in the process to receive approval to sell or operate a new aircraft—for their designs. Chris Teale, “FAA official: Flying cars are ‘more than just hype,’” Smart Cities Dive, January 15, 2020, available at https://www.smartcitiesdive.com/news/flying-cars-more-than-just-hype-faa-official-smart-cities/570408/.
  2. Adam Satariano, “Inside the High-Stakes Race to Build the World’s First Flying Taxi,” The New York Times, November 5, 2019, available at https://www.nytimes.com/2019/11/05/technology/flying-taxis-lilium.html?smid=nytcore-ios-share.
  3. Ibid.
  4. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation” (San Francisco: 2016), available at https://www.uber.com/elevate.pdf.
  5. This isn’t to suggest that voting and the continued integrity of public institutions aren’t important. On the contrary, corruption, voter suppression, and disinformation campaigns are all deeply detrimental to the functioning of a democracy.
  6. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation.”
  7. Natalie Kitroeff, David Gelles and Jack Nicas, “The Roots of Boeing’s 737 Max Crisis: A Regulator Relaxes Its Oversight,” The New York Times, July 27, 2019, available at https://www.nytimes.com/2019/07/27/business/boeing-737-max-faa.html.
  8. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation.”
  9. Federal Aviation Administration, “FAA Aerospace Forecast Fiscal Years 2017-2037,” available at https://www.faa.gov/data_research/aviation/aerospace_forecasts/media/FY2017-37_FAA_Aerospace_Forecast.pdf (last accessed November 2019).
  10. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation.”
  11. Office of Management and Budget, “Living Within Our Means and Investing in the Future: The President’s Plan for Economic Growth and Deficit Reduction” (Washington: 2011), available at https://vbidcenter.org/wp-content/uploads/2014/12/Office-of-Management-and-Budget-September-2011-Living-Within-Our-Means-and-Investing-in-the-Future.pdf.
  12. Texas Department of Transportation, “Roadway Design Manual” (Austin, TX: 2018), available at http://onlinemanuals.txdot.gov/txdotmanuals/rdw/sight_distance.htm#CHDCDCCH.
  13. Ibid.
  14. U.S. Government Accountability Office, “Air Traffic Control: FAA’s Analysis of Costs and Benefits Drove Its Plans to Improve Surveillance in U.S. Oceanic Airspace” (Washington: 2019), available at https://www.gao.gov/assets/710/700332.pdf.
  15. National Aeronautical and Space Administration, “Unmanned Aircraft System (UAS) Traffic Management (UTM),” available at https://utm.arc.nasa.gov/index.shtml (last accessed February 2020).
  16. Federal Highway Administration, “Simplified Highway Capacity Calculation Method for the Highway Performance Monitoring System” (Washington: U.S. Department of Transportation, 2017), available at https://www.fhwa.dot.gov/policyinformation/pubs/pl18003/hpms_cap.pdf.
  17. Office of Energy Efficiency and Renewable Energy, “FOTW #1040, July 30, 2018: Average Vehicle Occupancy Remains Unchanged From 2009 to 2017,” U.S. Department of Energy, July 30, 2018,available at https://www.energy.gov/eere/vehicles/articles/fotw-1040-july-30-2018-average-vehicle-occupancy-remains-unchanged-2009-2017.
  18. Result based on author’s calculation from Office of Energy Efficiency and Renewable Energy, “FOTW #1040, July 30, 2018”; and Federal Highway Administration, “Simplified Highway Capacity Calculation Method for the Highway Performance Monitoring System.”
  19. Washington Metropolitan Area Transit Authority, “Momentum: The Next Generation of Metro” (Washington: 2013), available at https://www.wmata.com/initiatives/plans/upload/2013-Momentum-Strategic-Plan-for-2025.pdf.
  20. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation.”
  21. Ibid.
  22. Bruce Schaller, “The New Automobility: Lyft, Uber and the Future of American Cities” (Brooklyn, NY: Schaller Consulting, 2018), available at http://www.schallerconsult.com/rideservices/automobility.pdf.
  23. Result based on author’s calculation from Schaller, “The New Automobility.”
  24. Los Angeles International Airport, “Los Angeles World Airports (LAWA) Traffic Comparison (TCOM) Los Angeles International Airport: Calendar YTD January to September” (Los Angeles: 2019), available at https://www.lawa.org/-/media/619105798bf34942b06389a39f5ffa89.pdf.
  25. Aristotle, “Politics,” available at http://classics.mit.edu/Aristotle/politics.3.three.html (last accessed November 2019). It’s worth noting that Aristotle, like other ancient philosophers, was not overly enamored with democracy, viewing the form as insufficiently concerned with justice, though in different ways than oligarchies.
  26. Irving Dilliard, Mr. Justice Brandeis, Great American: Press Opinion and Public Appraisal (Saint Louis, MO: The Modern View Press, 1941), available at

    https://babel.hathitrust.org/cgi/pt?id=mdp.39015009170443&view=1up&seq=56.

  27. Robert Dahl, Polyarchy: Participation and Opposition (New Haven, CT: Yale University Press, 1972).
  28. Martin Gilens, Affluence and Influence: Economic Inequality and Political Power in America (Princeton, NJ: Princeton University Press, 2012).
  29. Michael Eldridge, “Dewey’s Faith in Democracy as Shared Experience,” Transactions of the Charles S. Peirce Society 32 (1) (1996), available at https://www.jstor.org/stable/40320585?read-now=1&seq=1#page_scan_tab_contents. Eldridge makes this observation as part of his summary of the democratic philosophy of John Dewey.
  30. ATC operations at most commercial service airports run 24 hours a day. Yet, funding for ATC operations for VTOLs and delivery drones may fall to state or local governments. For instance, Congress eliminated federal financial support for passenger rail service lines less than 750 miles in length, excluding the Northeast Corridor. These routes are fully funded by state governments even though the service may carry Amtrak branding. Similarly, Congress may decide ATC for short-hop flights is a state and local responsibility, making this service subject to greater budgetary volatility. 
  31. Richard Fry and Paul Taylor, “The Rise of Residential Segregation by Income,” Pew Research Center, August 1, 2012, available at https://www.pewsocialtrends.org/2012/08/01/the-rise-of-residential-segregation-by-income/.
  32. Bethany Whitfield, “Residential Airparks: Living at the Airport,” Flying, February 10, 2014, available at https://www.flyingmag.com/pilots-places/pilots-adventures-more/residential-airparks-living-airport/.
  33. Wikiquote, “Niels Bohr,” available at https://en.wikiquote.org/wiki/Niels_Bohr (last accessed December 2019).
  34. Aristotle, “Politics.”
  35. Federal-Aid Highway Act of 1956, Public Law 627 (June 29, 1956), available at https://www.govinfo.gov/content/pkg/STATUTE-70/pdf/STATUTE-70-Pg374.pdf.
  36. Economies of scale brought down production costs for automobiles. In a short period of time, automobiles enjoyed widespread adoption. For instance, in 1920, there were only 9.2 million registered vehicles and a total population of 106 million people in the United States. By 1956, there were approximately 65 million vehicles and a population of 151 million people. The ratio of people to vehicles fell from 11 to 1 in 1920 to 2.3 to 1 in 1956. Results based on author’s calculation from U.S. Department of Transportation, “Motor Vehicle Registrations, By States, 1900-1995,” available at https://www.fhwa.dot.gov/ohim/summary95/mv201.pdf (last accessed September 2019); U.S. Census Bureau, “POP Culture: 1920,” available at https://www.census.gov/history/www/through_the_decades/fast_facts/1920_fast_facts.html (last accessed September 2019); U.S. Bureau of Transportation Statistics, “Number of U.S. Aircraft, Vehicles, Vessels, and Other Conveyances,” available at https://www.bts.gov/content/number-us-aircraft-vehicles-vessels-and-other-conveyances (last accessed September 2019); U.S. Census Bureau, “POP Culture: 1950,” available at https://www.census.gov/history/www/through_the_decades/fast_facts/1950_fast_facts.html (last accessed September 2019). These figures exclude motorcycles.
  37. Frank Hobbs and Nicole Stoops, “Demographic Trends in the 20th Century” (Washington: U.S. Department of Commerce, 2002), available at https://www.census.gov/prod/2002pubs/censr-4.pdf.
  38. Ibid.
  39. Steven E. Polzin, “Vehicle Miles Traveled Trends and Implications for the US Interstate Highway System” (Tampa, FL: Center for Urban Transportation Research, 2017), available at https://www.nap.edu/resource/25334/interstate/assets/meeting6/1%20Travel%20Forecast/PolzinSteven.pdf.
  40. Ross W. Gorte, “U.S. Tree Planting for Carbon Sequestration” (Washington: Congressional Research Service, 2009), available at https://fas.org/sgp/crs/misc/R40562.pdf. This value range covers both reforestation and afforestation of land. The former is defined as planting trees to create a forest on land that previously forest. The latter is the planting of trees to create forest on land that was not previously forest.
  41. Environmental Protection Agency, “Functions and Values of Wetlands,” (Washington: 2001), available at https://www.epa.gov/sites/production/files/2016-02/documents/functionsvaluesofwetlands.pdf.
  42. Land use map provided by Descartes Labs on January 9, 2020. For additional details about the growth of impervious surfaces over the last decade, see Emily Badger and Quoctrung Bui, “A Decade of Urban Transformation, Seen From Above,” The New York Times, December 27, 2019, available at https://www.nytimes.com/interactive/2019/12/27/upshot/america-from-above.html.
  43. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation.”
  44. Federal Highway Administration, “Summary of Travel Trends: 2017 National Household Travel Survey” (Washington: U.S. Department of Transportation, 2018), https://nhts.ornl.gov/assets/2017_nhts_summary_travel_trends.pdf.
  45. Uber Technologies, “Fast-Forwarding to a Future of On-Demand Urban Air Transportation.”

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