UN-Sustainable Urbanism: The Challenge of “Lock-In”
Abstract
:1. Introduction
2. Sustainability in Urbanism
3. Modeling the Negative
- Rates of consumption of resources, including renewable and non-renewable ones. Consumption of renewable resources is sustainable if they are regenerated at a higher rate than their consumption (e.g., timber, fresh water), and if their consumption does not produce an accumulation of other toxic effects (e.g., waste products, air pollution). Consumption of non-renewable resources is sustainable if they are fully recycled, or if they can feasibly be replaced by other resources later—and also if their consumption does not produce an accumulation of other toxic effects.
- Rates of accumulation of pollutants, contaminants, and other disruptive elements. Among these are chemicals that are toxic to the biosphere and/or humans, substances that are disruptive of ecologies and animal health (like plastics and per- and polyfluoroalkyl substances, or PFAS), and invasive species. As noted, a relatively new class of pollutants includes greenhouse gases, ozone-depleting chemicals, and other substances with accumulating and possibly catastrophic impacts to human and planetary well-being.
- Rates of degradation of habitats and ecologies, including critical ecosystems (e.g., ocean, wetlands) and the species that depend on them.
- Rate of decay versus regeneration of critical cultural and socioeconomic systems, including socioeconomic systems that are essential to human development and cultural wealth, political and institutional systems needed to manage catastrophic effects from technologies (e.g., ecological catastrophes), wars (e.g., use of nuclear or biological weapons), natural threats (e.g., pandemics), and other threats to urban and human sustainability.
- Over-reliance on low-occupancy, high-consumption vehicular transport. This category includes passenger automobiles, which are much larger and heavier per passenger than other forms of transport, require significantly higher rates of fuel consumption per capita, contain greater embodied resources and energy, and in the case of internal combustion engines, produce more toxic emissions in air and water. These vehicles are often operated only by single individuals, further raising per capita and overall consumption and depletion rates. To a lesser extent, this category also includes motorcycles, taxis, and transportation network companies, whose performance is only marginally better than personal low-occupancy vehicles.
- Inefficient envelope, size, orientation, and adaptability of buildings. Although progress has been made in recent years, many buildings are still poorly insulated and over-exposed to sun and wind, resulting in much higher consumption of resources for heating and cooling than necessary. Many buildings are also inefficiently organized, and therefore larger and more wasteful of energy and resources than necessary. Many buildings are also limited in their adaptability to new uses and to user needs and desires, resulting in excessive remodeling or even demolition. Finally, many buildings are inefficiently sited, resulting in greater land consumption and ecological impacts.
- Ecologically destructive systems for handling water and energy. Once again, progress has been made in recent years, but there is still too much reliance on non-renewable and toxic energy sources, in particular fossil fuels, and too much discharge of runoff water that is ecologically degraded in both quality and quantity.
- Decline of a well-ordered, walkable, functionally and visually appealing public realm. This is an under-appreciated factor, yet as research is demonstrating, one with profound consequences for the socioeconomic unsustainability of cities, as discussed below.
4. The Central Role of the Public Realm
5. Summarizing the Model
- Inefficient vehicles (and their infrastructures);
- Inefficient buildings (and their placements);
- Inefficient resource systems (and their extended impacts);
- Degraded public realm.
6. Lock-In of the Model
- The depletion of resources (including building energy fuel, water, vehicle fuel, etc.) is financially rewarding, and this powerful incentive is not offset by payments of true externality costs (the costs to others or to the future).
- Policies and practices by government institutions become path-dependent when they create beneficiaries who oppose change, often because the beneficiaries are able to profit from the policies and practices, and they can divert some of these profits to lobbying, political support, and other forms of institutional reinforcement. These actions further reinforce the lock-in.
- Costs for institutions that must reconfigure their processes, standards and technologies (known as “switching costs”) are powerful disincentives to reform, and powerful incentives to maintain a more easily predicted, lower-risk form of “business as usual”.
- Perhaps least well recognized, and perhaps most promising, cognitive and ideological models of normative urbanism also powerfully favor business as usual. Often, they do so in ways that are obscured by rationalizations and hidden biases. This is a promising finding, because there is good research on effective ways to overcome biases and rationalizations in decision-making [65,66].
- Using mechanisms to monetize externality costs and benefits, including tax policies, development charges, “feebates” (reduced or rebated regulatory fees for incentivized practices), and related financial tools. The mechanisms to allocate these costs must also be developed as reasonably accurate externality models, further requiring sophisticated Bayesian methodologies.
- Creating political momentum to overcome entrenched policies of special interests, through educational and political campaigning, and through professional pressure for reform of policies and practices. In turn, this goal requires effective communication with the public to motivate them to press for reforms.
- Creating institutional incentives for reform, which can include awards, certifications, grants, and model programs and ordinances.
- Advancing new counter-models of sustainable urbanism, with a focus on their appealing qualities for citizens and policymakers. These counter-models can create pathways for further implementation, bypassing locked-in constraints. The counter-models need to include actual built examples as well as persuasive evidence-based arguments.
- Transportation engineering models that prioritize mobility over access. These often take the form of context-insensitive street designs that are disruptive of pedestrian movement and visual quality, and, moreover, can be deadly to pedestrians and bicyclists. The counter-model balances access with mobility and creates an environment of transportation choice, context-sensitive design, and pervasive low-impact mobility (including convenient walking, biking and public transit).
- Building models that sever their connections to the public realm, and to other buildings, defaulting to a stand-alone aesthetic as objects to be regarded rather than contexts to be inhabited. The alternative model is one of intimate connections between buildings, and between them and their public realm, including cognitive and aesthetic connections.
- Infrastructure and landscape models that destroy existing ecological systems and replace them with destructive surface paving, piping, vegetation and other damaging structures. The alternative model embraces the existing ecology and seeks to build in complementary patterns: recharging clean water, protecting or adding native vegetation, neutralizing and not discharging pollutants, and most especially, maintaining a compact footprint that minimizes regional land impacts.
- Public realm models that degrade the functionality and aesthetics of the public realm, and its system of connections to efficiently distributed private spaces. The alternative model is all around us to see, in the compact, walkable, mixed-use communities of traditional city and town cores throughout human history.
7. Discussion
8. Conclusions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Mehaffy, M.W. UN-Sustainable Urbanism: The Challenge of “Lock-In”. Sustainability 2024, 16, 7301. https://doi.org/10.3390/su16177301
Mehaffy MW. UN-Sustainable Urbanism: The Challenge of “Lock-In”. Sustainability. 2024; 16(17):7301. https://doi.org/10.3390/su16177301
Chicago/Turabian StyleMehaffy, Michael W. 2024. "UN-Sustainable Urbanism: The Challenge of “Lock-In”" Sustainability 16, no. 17: 7301. https://doi.org/10.3390/su16177301