Next Article in Journal
The Effect of Urbanization and Farmland Transfer on the Spatial Patterns of Non-Grain Farmland in China
Previous Article in Journal
Analysis of the Characteristics of Traditional Rural Constructions for Animal Corrals in the Adriatic-Ionian Area
Previous Article in Special Issue
Common Spaces of Multi-Commercial Complexes from Urban Sustainability
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Sustainability
Volume 9
Issue 8
10.3390/su9081442
sustainability-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

The Future of Sustainable Urbanism: Society-Based, Complexity-Led, and Landscape-Driven

by
Rob Roggema
Faculty of Design, Architecture and Building, University of Technology Sydney, Ultimo 2007, Australia
Sustainability 2017, 9(8), 1442; https://doi.org/10.3390/su9081442
Submission received: 17 July 2017 / Revised: 6 August 2017 / Accepted: 13 August 2017 / Published: 15 August 2017
(This article belongs to the Special Issue Sustainable Architecture and Design)
Browse Figures
Versions Notes

Abstract

:
This article discusses the question: where to with sustainable urbanism? It includes a historic review of the concept of sustainable urbanism and reviews of recent literature in the field of eco-cities. Through these reviews, it deliberately interrogates new pathways for sustainable urbanism. The result of this investigation is the insight that there are six design principles that are required to create a sustainable city: a design in which cycles are closed, redundancy is built in, anti-fragility is created, citizens are seen as (design) experts, the landscape is used as the basis, and innovative, rule-breaking designs are developed. These six design principles are then captured in three comprehensive concepts, which together support the design of a sustainable city: the design approach needs to be a (1) society-based; (2) complexity-led, and (3) landscape-driven design approach.

1. Introduction

1.1. Aims

Most of current urbanism is based on a technological paradigm in which the quantification of elements such as housing, jobs and parking spaces, standards, and regulations seem more important than achieving resilience. These kinds of urbanism are strongly economically driven and money-based. Recent developments, such as smart cities, with their focus on data and technology, often deepen this technological paradigm, hence adding vulnerability to urban systems. The urban social and natural systems are seldom capable of dealing with sudden shocks, which are bound to occur at an increasing rate [1].
In the future we need to deal with a triplet of uncertainties [2]:
  • The first of this triplet are developments, which are uncertain by nature. Examples of these, often referred to as wicked problems [3,4,5], are climate change, mass migration, and disruptive technological developments. These are impossible to predict and are therefore inherently uncertain;
  • A second element consists of enforced uncertainties. Several sustainability transitions, such as the transition towards a green economy [6] or a low-carbon energy system [7,8] are deliberately enforced by international agreements and national policies. This type of uncertainties will impact the urban system. In order to accommodate these transitions the city itself needs to transform;
  • Thirdly, there is uncertainty that stems from being exposed to the aforementioned two elements: exposure to uncertainties. For instance, the urbanisation of the global population continues [9], which means an increasing number of people live in cities. At the same time, most cities worldwide are located in vulnerable, exposed areas [10]. Together, this means that the number of people that will have to deal with uncertainties is rapidly increasing.
Because of this triplet of uncertainties, a definition of the future of eco-urbanism is required: urbanism that deals with the above-mentioned triplet of uncertainties, using both advanced technologies, the laws of nature, and self-organizing adaptive systems. This article identifies how this future of eco-urbanism can be achieved.

1.2. Methods

The method of this research consists of two reviews, the development of a common framework, and concludes with a definition of sustainable urbanism. First, a review of the history of sustainability in urbanism was carried out. The second review focused on a broad range of ‘eco’-initiatives, such as regenerative cities, eco-cities, the Biosphere project, One Planet, and others. After these reviews, a common denominator, missing links, and gaps were identified and used to define a congruent future of sustainable urbanism.

1.3. Findings

First of all, the author did not find a unified or coherent perspective on sustainable urbanism. If we want to use the design of the city to deal with future disruptions resulting from climate impacts, migration, economic change, or any other threat, this design should allow the city to transform and adapt to changes. Looking at the city as a complex adaptive system, the capability to adapt to sudden, unprecedented changes and to deal with uncertainty is therefore essential.
Six design principles have been identified, which are needed to support the design of a sustainable city. These design principles are:
(1)
Close cycles at the lowest possible scale;
(2)
Build redundancy in the design;
(3)
Create anti-fragility;
(4)
See citizens as (design) experts;
(5)
Use the landscape as the basis for urban growth;
(6)
Develop innovative, rule-breaking designs.
These six design criteria are then consolidated into three comprehensive ‘concepts’ for the design of sustainable cities: society-based, complexity-led, and landscape-driven, which will be extensively described in this article.
The society, consisting of citizens and governmental and industry institutions, is seen as a pool of experts and ideas to co-feed the planning agenda. The research agenda is complimentary with the society-based agenda.
The complexity of cities needs to be deconstructed in approximately 15 separate layers before it can be reconstructed at the neighborhood level.
The landscape should form the basis for urban growth in order to create cities that exist in harmony with landscape-processes, which on their turn determine the shape of the city.

1.4. Conclusions

The main conclusion of this article is these three comprehensive concepts, and the six design principles can be used in the design of more sustainable cities at every scale.

2. Methods

The methodology in this article is based on two extensive literature reviews, one on the history of sustainability in urbanism and one on green, or ecological, urbanism or ‘eco’-urbanism. Both topics have been studied extensively, and used recent journal articles, books, and websites to collect the information needed to present a coherent analytical reasoning.
Grounded theory has been used as the core methodology. The theoretical proposition has been built up from all its parts, in a constant process of shaping, modifying, and redesigning the theory. This research approach does start with its parts (the findings from literature reviews), identifies key points and concepts (the six principles), which in their turn have informed theory forming (the three overarching concepts), hence it reflects the principles of Grounded Theory. As a general definition of Grounded Theory, it is a methodology developed by Glaser and Strauss [11] to construct a theory derived from qualitative analysis of data [12]. In Grounded Theory, the research guides data collection. The core here is theoretical sampling, which is concept driven. Out of the data, concepts are developed, which subsequently direct the collection of data. Only relevant concepts are elaborated further and integrated, linking categories around core categories, which are refined and trimmed into a theoretical construct. In essence, Grounded Theory can be brought back to three key steps. In the first step, key points (the rudiments of key principles) are identified and around these key points data are collected. In the second step, these key points are connected in concepts (the six principles), and the third step integrates the concepts in a theoretical construct (the three overarching concepts). The attractiveness of this research theory was that there was no fixed pattern beforehand, but it focused on the creation of new insights and the theory emerged during the process.
From these reviews, six design principles for sustainable urbanism emerged, which define the identification, design, and realisation of resilience in urban areas at every scale. The principles are interrelated and are captured in three comprehensive concepts: sustainable urbanism has to be based in society, led through a complexity lens, and design should be based in the landscape.

3. Results

3.1. Review of the History of Sustainability in Urbanism

Looking back in time, sustainability has not always been a central theme in urbanism. ‘The term ‘sustainable urbanism’ encompasses topics of sustainability related to the entire process of city development and management, while sustainable urban design sits somewhere within that. Sustainable urban design is not necessarily a clearly delineated subset of sustainable urbanism, but instead can be thought of as focus area within it that is concentrated around issues of design, while still maintaining strong links to the other realms such as planning, engineering, real estate, and policy [13]. The famous image of the architect eating the landscape, by Malcolm Wells, illustrates the way urbanism was seen for a long time: as a destroyer of natural values. Girardet [14] was one of the first to acknowledge the importance of an integrated approach to developing cities in a sustainable way. He connected themes such as looking at cities as ecosystems, the footprint of cities, urban heat islands, and others with urban design schools, such as the garden city movement [15], the modern city of Le Corbusier [16], Frank Lloyd Wright’s Broadacre city [17], and megacities in general [18,19]. His pledge for convivial cities, the role of citizens and the local scale, and the attention for health, greening the city, renewable energy and recycling, and sustainable forms of mobility [14], are still relevant. Since then, many perspectives, visions, and conceptual practices have been developed, each of them taking sustainability into account in the planning and the design of cities. In the last 20 years, a number of theories or ideologies have influenced thinking about (sustainable) urbanism. Scholars such as Farr [20], acknowledging a strong shift towards integration of ecological analyses in urbanism, Beatley, focusing on ecologically-based land use planning [21] and integrating nature into urban design and planning [22], Mostafavi [23], deliberating on ecological urbanism, Waldheim [24], launching landscape urbanism in which landscape supplants architecture as the basis of urban design, and Newman et al. [25], elaborating on the resilience of the city, as well as Duany et al. [26], proposing an extensive manual on smart growth, and Haas [27], defining a wide range of principles for planning of sustainable and resilient cities, have all covered ground related to building a framework for sustainable urbanism. However, much of the literature on sustainable urban design still lacks grounds for holistically relating the different aspects of urban design [13]. Taking these readings as the starting point of thinking, sustainability in urbanism has been divided in seven distinctive periods [2] which illustrate how the concept of sustainable urbanism has evolved over time.
From the early days when aesthetics were defined by Vitruvius [28] as not only beautiful (venustas), but also solid (firmitas) and useful (utilitas) [29], urban sustainability is defined as a multi-layered concept and aesthetics is equally important as economic viability or ecological value, not more or less important [30]. Sustainability is not similar to environmental quality. A high environmental quality alone does not guarantee a high degree of sustainability. Similarly, an urban environment with a high environmental quality or a high economic value, but without beauty is not considered sustainable either.
After this, periods such as rationalism and conceptualism can be distinguished. Rationalism assumes knowledge will implicitly lead to solutions. An expert planner or the designer ‘who knows it all’ [31] is required to translate this knowledge into functional urban environments. The shape of the city follows the land use, or ‘form follows function’ [32], and engineers play an important role in the final outcome of the design process. In this context sustainability becomes a quantifiable aspect and standards and regulations were introduced, such as for clean water, air, and soil. In the conceptualism period, the water system, the soil, and nature are used as layers [33], an approach that is widely used in the Netherlands [34]. The abiotic, biotic, and anthropogenic layers shape the landscape. The layers aim to separate different dynamics of use. Where the subsoil is seen as changing extremely slowly, and the networks change at a moderate pace, the occupation patterns can change relatively rapidly. It assumes the occupation patterns are nested in the infrastructure networks, which in turn are embedded in the substrate system [35]. In the casco-concept, which is based on this thinking, these spatial dynamics are separated [36]. In the concept called ‘the strategy of the two networks’, higher dynamic uses (traffic, industries, intensive forms of agriculture) are linked to the transportation network and the lower dynamic uses (nature, green, water, residential) to the water network [37,38].
In the negotiatism period, sustainability is seen as a discussable ambition in the planning process. New methods are developed to target sustainability ambitions, such as the DCBA-method [39], in which every urban design aspect requirement is set for level D to A, D being the highest. Over time, the negotiation process evolved into advanced participatory processes, in which engaged citizens could co-design and co-create [40,41] the sustainability of their direct environment [42,43]. In these sessions, the wisdom of the crowd [44] is used to identify future strategies for a sustainable spatial development.
Looking at the city as an ecosystem [45] is the key of the period in which urban metabolism [46,47,48,49,50] defines the city in terms of its flows. When the layer approach is combined with this system’s thinking, a comprehensive model for urban environmental design [51] emerges. The degree to which the system is able to deal with the flows, or networks of traffic, water, energy, and materials, determines the level of sustainability of the system. The design of the city is based on ways in which depletion of resources and production of waste are reduced, and in which resources can be reused and recycled within the city.
The most recent periods, emergism and anti-fragilism focus on the city as a responsive system, in which self-organisation and the adaptive capacities of complex systems determine urban processes. Emergism takes complexity [52,53,54,55,56] as the input for the design of cities [57,58]. Self-organisation and emergence are key concepts, and are used to design interventions in the system to achieve certain changes. These concepts are common in nature and can be used in designing future cities and landscapes that are more adaptable [59]. The designer acts as a facilitator of the process of change, intervening at specific places or times to initiate a change in the system. Approaches such as eco-acupuncture [60,61] and Swarm Planning [58] aim to design small interventions in an existing urban precinct or landscape to transform the area and become more resilient. In order to apply these principles, physical elements in the city or the landscape need to be made moveable [62] and capable of responding to different paces of change that might occur in the city: fast, slow, or sudden [63]. In order to adapt to new circumstances urban systems need to become agile [64]. Rather than only responding to change by coping with it, urban environments can actually become stronger than before through their response to climate events. This concept is called anti-fragility. ‘Ant-fragility is defined as a convex response to a stressor or source of harm (for some range of variation), leading to a positive sensitivity to increase in volatility (or variability, stress, dispersion of outcomes, or uncertainty, what is grouped under the designation “disorder cluster”)’ [65], and offers interesting opportunities. For instance, if the city can create a stronger flood defence by itself once a flood occurs, the city becomes safer. Anti-fragilism is not a common approach in urbanism yet. However, the current combination of increasing uncertainties and unalterable cityscapes places urban population increasingly at risk. Therefore it is necessary to investigate the solutions anti-fragility might bring to urbanism.
Learning from the history of sustainability in urbanism, several key-concepts stand out. The concepts developed to create sustainable framework with the landscape as a basis, such as the layer approach [34,35], the casco-concept [36], and the Two Networks strategy [37,38], have determined much of the work and research being carried out in landscape architecture.
The engagement of communities in the planning and design of urban environment is another key concept which determines the sustainability, support, and acceptance of urban change amongst residents. Recent concepts such as co-design and co-creation allow for a broad spectrum of expertise sets in the design process, which stimulates the development of new and innovative design ideas and new knowledge.
The view of the city as an ecosystem has changed the way we look at urban change and design. The metabolism and design of flows made it possible to discuss the sustainability of the city as a whole, and close the cycles of energy, water, and materials.
More recently, the city is seen as a complex adaptive system and this implies that adaptation and resilience of the city can be discussed as core characteristics. The adaptivity of the city can be influenced through strategic design interventions supporting self-organisation. Adaptation requires creating space to adapt, hence this concept advocates redundancy (‘space for the unknown’) in the urban realm.
A future avenue to increase the strength of the city is to create anti-fragile environments, which grow under influence of external impacts.
These key characteristics derived from the analysis are summarised in Table 1. They lead to six principles that serve as a basis for design: closing cycles, innovative designs, create space for the unknown, anti-fragility, people’s engagement, and taking the landscape as basis for design. These principles are regarded under the larger comprehensive concepts such as society, complexity, and landscape.

3.2. Review of Eco-Initiatives in the Built Environment

3.2.1. Drivers for Green, or ‘Ecological’, Urbanism

Green urbanism is, by definition, interdisciplinary, as in ‘ecological design’, which has been and will be interdisciplinary, not the property of any single profession or movement [66]. Where ecologists look at the size of the ecological footprint, public health focuses on the exposure to pollution, and economists have their eye on the differences in price of real estate, green urbanism unites these views [67]. Green urbanism makes the effort to minimize the use of energy, water, and materials at each stage of the city’s or district’s life cycle [68]. In a new era of uncertainty energy, water and food supply are critical. Humans create a world of increasingly non-calculable uncertainty with the same speed of its technological developments [69]. For eco-urbanism, six driving forces are distinguished: They can be driven by environmental challenges, emerge out of socio-economic pressure, are seen as a business opportunity, be part of cultural branding, evolve out of political leadership, and could be instigated by international co-operation [70]. The development of the eco-city, based on a different combination of these drivers, emerged in three phases (Table 2): after a normative and regulatory phase, the current discourse is based on innovation.
These three phases can be linked, with differences in the means to realize an eco-city: Environmental sustainability is used in the normative phase, models are used to standardize in the second phase, and, in the current period, sustainability is achieved through technology and design [71].

3.2.2. Urban Design Principles

Based on these driving forces for green urbanism, a series of principles can be defined (Table 3) and applied in a systemic and adapted way, requiring a specific approach for every unique site. The future of our society is not merely a technical matter of finding more eco-friendly energy solutions, but a question of holistic environmental and social sustainability, and identifying principles for healthy communities. Much of Green Urbanism is common sense urbanism [68].

3.2.3. Eco-City Typologies

‘Full awareness of problems posed by climate change and consumption of fossil fuel is of equal importance and just as far reaching, raising the possibility of entirely new city models and typologies that are likely to emerge’ [73]. For instance, Kahn defines a green city as a metropolis, which has a core area containing a substantial population nucleus, surrounded by adjacent communities with a high degree of social and economic integration. Green stands for cities that have clean air and water, pleasant streets and parks, are resilient in the face of natural disasters, and have a low risk at infectious disease outbreaks, and they encourage green behavior [67].
Haughton [74] distinguishes the following four models of cities and their relations to their environmental hinterlands:
  • Self-reliant cities: intensive internalization of economic en environmental activities, circular metabolism, bioregionalism, and urban autarky;
  • Redesigning cities and their regions: planning for compact, energy efficient city regions;
  • Externally dependent cities: excessive externalization of environmental cost, open systems, linear metabolism, and buying in additional carrying capacity;
  • Fair Share cities: balancing needs and rights equitably with regulated flows of environmental value and compensatory systems;
Focusing more specifically on sustainable urbanism, De Jong et al. [75] distinguish an additional six types of cities:
  • The sustainable city, which has a self-sufficient economic, social, and environmental system;
  • The low carbon city is minimizing the human-inflicted carbon footprint by reducing or even eliminating the use of non-renewable energy resources;
  • The smart city [76], in which investments in human and social capital is coupled with investment in traditional (transport) and modern information and telecommunication infrastructure, generating sustainable economic development and a high quality of life while promoting prudent management of natural resources [77];
  • The knowledge city integrates cities that physically and institutionally combine the function of a science park with civic and residential functions [78];
  • The resilient city in which a predictive model of urban systems is built through three interconnected components of uncertainty: adaptation, spatial planning, and sustainable urban form (compactness, density, mixed land use, diversity, passive solar, greening, and renewal and utilization) [79], in order to deal with ecological problems, hazards and disasters, and shocks in urban en regional economies, through promoting urban governance and institutions [80];
  • The eco-city aims to reconstruct cities in balance with nature, a city built within the principles of living within the means of the environment [81].
An eco-city is a human settlement modelled on the self-sustaining resilient structure and function of natural ecosystems. The eco-city provides healthy abundance to its inhabitants without consuming more (renewable) resources than it produces, without producing more waste than it can assimilate, and without being toxic to itself or neighbouring ecosystems. Its habitants’ ecological impact reflects planetary supportive lifestyles; its social order reflects fundamental principles of fairness, justice, and reasonable equity [82]. Best practice examples of eco-cities in which these principles to a lesser or larger extend have been realised include the EVA Lanxmeer project in the Netherlands, Masdar ecocity in UAE, Hammarby-Sjöstadt in Stockholm, Sweden, and Hafencity in Hamburg, Germany.
The following dimensions of eco-cities are distinguished [83]:
  • Sustainable development: meet the needs of the present without compromising the ability of future generations to meet their own needs [84];
  • Bioregionalism: a region governed by nature not legislature [85];
  • Community economic development: communities initiate their own solutions to their common economic problems;
  • Appropriate technology: enhance self-reliance of people;
  • Social ecology: committed citizenry cutting across class and economic barriers to address dangers;
  • Green movement: community self-reliance, quality of life, harmony with nature, and decentralization and diversity [86];
  • Ubiquitous eco-city: international knowledge transfer, carbon discourse, smart city and ecological cities as economic cities [87,88].
The regenerative city relies primarily on local and regional food supplies, is powered, heated, cooled, and driven by renewable energy, reuses resources, and restores degraded ecosystems [89]. The aim of the regenerative city is to be able to regenerate the natural resources it absorbs, consisting of four regenerations: Regeneration of Resources (From linear to circular flows), Regeneration of Natural Capital and Urban Ecosystems (from consuming to ‘prosuming’), Regeneration of Urban Spaces (from Sprawled to Dense) and Regeneration of Communities (from Passive to Active engagement) [90]. ReGen villages engineer and facilitate the development of integrated and resilient neighborhoods that power and feed self-reliant families. The Internet of Things (IoT) enables thriving communities with surplus energy, water, and organic food in the aggregate become asset classes that can amortize and reduce mortgage payments [91].

3.2.4. Urban Design Characteristics of Eco-Cities

More detailed characteristics of sustainable urban environments can be distinguished, such as BedZED (Table 4, [92]), and as described by Kenworthy [93]:
  • Compact mixed use urban form;
  • Natural environment permeates the city’s spaces;
  • Transit, walking and cycling infrastructure;
  • Environmental technologies for water, energy, and waste;
  • City centers are human centers, with access other than automobile;
  • High quality public realm;
  • Legible, permeable, robust varied, rich, visually appropriate, and personalized physical structure;
  • Innovation, creativity, and uniqueness create economic performance;
  • Visionary planning through ‘debate and decide’.
Learning from the review of eco-city literature, many different concepts, models, and principles arise. Depending on the phase of development, several urban typologies are distinguished, which each focus on different objects. The objects can be grouped in flows, climate and landscape, transport and densities, and social aspects (Table 5). These groups can be translated in principles for urbanism, to close the cycles, base the design on the landscape, involve people in a co-creation process, and enhance innovation.

4. The Future of Sustainable Urbanism

On the basis of the reviews of a history of sustainable urbanism and the literature on green cities, or eco-cities, six general principles for designing a sustainable city are defined: (1) close cycles at the lowest possible scale; (2) build redundancy in the design; (3) create anti-fragility; (4) see citizens as (design) experts; (5) use the landscape as the basis for urban growth; and (6) develop innovative, rule-breaking designs. Bringing the analyses of the history of sustainability in urbanism and the theory of eco-cities together (Table 6), three comprehensive aspects of sustainable urbanism can be distinguished: the relation between society and the research community, the complexity of urban resilience, and the role of ‘landscape’ in urbanism.

4.1. Principles for Sustainable Urbanism

The six principles for sustainable urbanism are the following:
  • Close cycles at the lowest possible scale. When the cycles of water, energy, and materials are closed, no waste streams are produced and the city is clean and has an efficient urban metabolism. The circularity provides abundant opportunities to create economic benefits. However, it is not always technically and financially most feasible to close cycles at the lowest possible scale. As Tillie et al. [94] and Van den Dobbelsteen [95] have pointed out, for energy solutions on different scales, up-scaling from the individual building can also lead to a balanced urban system;
  • Create spaces for the unknown. When redundancy becomes a standard part in urban design, the city has the flexibility to ‘host’ unprecedented events. If, for instance, a cyclone hits the city, there is space to temporarily store the accompanying water. Roggema [58] has identified this space as being ‘unplanned’;
  • Design anti-fragile spaces. Using this new concept to design places that improve the quality in the city when an event occurs. ‘Ant-fragility is defined as a convex response to a stressor or source of harm (for some range of variation), leading to a positive sensitivity to increase in volatility (or variability, stress, dispersion of outcomes, or uncertainty, what is grouped under the designation “disorder cluster”)’ [65]. Applied in urban environments under stress of climate impacts, anti-fragility is the concept that urban environments become stronger than before through their response to climate events. In urbanism, this concept is ill-researched. However, it could potentially open new design pathways to create urban environments that not only could withstand or bounce back from climate disasters, but, as a result of the hazard, grow stronger;
  • Let people own their environment. When residents are part of the design process, they will create ownership over the changes and invest in their environment. Once residents own their environment, they will make sure it is maintained well [96]. The design charrette is a wonderful design method to develop designs in an inclusive way [97].
  • Use the landscape as the basis for urbanism. Landscape systems, such as the water system, ecology, and soil, create the conditions for urban occupancy. The values in the landscape then will determine the type of urban development. This is contrary to the current situation where the urban development dictates the landscape, e.g., overthrows the existing landscape values to create ordinary residential areas. Even in existing cities, the underlying landscape can be illuminated and brought to the surface to give the city extra ecological qualities.
  • Create innovative designs. The current conventions need to be broken if a sustainable city is to be developed. The existing procedures need to be bypassed using creative design approaches. For the development of regional plans, metropolitan spatial visions, district plans, and neighbourhood designs, a sabbatical detour can provide the space to think differently and the time to come up with alternative design propositions. Elements of a sabbatical detour are design competitions, an idea-generating charrette, designers in resident, exhibitions, and many other activities.

4.2. Society Based, Complexity-Led, and Landscape-Driven

The six design principles are interrelated and can be coherently summarized under three comprehensive concepts (see Table 6).

4.2.1. Society-Based Urbanism

First of all, a key feature of an eco-city is a new relationship between Research/Governance and Society. Recent developments in the history of sustainable urbanism and the literature on eco-urbanism show that society increasingly plays the role of co-designer. The knowledgeable citizen has appeared and he/she is no longer satisfied with a role as respondent to plans made by professionals and/or the government. This implies a different role for the designer himself. Instead of being the ‘planner who knows’, the designer must become the ‘planner who listens’. Before a design for a city is made, the designer as well as governing bodies will benefit from the knowledge and local expertise citizens have and can bring in the design process. The design then is enriched with additional understanding and emotional connotations of the city at stake. The research agenda therefore is not only determined by the funding agency, or the brains of the researcher, it will also be influenced through input from society. A recent planning process undertaken within the frame of 100 resilient cities in Sydney has revealed that citizens came up with approximately 400 ideas that make the city more resilient. Cross-pollination between research agendas and the civil agenda is necessary to grow a sustainable city.

4.2.2. Complexity-Led Urbanism

Secondly, the reviews have revealed that thinking about the city as a complex system [57,98] is becoming more prominent. The different subsystems in the city, such as the transportation system, the energy system, and others, are increasingly seen as complex systems as such, but these feed in to the complexity of the city as a whole. The complexity of the entire city is difficult to grasp, as the interrelations, dependencies, and connectivity between all subsystems in the city are complex by nature. Earlier research [99] therefore proposed to deconstruct urban complexity in 15 systemic layers. Amongst these urban systems are the zero-carbon city, the climate resilient city, the densified city, the inhabitable city, the affordable city, the healthy city, the metabolic city, and more. Once these ‘single-issue cities’ have been designed to their ultimate, most resilient shape, they can be recombined. Then, the complexity can be reconstructed at the neighborhood scale, where local potentials and identities can be generated. Combining the specific features of the different layers for each location gives these places a very specific identity distinct from their neighbors. And, because the reconstructed complexity is based on the resiliency of individual layers, the overall capacity to adapt will increase both at the local level and for the entire metropolis. Because the set of 15 layers contains technical, socio-economic, and nature-based aspects, the combination of these layers provides a balanced and integrated way of looking at the entire city.
Research on these 15 layers is elaborate and the set-up of a rigorous data-base is time-consuming. Recently, investigations into the Zero-Carbon Metropolis of Sydney has led to an image of the first layer (Figure 1), which already can form the basis for further resilient designs at a lower scale [100]. This first layer has been developed by mapping the metropolitan renewable energy resources of the Greater Sydney area. These mappings of the wind potentials, hydropower potentials, solar potentials, and biomass potentials have been connected with the demand of households, public utilities, and industries under an ecological ‘zero-carbon’ lifestyle scenario. The integrated map shows the combination of these types of renewable energy supplies.

4.2.3. Landscape-Driven Design

Landscape is everywhere around us, but in recent decades it has not played a dominant role in the growth of cities. The landscape is often neglected and replaced by an urban landscape that marginally contains elements of the former landscape. Both reviews illustrate that the landscape, represented through its elevation, water, ecology, is a crucial factor to create more sustainable cities. These factors, if not used as a determining factor in urban development, will eventually counterpunch at the city in the form of severe flooding, absence of agricultural fertility, or other disruptive processes. When these factors, however, are used as the basis for urban development, a truly sustainable city could emerge. The processes that drive the landscape are then also the drivers of urban development. If the flows of water form the basis for the urban lay-out, or if the connected habitats of natural ecologies are taken as the starting point of urban development, or if the natural gradients of higher oligotrophic grounds and the lower eutrophic soils are kept intact, the city that emerges builds on the natural richness of the landscape, creating a city in harmony with its environments. Recently, studies have been undertaken for the Badgerys Creek area, west of Sydney, where a new airport and a city with one million new inhabitants are planned to arise. If the urban growth is guided by the principles of the landscape, a very interesting and attractive urban environment can be designed (Figure 2).

5. Discussion

Sustainable urbanism is not only created by design. Economic factors, existing conventions, and limited scope of thinking could all lead to a way of city building that is not sustainable, despite all individual efforts to achieve exactly that. This article proposes to think in broader concepts, and to apply core sustainable design principles to create more sustainable cities.
The methodology used in this article is predominantly based on an extensive literature review. This implies that other sources of information such as practical examples of sustainable urbanism, current research programs within H2020 or Australian CRC’s (e.g., for Low Carbon Living) are excluded. For strengthening the theoretical contribution of this article, it is suggested to include these sources and amend the six principles accordingly.
The role of emergence and non-linearity in the development of sustainable urban designs is important. Systems thinking is the core of both landscape-driven urbanism, complexity-led urbanism, and socio-ecological systems thinking. The non-linearity of developments in the landscape is process-driven, and hence not simply logical. The interactions in society are in itself unpredictable due to the endless options of human interaction, hence the outcomes of co-creative processes are the result of an emergent process. The city itself is, as mentioned, a complex adaptive system, which makes the future of urban developments difficult to predict, and complexity theory forms the basis of modern city planning. All three overarching concepts find, therefore, their theoretical basis in systems thinking. The properties of systems can, therefore, be used in urbanism to create Master Plans, Urban Designs, and Precinct Plans that are more sustainable.
This also brings the discussion between sustainability and resilience to the fore. Whereas sustainability is mainly focused on the environmental quality of urban areas, the sustainability of its flows, and the way people can participate in the planning process [37], resilience focuses on the ability of the urban systems to bounce back and/or be less vulnerable for shocks influencing the urban system [25]. Hence, there is a certain overlap between these two concepts, especially when urban systems are set at the core of urbanism. Socio-ecological systems (people and networks, nature, water, energy, and mobility) can be both sustainable and resilient. Using a complex adaptive systems’ planning approach to cities is, therefore, logical and preferable.
The three aspects, society-based, complexity-led, and landscape-driven are broad. They provide a way of thinking, and direct the process of designing a sustainable city. In this article, each of these aspects is described in more detail to support urbanists to create sustainable cities. These aspects are also described to a certain abstraction, as each of them can be applied in practice in a way that suits the specific context. Whereas society-based directs the process and the role of the designer in the process, complexity-led and landscape-driven contain more guidance on the content.
The six principles require application and further elaboration in concrete case studies to test and investigate their implications. The principles are each covering a field of research that contributes to developing a sustainable city.
Based on the three aspects and six principles, a definition for sustainable urbanism can be developed: “Sustainable urbanism is society-based, complexity-led, and landscape-driven, and it closes cycles at the best possible scale, creates spaces for the unknown, designs anti-fragile areas, lets people own their environment, uses the landscape as the basis for design, and creates innovative rule-breaking designs”.

6. Conclusions

This article started with two reviews of literature, one on the historic development of the concept of sustainable urbanism and one on recent literature about green eco-cities. These reviews revealed that for the design of a sustainable city, three aspects and six principles need to be taken into account.
Each city should organize a process in which the society is as agenda-setting as the research community.
Every city should deconstruct its complex urban systems and recombine them at the neighborhood level.
Each city should base its urban growth and redevelopment on the landscape, giving space to the natural conditions of an area to shape a harmonious city.
In order to be effective in creating this sustainable city, every design should strive for closing cycles, building in redundancy, creating anti-fragility, having the courage to listen to its citizens, and using the landscape as a basis for innovative, rule-breaking designs.

Conflicts of Interest

The author declares no conflict of interest.

References

  1. Intergovernmental Panel on Climate Change (IPCC). Climate Change 2014: Synthesis Report; Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change; Core Writing Team, Pachauri, R.K., Meyer, L.A., Eds.; IPCC: Geneva, Switzerland, 2014; p. 151. [Google Scholar]
  2. Roggema, R. The future of sustainable urbanism: A redefinition. City Territ Archit. 2016, 3. [Google Scholar] [CrossRef]
  3. Rittel, H.; Webber, M. Dilemmas in a general theory of planning. Policy Sci. 1973, 4, 155–169, Reprinted in Developments in Design Methodology; Cross, N., Ed.; Wiley: Chichester, UK, 1984; pp. 135–144. [Google Scholar] [CrossRef]
  4. VROM-raad. De Hype Voorbij, Klimaatverandering als Structureel Ruimtelijk Vraagstuk; advies 060; VROM-raad: Den Haag, The Netherlands, 2007. [Google Scholar]
  5. Commonwealth of Australia. Tackling Wicked Problems; a Public Policy Perspective; Australian government/Australian Public Service Commission: Canberra, Australia, 2007.
  6. Allen, C.; Clouth, S. A Guidebook to the Green Economy; UNDESA: New York, NY, USA, 2012. [Google Scholar]
  7. Foxon, T.J.; Hammond, G.P.; Pearson, P.J. Developing transition pathways for a low carbon electricity system in the UK. Technol. Forecast. Soc. Chang. 2010, 77, 1203–1213. [Google Scholar] [CrossRef] [Green Version]
  8. Bulkeley, H.; Broto, V.C.; Hodson, M.; Marvin, S. (Eds.) Cities and Low Carbon Transitions; Routledge: London, UK, 2010. [Google Scholar]
  9. United Nations. World Urbanization Prospects. The 2007 Revision; United Nations: New York, NY, USA, 2008. [Google Scholar]
  10. Kreimer, A.; Arnold, M.; Carlin, A. (Eds.) Building Safer Cities: The Future of Disaster Risk; The International Bank for Reconstruction and Development, The World Bank: Washington, DC, USA, 2003. [Google Scholar]
  11. Glaser, B.; Strauss, A. The Discovery of Grounded Theory; Aldine: Chicago, IL, USA, 1967. [Google Scholar]
  12. Corbin, J.; Strauss, A. Basics of Qualitative Research; Sage Publications: Thousand Oaks, CA, USA, 2008. [Google Scholar]
  13. Larco, N. Sustainable urban design—A (draft) framework. J. Urban Des. 2016, 21, 1–29. [Google Scholar] [CrossRef]
  14. Girardet, H. The GAIA Atlas of Cities: New Directions for Sustainable Urban Living; Gaia Books Limited: London, UK, 1996. [Google Scholar]
  15. Howard, E. Garden Cities of Tomorrow; S. Sonnenschein & Co., Ltd.: London, UK, 1902. [Google Scholar]
  16. Wise, E. A gradual awakening: Broadacre city and a new American agrarianism. Berkeley Plan J. 2013, 26, 133–149. [Google Scholar]
  17. Cohen, J.-L.; Benton, T. (Eds.) Le Corbusier Le Grand; Phaidon Press Limited: London, UK, 2008. [Google Scholar]
  18. Nicholls, R.J. Coastal megacities and climate change. GeoJournal 1995, 37, 369–379. [Google Scholar] [CrossRef]
  19. Donatiello, J.E. The world’s population: An encyclopedia of critical issues, crises, and ever-growing countries. Ref. User Serv. Q. 2015, 54, 85. [Google Scholar] [CrossRef]
  20. Farr, D. Sustainable Urbanism. Urban Design with Nature; John Wiley and Sons Inc.: Hoboken, NJ, USA, 2008. [Google Scholar]
  21. Beatley, T. Green Urbanism: Learning from European Cities; Island Press: Washington, DC, USA, 2000. [Google Scholar]
  22. Beatley, T. Biophilic Cities: Integrating Nature into Urban Design and Planning; Island Press: Washington, DC, USA, 2010. [Google Scholar]
  23. Mostafavi, M. Why Ecological Urbanism? Why Now? In Ecological Urbanism; Mostafvai, M., Doherty, G., Eds.; Lars Müller Publishers: Baden, Switzerland, 2010. [Google Scholar]
  24. Waldheim, C. Landscape as Urbanism. In Landscape as Urbanism Reader; Waldheim, C., Ed.; Princeton Architectural Press: New York, NY, USA, 2006; pp. 21–34. [Google Scholar]
  25. Newman, P.; Beatley, T.; Boyer, T. Resilient Cities; Island Press: Washington, DC, USA, 2009. [Google Scholar]
  26. Duany, A.; Speck, J.; Lydon, M. The Smart Growth Manual; McGraw-Hill Education: New York, NY, USA, 2009. [Google Scholar]
  27. Haas, T. Sustainable Urbanism and Beyond; Rizzoli: New York, NY, USA, 2012. [Google Scholar]
  28. Kriens, I.; Klaasen, I.T.; Rooij, R.M. De Kern van Ruimtelijke Planning and Strategie. Ruimte en Maatschappij; Technische Universiteit Delft: Delft, The Netherlands, 2008. [Google Scholar]
  29. Morgan, M.H. Vitruvius. The Ten Books on Architecture; Harvard University Press: Cambridge, MA, USA; Oxford University Press: London, UK, 2001. [Google Scholar]
  30. Ministerie van Landbouw Natuurbeheer en Visserij. Nota Landschap; Ministerie van LNV: Den Haag, The Netherlands, 1992. [Google Scholar]
  31. Gunder, M. Fake it until you make it, and then…. Plan Theory 2011, 10, 201–212. [Google Scholar] [CrossRef]
  32. Sullivan, L. The Tall Office Building Artistically Considered; Lippincott’s Monthly Magazine: New York, NY, USA, 1896. [Google Scholar]
  33. McHarg, I.L. Design with Nature; Natural History Press: New York, NY, USA, 1969. [Google Scholar]
  34. Van Schaick, J.; Klaasen, I.T. The Dutch layers approach to spatial planning and design: A fruitful planning tool or a temporary phenomenon? Eur. Plan. Stud. 2011, 19, 1775–1796. [Google Scholar] [CrossRef]
  35. Priemus, H. The network approach: Dutch spatial planning between substratum and infrastructure networks. Eur. Plan. Stud. 2007, 15, 667–686. [Google Scholar] [CrossRef]
  36. Sijmons, D. Het Casco-Concept, een Benaderingswijze Voor de Landschapsplanning; Ministerie van LNV, directie NBLF: Utrecht, The Netherlands, 1992. [Google Scholar]
  37. Tjallingii, S.P. Ecopolis: Strategies for Ecologically Sound Urban Development; Backhuys Publishers: Leiden, The Netherlands, 1995. [Google Scholar]
  38. Tjallingii, S. Planning with water and traffic networks. Carrying structures of the urban landscape. Res. Urban Ser. 2015, 3, 57–80. [Google Scholar] [CrossRef]
  39. Teeuw, P. Duurzame Ideeën % DCBA Methodiek: Ambitie Stellen Volgens de Viervarianten-Methode; AEneas, Boxtel: Hertogenbosch, The Netherlands, 2010. [Google Scholar]
  40. Sanders, E.B.N.; Stappers, P.J. Co-creation and the new landscape of design. CoDesign 2008, 4, 5–18. [Google Scholar] [CrossRef]
  41. Roggema, R.; Martin, J.; Arcari, P.; Clune, S.; Horne, R. Design-Led Decision Support Process and Engagement; VCCCAR: Melbourne, Australia, 2013. [Google Scholar]
  42. Roggema, R.; Vos, L.; Martin, J. Resourcing local communities for climate adaptive designs in Victoria, Australia. Chin. J. Popul. Resour. Manag. 2014, 12, 210–226. [Google Scholar] [CrossRef]
  43. Roggema, R.; Martin, J.; Vos, L. Governance of Climate Adaptation in Australia: Design Charrettes as Creative Tool for Participatory Action Research. In Action Research for Climate Change Adaptation: Developing and Applying Knowledge for Governance; Van Buuren, A., Eshuis, J., van Vliet, M., Eds.; Routledge: London, UK, 2014; pp. 92–108. [Google Scholar]
  44. Surowiecki, J. The Wisdom of Crowds: Why the Many Are Smarter Than the Few; Little Brown: Boston, MA, USA, 2004. [Google Scholar]
  45. Tomásek, W. Die Stadt als Oekosystem; Űberlegungen zum Vorentwurf Landschafsplan Köln (The city as ecosystem; considerations about the scheme of the Landscape design Cologne). Landsch. Stadt 1979, 11, 51–60. [Google Scholar]
  46. Wolman, A. The metabolism of cities. Sci. Am. 1965, 213, 179–190. [Google Scholar] [CrossRef] [PubMed]
  47. Newman, P.W.G. Sustainability and cities: Extending the metabolism model. Landsc. Urban Plan. 1999, 44, 219–226. [Google Scholar] [CrossRef]
  48. Kennedy, C.; Cuddihy, J.; Engel-Yan, J. The changing metabolism of cities. J. Ind. Ecol. 2007, 11, 43–59. [Google Scholar] [CrossRef]
  49. Kennedy, C.; Pincetl, S.; Bunje, P. The study of urban metabolism and its applications to urban planning and design. Environ. Pollut. 2010, 159, 1965–1973. [Google Scholar] [CrossRef] [PubMed]
  50. Shafie, F.A.; Dasimah, O.; Karuppannanb, S. Urban metabolism: A research methodology in urban planning and environmental assessment. In Proceedings of the 1st International Conference on Research Methodology for Built Environment and Engineering, Kuala Lumpur, Malaysia, 17–18 December 2013. [Google Scholar]
  51. Kristinsson, J. Integrated Sustainable Design; Van den Dobbelsteen, A., Ed.; Delft Digital Press: Delft, The Netherlands, 2012. [Google Scholar]
  52. Prigogine, Y.; Stengers, I. Order out of Chaos. Man’s New Dialogue with Nature; Bantam Books Inc.: New York, NY, USA, 1984. [Google Scholar]
  53. Mitchell Waldrop, M. Complexity. The Emerging Science at the Edge of Order and Chaos; Simon and Schuster Paperbacks: New York, NY, USA, 1992. [Google Scholar]
  54. Kauffman, S.A. The Origin of Order: Self-Organisation and Selection in Evolution; Oxford University Press: New York, NY, USA, 1993. [Google Scholar]
  55. Kauffman, S. At Home in the Universe; Oxford University Press: Oxford, UK, 1995. [Google Scholar]
  56. Cohen, J.; Stewart, I. The Collapse of Chaos: Discovering Simplicity in a Complex World; Penguin Group Ltd.: London, UK, 1994. [Google Scholar]
  57. Portugali, J. Self-Organisation and the City; Springer: Berlin, Germany, 2000. [Google Scholar]
  58. Roggema, R. Swarm Planning: The Development of a Spatial Planning Methodology to Deal with Climate Adaptation. Ph.D. Thesis, Delft University of Technology, Delft, The Netherlands, 2012. [Google Scholar]
  59. Waterman, R.E. Integrated Coastal Policy via Building with Nature. Ph.D. Thesis, Delft University of Technology, Delft, The Netherlands, 2010. [Google Scholar]
  60. Ryan, C. Eco-acupuncture: Designing and facilitating pathways for urban transformation, for a resilient low-carbon future. J. Clean. Prod. 2013, 50, 189–199. [Google Scholar] [CrossRef]
  61. Ryan, C.; Biggs, C.; Trudgeon, M. Eco-acupuncture and greenaissance: Designing urban interventions for resilient post-carbonaceous futures, from Victoria (Australia) to Florence (Italy). In Proceedings of the State of Australian Cities Conference, Sydney, Australia, 26–29 November 2013. [Google Scholar]
  62. Roggema, R. Towards enhanced resilience in city design: A proposition. Land 2014, 3, 460–481. [Google Scholar] [CrossRef]
  63. Roggema, R. Three urbanisms in one city: Accommodating the paces of change. J. Environ. Prot. 2015, 6, 946–956. [Google Scholar] [CrossRef]
  64. Russell, J.S. The Agile City. Building Well-Being and Wealth in an Era of Climate Change; Island Press: Washington, DC, USA, 2011. [Google Scholar]
  65. Taleb, N.N. Antifragile—Things That Gain from Disorder; Random House: New York, NY, USA, 2012. [Google Scholar]
  66. Ellis, C. Landscape Urbanism and New Urbanism: A View of the Debate. J. Urban Des. 2015, 20, 303–307. [Google Scholar] [CrossRef]
  67. Kahn, M.E. Green Cities Urban Growth and the Environment; Brookings: Washington, DC, USA, 2006. [Google Scholar]
  68. Lehmann, S. Green Urbanism: Formulating a Series of Holistic Principles. Sapiens 2010, 3, 1–17. [Google Scholar]
  69. Beck, U. Risk Society. Towards a New Modernity; Sage: London, UK, 2000. [Google Scholar]
  70. Joss, S. Eco-cities: The mainstreaming of urban sustainability—Key characteristics and driving forces. Int. J. Sustain. Dev. Plan. 2011, 6, 268–285. [Google Scholar] [CrossRef]
  71. Rapoport, E.; Vernay, A.-L. Defining the Eco-City: A Discursive Approach; International Ecocities Initiative; University of Westminster: London, UK, 2014; Available online: https://www.westminster.ac.uk/file/42096/download (accessed on 15 May 2017).
  72. Van den Dobbelsteen, A.; Jansen, S.; van Timmeren, A.; Roggema, R. Energy Potential Mapping—A systematic approach to sustainable regional planning based on climate change, local potentials and exergy. In Proceedings of the CIB World Congress, Cape Town, Africa, 14–18 May 2007. [Google Scholar]
  73. Lehmann, S. The Principles of Green Urbanism. Transforming the City for Sustainability; Earthscan: London, UK, 2010. [Google Scholar]
  74. Haughton, G. Developing sustainable urban development models. Cities 1997, 14, 189–195. [Google Scholar] [CrossRef]
  75. De Jong, M.; Joss, S.; Schraven, D.; Zhan, C.; Weinen, M. Sustainable-smart-resilient-low carbon-eco-knowledge cities; making sense of a multitude of concepts promoting sustainable urbanization. J. Clean. Prod. 2015, 109, 25–38. [Google Scholar] [CrossRef]
  76. Townsend, A.M. Smart Cities. Big Data, Civic Hackers, and the Quest for a New Utopia; W.W. Norton Inc.: New York, NY, USA, 2014. [Google Scholar]
  77. Caragliu, A.; Del Bo, C.; Nijkamp, P. Smart Cities in Europe. J. Urban Technol. 2011, 18, 65–82. [Google Scholar] [CrossRef]
  78. Yigitcanlar, T.; Velibeyogly, K.; Baum, S. (Eds.) Knowledge-Based Urban Development: Planning and Applications in the Information Era; IGI Global: Hershey, PA, USA, 2008. [Google Scholar]
  79. Jabareen, Y. Planning the resilient city: Concepts and strategies for coping with climate change and environmental risk. Cities 2013, 31, 220–229. [Google Scholar] [CrossRef]
  80. Leichenko, R. Climate change and urban resilience. Curr. Opin. Environ. Sustain. 2011, 3, 164–168. [Google Scholar] [CrossRef]
  81. Register, R. Ecocity Berkeley: Building Cities for a Healthy Future; North Atlantic Books: Berkeley, CA, USA, 1973. [Google Scholar]
  82. Ecobuilders (Undated). What Is an Ecocity? Available online: http://www.ecocitybuidlers.org/what-is-an-ecocity/ (accessed on 12 April 2017).
  83. Roselund, M. Dimensions of the eco-city. Cities 1997, 14, 197–202. [Google Scholar] [CrossRef]
  84. World Commission on Environment and Development (WCED). Our Common Future; Oxford University Press: New York, NY, USA, 1987. [Google Scholar]
  85. Sale, K. Dwellers in the Land: The Bioregional Vision; Sierra Club: San Francisco, CA, USA, 1985. [Google Scholar]
  86. Capra, F.; Spretnak, C. Green Politics: The Global Promise; Dutton: New York, NY, USA, 1984. [Google Scholar]
  87. Van Timmeren, A.; Henriquez, L.; Reynolds, A. Ubikquity & the Illuminated City; TU Delft: Delft, The Netherlands, 2015. [Google Scholar]
  88. Joss, S.; Cowley, R.; Tomozeiu, D. Towards the ‘ubiquitous eco-city’: An analysis of the internationalisation of eco-city policy and practice. Urban Res. Pract. 2013, 6, 54–74. [Google Scholar] [CrossRef]
  89. Howarth, L. Ecopolis, the Emergence of Regenerative Cities. The Ecologist. Available online: http://www.theecologist.org/News/news_analysis/2000416/ecopolis_the_emergence_of_regenerative_cities.html (accessed on 12 April 2017).
  90. Boselli, F. Cities Must Be Regenerative. But What Kind of Regeneration Are We Actually Talking About? World Future Council. 2016. Available online: https://www.worldfuturecouncil.org/cities-must-regenerative-kind-regeneration-actually-talking/ (accessed on 12 April 2017).
  91. ReGen Villages Holding. REGENVILLAGES. 2016. Available online: http://www.regenvillages.com (accessed on 18 May 2017).
  92. Kenworthy, J.R. The eco-city: ten key transport and planning dimensions for sustainable city development. Environ. Urban. 2006, 18, 67–85. [Google Scholar] [CrossRef]
  93. Bioregional. The BedZED Story. The UK’s First Large Scale, Mixed-Use Eco-Village; Bioregional Development Group: London, UK, 2016. [Google Scholar]
  94. Tillie, N.; Van Den Dobbelsteen, A.; Doepel, D.; Joubert, M.; De Jager, W.; Mayenburg, D. Towards CO2 Neutral Urban Planning: Presenting the Rotterdam Energy Approach and Planning (REAP). J. Green Build. 2009, 4, 103–112. [Google Scholar] [CrossRef]
  95. Van den Dobbelsteen, A.; Wisse, K.; Doepel, D.; Tillie, N. REAP2-new concepts for the exchange of heat in cities. In Proceedings of the 4th CIB Conference Smart and Sustainable Built Environments, Sao Paulo, Brazil, 27–29 June 2012. [Google Scholar]
  96. Western Australian Planning Commission. Designing out Crime. Planning Guidelines; State of Western Australia: Perth, Australia, 2009.
  97. Roggema, R. The Design Charrette: Ways to Envision Sustainable Futures; Springer: Dordrecht, The Netherlands; Heidelberg, Germany; London, UK, 2013; p. 335. [Google Scholar]
  98. Portugali, J. Complexity theory as a link between space and place. Environ. Plan. A 2006, 38, 647–664. [Google Scholar] [CrossRef]
  99. Roggema, R.; Thomas, L. Critical mapping for transformational cities. In Proceedings of the Passive and Low Energy Architecture (PLEA 2017), Edinburgh, UK, 3–5 July 2017. [Google Scholar]
  100. Roggema, R.; King, L.; van den Dobbelsteen, A. Towards Zero-Carbon metropolitan regions: The example of Sydney. Energies 2017. forthcoming. [Google Scholar]
Sustainability 09 01442 g001 550
Figure 1. Map showing the Metropolis of Sydney as a Zero-Carbon area (Roggema et al., 2017).
Figure 1. Map showing the Metropolis of Sydney as a Zero-Carbon area (Roggema et al., 2017).
Sustainability 09 01442 g001
Sustainability 09 01442 g002 550
Figure 2. Plan for a landscape-driven urban design for Badgerys Creek (Source: Lingfen Xue, work resulting from the design studio GO WEST! Led by Rob Roggema and Craig Allchin, UTS, Autumn 2017).
Figure 2. Plan for a landscape-driven urban design for Badgerys Creek (Source: Lingfen Xue, work resulting from the design studio GO WEST! Led by Rob Roggema and Craig Allchin, UTS, Autumn 2017).
Sustainability 09 01442 g002
Table
Table 1. Sustainable urbanism translated in principles and overarching concepts.
Table 1. Sustainable urbanism translated in principles and overarching concepts.
PhaseConceptPrincipleOverarching
Aesthetics
Rationalism
NegotiatismCo-design
Co-creation		People
Innovative design		Society
EmergensimInterventionsInnovative design
Ecosystem basedMetabolismClose cyclesComplexity
Antifragility Antifragile
EmergenismInterventionsSpace for the unknownLandscape
ConceptualismLayers Approach
Casco Concept
Two Network Strategy		Landscape as basis
Table
Table 2. Three phases of eco-city development (adapted from 70).
Table 2. Three phases of eco-city development (adapted from 70).
PhasePerspectiveMeans
1980’sGrassroots, visionsNormativeEnvironmental standards
1992–early 2000Local and national experimentationRegulatory, standardisedStandardized models
2000–presentGlobal expansion, mainstreamingInnovation, conceptualTechnology and design
Table
Table 3. Principles for Green Urbanism (adapted from 68).
Table 3. Principles for Green Urbanism (adapted from 68).
PrincipleAspects
Climate and contextSite’s climate conditions, orientation and compactness, landscape, topography and resources, maintain complexity, own methods, and tailored strategies for every district take advantage of local potentials
Renewable energyAvailability of local renewables (energy potentials [72], city district as a producer of energy, distributed energy supply though decentralized systems, local storage, smart grid, energy efficiency, co-gen, cascading exergy principles, intelligent building management.
Zero-wasteCircular, closed loop, turn waste into resource, reduce, reuse, recycle, and compost waste to produce energy, remanufacturing, balance in nitrogen cycle
WaterReduce consumption, efficiency of use, water quality, aquatic habitats, city as a water catchment area, storm water retention and flood management, rainwater harvesting, local treatment of waste-water, safe water and sanitation, algae, integrated urban water cycle planning, black and grey water treatment, dual water systems, drought resistant crops
Landscape and urban biodiversityLocal biodiversity, habitat, ecology, wildlife rehabilitation, forest conservation, urban vegetation, inner city gardens and urban agriculture, mitigating Urban Heat island effects, tree planting, restoring stream and river banks, de-pavements, carbon storage
Sustainable transport and good public space in compact poly-centric citiesPublic space network, post fossil mobility, access to public transport, safe bicycle ways, smart vehicles, walkeable city, streetscapes for healthy active lifestyle, medium dense housing typologies
Local materials with less embodied energyAdvanced materials technology, local materials, modular prefabrication, lightweight structures, disassembly, resource recovery, reuse building components
Density and retrofitting existing districtsDensification of the city, mixed use urban infill, retrofitting inefficient building stock, better land use planning, public space upgrading, adaptive reuse, city above the city, self-sufficiency
Passive design for buildings and districtsLow energy, zero-emission design, reduce energy use, compact solar architecture, bioclimatic architecture, design for disassembly, solar architecture, flexibility in plans, energy generating buildings
Liveability and mixed useAffordable housing, healthy community, social inclusion, mixed use, liveable and flexible housing typologies, secure tenure, diversity, integrating a diversity of economic and cultural activities,
Local food and short supply chainsLocal food production, regional supply, urban farming and agriculture, community and allotment gardens, roof gardens, urban market garden, paper bags, recycling, organic produce
Identity and sense of placePublic health, cultural identity, urban heritage, air quality, distinct environment, grassroots strategies, affordable studio space, creativity of government and citizens, health, activities and safety
Urban governance and leadershipEvolutionary and adaptive policies, decision making, and responsibility shared with empowered citizenry, enabling citizens, updating building codes, improve planning participation, integrated public awareness, legislating controls on density and urban sprawl, support high quality densification, finance low-to-no-carbon pathways, eliminate fossil fuel subsidies, certify urban development projects
Education, research and knowledgeUp-skilling, knowledge dissemination, primary and secondary school teaching programs, university as a think tank, redefine education of architects, foundation of centre for sustainable urban development
Table
Table 4. BedZED’s One Planet Living principles for design [92].
Table 4. BedZED’s One Planet Living principles for design [92].
PrincipleDesign
Health and happinessEncouraging active, social, meaningful lives to promote health and wellbeing
Equity and local economyCreate safe equitable places to live and work, which support local prosperity and international fair trade
Culture and communityNurturing local identity and heritage empowering communities and promoting a culture of sustainable living
Land and natureProtecting and restoring land for the benefit of people and wildlife
Sustainable waterUsing water efficiently, protecting local water resources and reducing flooding and drought
Local and sustainable foodPromoting sustainable humane farming and healthy diets high in local seasonal organic food and vegetable protein
Travel and transportReducing the need to travel, encouraging walking, cycling and low-carbon transport
Materials and productsUsing materials from sustainable sources and promoting products, which help people reduce consumption
Zero wasteReducing consumption re-using and recycling to achieve zero-waste and zero pollution
Zero carbon energyMaking buildings and manufacturing energy efficient and supplying all energy with renewables
Table
Table 5. Eco-cities concepts translated in principles.
Table 5. Eco-cities concepts translated in principles.
PhaseCityObjectPrinciple
Environmental standard
Standardised modelsSustainable city
Self-reliant city
Resilient city
Regenerative city		Renewable energy
Low embodied energy
Passive design
Zero waste
Food
Water		Flows/close cycles
Carrying capacity, metabolism zero-low-carbon city
Technology and designBioregional city
Green/Ubiquitous Eco-city		Climate
Landscape and biodiversity		Landscape-based design
Smart city
Redesign of city
Knowledge city		Densification
Transport and travel
Fair share/Equity and local economy/Community developmentSocial ecology
Health & happiness
Cultural community		LiveabilityPeople, co-creation
Local production
Identity		Innovative design
Uber governancePeople, co-design
EducationPeople
Table
Table 6. Sustainable urbanism and eco-cities key elements combined into principles and overarching concepts.
Table 6. Sustainable urbanism and eco-cities key elements combined into principles and overarching concepts.
PhaseConceptPrincipleOverarchingPrincipleObjectCityPhase
NegotiatismCo-design
Co-creation		People
Innovative design		SocietyPeople, co-creationLiveability
Local production
Identity		Social ecology
Health & happiness
Cultural community		Fair Share/Equity and local economy/Community development
Innovative designUrban governance
People, co-design peopleEducation
EmergenismInterventionsInnovative design
Ecosystem basedMetabolismClose cyclesComplexityFlows/close cyclesRenewable energy
Low embodied energy
Passive design
Zero waste
Food
Water		Sustainable city
Self-reliant city
Resilient city
Regenerative city		Standardised models
Antifragility Antifragile
EmergenismInterventionsSpace for the unknown
ConceptualismLayers,
Casco
S2N		Landscape as basisLandscapeLandscape-based designClimate
Landscape and biodiversity		Carrying capacity, metabolism
Zero-low-carbon City
Densification
Transport & Travel		Bioregional city
Green/Ubiquitous Eco-city
Smart city
Redesign of cities Knowledge city		Technology and design
Aesthetics Environmental standard
Rationalism

Share and Cite

MDPI and ACS Style

Roggema, R. The Future of Sustainable Urbanism: Society-Based, Complexity-Led, and Landscape-Driven. Sustainability 2017, 9, 1442. https://doi.org/10.3390/su9081442

AMA Style

Roggema R. The Future of Sustainable Urbanism: Society-Based, Complexity-Led, and Landscape-Driven. Sustainability. 2017; 9(8):1442. https://doi.org/10.3390/su9081442

Chicago/Turabian Style

Roggema, Rob. 2017. "The Future of Sustainable Urbanism: Society-Based, Complexity-Led, and Landscape-Driven" Sustainability 9, no. 8: 1442. https://doi.org/10.3390/su9081442

APA Style

Roggema, R. (2017). The Future of Sustainable Urbanism: Society-Based, Complexity-Led, and Landscape-Driven. Sustainability, 9(8), 1442. https://doi.org/10.3390/su9081442

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop